ultrasonic fingerprint sensor for on-screen applications

专利摘要:
The present invention relates to methods, devices, apparatus and systems for an ultrasonic fingerprint sensor under the screen. A display device may include a glass plate, a screen underlying the glass plate and an ultrasonic fingerprint sensor underlying the screen, where the ultrasonic fingerprint sensor is configured to transmit and receive ultrasonic waves via an acoustic path through the glass plate and the screen. A light blocking layer and / or an electrical shielding layer can be provided between the ultrasonic fingerprint sensor and the screen, where the light blocking layer and / or the electrical shielding layer are in the acoustic path. A mechanical stress insulation layer can be provided between the ultrasonic fingerprint sensor and the screen, where the mechanical stress insulation layer is in the acoustic path.
公开号:BR112019026830A2
申请号:R112019026830-8
申请日:2018-06-14
公开日:2020-06-30
发明作者:Hrishikesh Vijaykumar Panchawagh；Firas Sammoura；Jessica Liu Strohmann；David William Burns；Ila Ravindra Badge；Yipeng Lu；Kostadin Dimitrov Djordjev；Suryaprakash Ganti；Chin-Jen Tseng；Nicholas Ian Buchan；Tsongming Kao；Leonard Eugene Fennell
申请人:Qualcomm Incorporated；
IPC主号:

专利说明:

[0001] [0001] This application claims priority benefit for United States Patent Application No. 16 / 006,640, filed on June 12, 2018 and entitled “ULTRASONIC FINGERPRINT SENSOR FOR UNDER-DISPLAY APPLICATIONS”, which claims priority for United States Provisional Patent Application No. 62 / 525,154, filed on June 26, 2017 and entitled “ULTRASONIC FINGERPRINT SENSOR FOR UNDER-DISPLAY APPLICATIONS”, each of which is incorporated herein by reference in its entirety and for all purposes. TECHNICAL FIELD
[0002] [0002] The present invention relates, in general, to ultrasonic fingerprint sensor systems and, more particularly, to ultrasonic fingerprint sensor systems incorporated in screen applications. RELATED TECHNOLOGY DESCRIPTION
[0003] [0003] In an ultrasonic sensor system, an ultrasonic transmitter can be used to send an ultrasonic wave through an ultrasonic transmitting medium or means and towards an object to be detected. The transmitter can be operatively coupled to an ultrasonic sensor configured to detect portions of the ultrasonic wave that are reflected from the object. For example, in ultrasonic fingerprint image captors, an ultrasonic pulse can be produced by starting and stopping the transmitter for a very short time. At each material interface encountered by the ultrasonic pulse, a portion of the ultrasonic pulse is reflected.
[0004] [0004] For example, in the context of an ultrasonic fingerprint image capture, the ultrasonic wave can travel across a glass plate (platen) on which a person's finger can be placed to obtain a fingerprint image . After passing through the glass plate, some portions of the ultrasonic wave find the skin that is in contact with the glass plate, for example, fingerprint grooves, while other portions of the ultrasonic wave find air, for example, depressions between adjacent grooves of a fingerprint, and can be reflected with different intensities back to the ultrasonic sensor. The reflected signals associated with the finger can be processed and converted to a digital value representing the signal strength of the reflected signal. When several of these reflected signals are collected in a distributed area, the digital values of such signals can be used to produce a graphical display of the signal strength over the distributed area, for example, converting the digital values into an image, thus producing an image fingerprint. In this way, an ultrasonic sensor system can be used as a fingerprint image capture or other type of biometric scanning. In some implementations, the detected signal strength can be mapped to a finger contour map that is representative of the depth of the groove structure detail.
[0005] [0005] Ultrasonic sensor systems can be incorporated into display devices such as fingerprint sensor systems to authenticate a user. Advances in display devices have resulted in flexible screens, three-dimensional protective glass, and frameless designs. Consequently, more and more display devices have limited space to incorporate a discrete button for a fingerprint sensor system or a fingerprint sensor system under glass that is positioned peripherally to the display device screen. A fingerprint sensor system under screen and under glass can provide additional functionality and space to the display device and can open additional authentication software applications for better user interfaces. SUMMARY
[0006] [0006] The devices, systems and methods of the present invention each have several aspects, none individually being solely responsible for the desirable attributes disclosed herein.
[0007] [0007] An aspect of the object of the present invention can be implemented in an apparatus. The device includes a screen, an ultrasonic sensor system underlying the screen and is configured to transmit and receive ultrasonic waves in an acoustic path through the screen, a light blocking layer between the ultrasonic sensor system and the screen, the blocking of light positioned in the acoustic path, and an adhesive layer between the screen and the ultrasonic sensor system. The adhesive layer is positioned on the acoustic path and configured to allow the ultrasonic sensor system to be separated from the screen.
[0008] [0008] In some implementations, the device even includes an electrical shield layer between the ultrasonic sensor system and the screen, the electrical shield layer being electrically conductive and grounded, the electrical shield layer positioned in the acoustic path. Each of the electrical shield layer and the light blocking layer can be non-porous or substantially non-porous. In some implementations, the screen is an organic light-emitting diode (OLED) screen. In some implementations, the screen is a flexible OLED screen formed on a plastic substrate. In some implementations, the adhesive layer includes an epoxy based adhesive, the epoxy based adhesive including a thermoplastic paint. In some implementations, the device even includes a mechanical stress insulation layer between the adhesive layer and the ultrasonic sensor system, in which the mechanical stress insulation layer includes a plastic material. In some implementations, the ultrasonic sensor system includes a sensor substrate having a plurality of sensor pixel circuits disposed therein, a piezoelectric transceiver layer coupled to the sensor substrate and including a piezoelectric material configured to generate the ultrasonic waves, and a layer electrode coupled to the piezoelectric transceiver layer. In some implementations, the piezoelectric transceiver layer includes polyvinylidene fluoride (PVDF), polyvinylidene fluoride and trifluoroethylene copolymer (PVDF-TrFE), lead zirconate titanate (PZT), aluminum nitride (A1N), or composites thereof. In some implementations, the sensor substrate comprises a material selected from the group consisting of: glass, plastic, silicon and stainless steel.
[0009] [0009] Another innovative aspect of the object described in the present disclosure can be implemented in a device. The device includes a screen, an ultrasonic sensor system underlying the screen and configured to transmit and receive ultrasonic waves in an acoustic path through the screen, and an adhesive layer between the ultrasonic sensor system and the screen, the adhesive layer positioned on the path acoustic.
[0010] [0010] In some implementations, the device even includes a mechanical stress insulation layer between the adhesive layer and the ultrasonic sensor system, the mechanical stress insulation layer including a plastic material and positioned in the acoustic path. In some implementations, the ultrasonic sensor system covers all or a substantial part of an active area of the screen. In some implementations, the screen is an organic light-emitting diode (OLED) screen. In some implementations, the adhesive layer is reworkable and configured to allow the ultrasonic sensor system to be separated from the screen, the adhesive layer including a pressure sensitive adhesive or an epoxy based adhesive. In some implementations, the device even includes a light blocking layer between the adhesive layer and the screen, the light blocking layer positioned on the acoustic path, and an electrical shielding layer between the adhesive layer and the screen, the electrical shielding being electrically conductive and grounded, the electrical shielding layer positioned in the acoustic path, in which each of the light blocking layer and the electrical shielding layer is non-porous or substantially non-porous.
[0011] [0011] Another innovative aspect of the object described in the present disclosure can be implemented in a device. The device includes a screen, an ultrasonic sensor system underlying the screen and configured to transmit and receive ultrasonic waves in an acoustic path through the screen, and a multifunctional film between the ultrasonic sensor system and the screen, in which the multifunctional film includes a light blocking layer, an electrical shielding layer, an adhesive layer, a mechanical stress insulation layer, or combinations thereof, the multifunctional film positioned in the acoustic path.
[0012] [0012] Another innovative aspect of the object described in the present disclosure can be implemented in a method of manufacturing an appliance. The method includes providing a display device, in which the display device includes a glass plate and a screen underlying the glass plate, attaching a light blocking layer, an electrical shield layer, a mechanical voltage insulation layer or combinations thereof to the screen, in which the electrical shielding layer is electrically conductive and grounded, and attaching an ultrasonic sensor system to the light blocking layer, the electrical shielding layer, the mechanical stress insulation layer, or combinations of them, in which the ultrasonic sensor system is underlying the screen and configured to transmit and receive ultrasonic waves in an acoustic path through the screen and the glass plate, in which the light blocking layer, the electrical shielding layer, the mechanical stress insulation layer or combinations thereof are in the acoustic path.
[0013] [0013] In some implementations, fixing the light blocking layer, the electrical shielding layer, the mechanical stress insulation layer or combinations thereof includes laminating the light blocking layer, the electrical shielding layer, the mechanical stress insulation or combinations thereof to the screen. In some implementations, the method even includes attaching an adhesive layer to the screen to allow at least the ultrasonic sensor system to be separated from the screen, where the adhesive layer is positioned in the acoustic path.
[0014] [0014] Another innovative aspect of the object described in the present disclosure can be implemented in a device. The device includes a screen, and an ultrasonic sensor system underlying the screen and configured to transmit and receive ultrasonic waves in an acoustic path through the screen. The ultrasonic sensor system includes a flexible substrate including a plurality of sensor pixel circuits disposed therein, and a piezoelectric transceiver layer coupled to the flexible substrate and including a piezoelectric material configured to generate the ultrasonic waves. The device also includes a first layer of high acoustic impedance between the piezoelectric transceiver layer and the screen.
[0015] [0015] In some implementations, the first layer of high acoustic impedance includes one or both of a light blocking layer and an electrical shielding layer. In some implementations, the first layer of high acoustic impedance includes an electrode layer adjacent to the piezoelectric transceiver layer. In some implementations, the layer with a high acoustic impedance value has an acoustic impedance value greater than about 5.0 MRayls. The device also includes an adhesive layer between the screen and the ultrasonic sensor system, the adhesive layer positioned on the acoustic path and configured to allow the ultrasonic sensor system to be separated from the screen. In some implementations, the flexible substrate includes polyethylene terephthalate (PET), polyethylene naphthalate (PEN), a polyimide, stainless steel sheet, thin film silicon, or other flexible material. In some implementations, the device even includes a second layer of high acoustic impedance on the rear side of the ultrasonic sensor system. BRIEF DESCRIPTION OF THE DRAWINGS
[0016] [0016] Details of one or more implementations of the object described in this specification are presented in the attached drawings and in the description below. Other features, aspects and advantages will become evident from the description, drawings and claims. Note that the relative dimensions of the figures below may not be scaled.
[0017] [0017] Equal designations and reference numbers in the various drawings indicate equal elements.
[0018] [0018] Figure 1 shows a front view of a diagrammatic representation of an exemplary mobile device that includes an ultrasonic detection system according to some implementations.
[0019] [0019] Figure 2A shows a block diagram representation of components of an exemplary ultrasonic detection system according to some implementations.
[0020] [0020] Figure 2B shows a block diagram representation of components of an exemplary mobile device that includes the ultrasonic detection system of Figure 2A.
[0021] [0021] Figure 3A shows a cross-sectional view of a diagrammatic representation of a portion of an exemplary ultrasonic detection system according to some implementations.
[0022] [0022] Figure 3B shows an enlarged cross-sectional side view of the exemplary ultrasonic detection system of Figure 3A according to some implementations.
[0023] [0023] Figure 4A shows an exploded view of exemplary components of the exemplary ultrasonic detection system of Figures 3A and 3B according to some implementations.
[0024] [0024] Figure 4B shows an exploded view of exemplary components of an ultrasonic transceiver matrix in an ultrasonic sensor system of Figures 3A and 3B according to some implementations.
[0025] [0025] Figure 5 shows an example of using a fingerprint sensor in which the fingerprint sensor is not under the screen according to some implementations.
[0026] [0026] Figure 6 shows an example of using a fingerprint sensor, where the fingerprint sensor is under the screen according to some implementations.
[0027] [0027] Figure 7 shows a cross-sectional view of an ultrasonic sensor system under an exemplary glass plate with a flexible printed circuit (FPC).
[0028] [0028] Figure 8A shows a schematic cross-sectional view of an exemplary device including a glass plate and a screen underlying the glass plate according to some implementations.
[0029] [0029] Figure 8B shows a schematic cross-sectional view of an exemplary ultrasonic fingerprint sensor system according to some implementations.
[0030] [0030] Figure 9A shows a schematic cross-sectional view of an exemplary device including a glass plate, a screen underlying the glass plate and a light blocking layer and an electrical shield layer underlying the screen according to some implementations.
[0031] [0031] Figure 9B shows a schematic cross-sectional view of an exemplary ultrasonic fingerprint sensor system to be coupled or attached to the device of Figure 9A and to be underlying the screen according to some implementations.
[0032] [0032] Figure 10A shows a schematic cross-sectional view of an exemplary device including an ultrasonic fingerprint sensor system underlying a screen and an acoustic path of the ultrasonic fingerprint sensor system according to some implementations.
[0033] [0033] Figure 10B shows a schematic cross-sectional view of an exemplary device including an ultrasonic fingerprint sensor system underlying a screen and an acoustic path of the ultrasonic fingerprint sensor system according to some other implementations.
[0034] [0034] Figures 11A-11F show schematic cross-sectional views of several exemplary ultrasonic sensor systems in a "receiver down" orientation according to some implementations.
[0035] [0035] Figures 12A-12F show schematic cross-sectional views of several exemplary ultrasonic sensor systems in a "receiver up" orientation according to some implementations.
[0036] [0036] Figures 13A-13B show schematic cross-sectional views of several exemplary ultrasonic sensor systems including a foam support layer according to some implementations.
[0037] [0037] Figure 14A shows a schematic cross-sectional view of an exemplary flexible ultrasonic sensor system in a “receiver up” orientation according to some implementations.
[0038] [0038] Figure 14B shows a schematic cross-sectional view of an exemplary flexible ultrasonic sensor system in a “receiver down” orientation according to some implementations.
[0039] [0039] Figure 15 shows data of acoustic signals reflected in "soft" and "hard" substrates and with different layers overlapping and / or underlying the "soft" substrates.
[0040] [0040] Figures 16A-16D show schematic cross-sectional views of several exemplary devices including a screen and incorporating a light blocking layer, an electrical shielding layer and an ultrasonic sensor system underlying the screen.
[0041] [0041] Figure 17 shows an exemplary method of manufacturing a device including an ultrasonic sensor system underlying a screen.
[0042] [0042] Figure 18 shows an example of using a capacitive detection mode and an ultrasonic detection mode with an ultrasonic fingerprint sensor positioned behind an electronic device screen to activate the electronic device.
[0043] [0043] Figure 19 shows a schematic cross-sectional side view of a configuration with an ultrasonic fingerprint sensor positioned behind a screen of a mobile device.
[0044] [0044] Figure 20 shows an example of a flowchart for a method of orienting a user of an OLED or LCD screen device to position a finger above a fingerprint sensor under LCD or under OLED. DETAILED DESCRIPTION
[0045] [0045] The following description refers to certain implementations in order to describe the innovative aspects of the present invention. However, a person ordinarily skilled in the art will readily recognize that the teachings presented here can be applied in several different ways.
[0046] [0046] An on-screen fingerprint sensor system can be provided on a display device or device. Many high-end screens use organic light-emitting diode (OLED) screens or organic active-matrix LED (AMOLED) screens. Some screens of the present invention can be provided on organic light-emitting diode (pOLED) screens, which can also be called flexible OLED screens. Capacitive-based fingerprint sensors may require electromagnetic signals that can interfere with the electrical functions of the screen. Signals generated or transferred within the screen along with associated conductive traces can reduce the capacitive fingerprint detection capability. Optical-based digital printing systems can be limited or rendered unusable when the display devices include a light blocking layer or a large number of metal traces. An ultrasonic-based fingerprint sensor can be incorporated into a display device on a screen. The ultrasonic-based fingerprint sensor can be incorporated under the screen of a display device with a light blocking layer and without interfering with the electrical functions of the display device.
[0047] [0047] The configurations and techniques for ultrasonic fingerprint sensor systems described in this document may be suitable for use with flexible screens, curved screens, curved protective glasses and 2.5D or three-dimensional screens under development. The ultrasonic image of fingerprints is largely unaffected by small features on OLED screens and other types of screens, such as pixels or touch screen electrodes. As the ultrasonic and electrical domains are inherently different, the interference between the electro-optical and electro-acoustic domains is reduced. Interference and unwanted interactions between the ultrasonic fingerprint sensor system and other portions of the screen are still reduced or minimized in part due to the use of light blocking layers, reduction of electromagnetic interference (EMI), electrical shielding, voltage, heat dissipation and heat radiation that are described below.
[0048] [0048] The ultrasonic based fingerprint sensor is configured to transmit and receive ultrasonic waves in an acoustic path through a display device screen. At least one of a light blocking layer and an electrical shielding layer can be positioned between the ultrasonic based fingerprint sensor and the screen, where the light blocking layer and the electrical shielding layer can be in the path acoustic. In some implementations, each of the light blocking layer and the electrical shielding layer is substantially non-porous. In some implementations, a mechanical stress insulation layer can be placed between the ultrasonic-based fingerprint sensor and the screen. Specifically, the mechanical stress insulation layer can include a plastic material, and the mechanical stress insulation layer can be positioned between an adhesive layer underlying the screen and the ultrasonic-based fingerprint sensor. In some implementations, the ultrasonic-based fingerprint sensor may include a piezoelectric layer and an array of pixel circuits arranged on a flexible substrate, in which a layer of high acoustic impedance is arranged between the piezoelectric layer and the screen. In some implementations, an additional high acoustic impedance layer may be arranged between the piezoelectric layer and a surface opposite the screen, where the additional high acoustic impedance layer is not in the acoustic path. In some implementations, a low acoustic impedance layer is placed between the piezoelectric layer and the screen to create an impedance mismatch. High or low acoustic impedance layers create acoustic impedance mismatches to reflect more acoustic energy at interfaces between the high and low acoustic impedance layers. In some implementations, the ultrasonic-based fingerprint sensor may include a porous foam backing layer underlying the piezoelectric layer. In some implementations relating to flexible or foldable screens, the ultrasonic-based fingerprint sensor may include a piezoelectric layer and an array of pixel circuits arranged on a flexible plastic substrate, where the flexible plastic substrate is coupled to and extends from edge to edge. edge with the flexible screen.
[0049] [0049] Particular implementations of the object described in the present disclosure can be implemented to realize one or more of the following potential advantages. An on-screen fingerprint sensor increases the functionality of the active screen area of a display device. In addition, an on-screen fingerprint sensor can reduce form factors and can be incorporated into frameless display devices. On-screen configurations allow for more active sensor areas for better performance, more flexibility in sensor placement and a better user experience. A light blocking layer can provide a mechanical function in the display device by providing insulation from mechanical stress and can provide an optical function by providing a non-reflective absorption layer so that visible light does not penetrate. Ultrasonic fingerprint sensor systems can transmit and receive ultrasonic waves through light blocking layers.
[0050] [0050] Figure 1 shows a diagrammatic representation of an exemplary mobile device 100 that includes an ultrasonic detection system according to some implementations. Mobile device 100 may be representative of, for example, various portable computing devices, such as cell phones, smartphones, smart watches, multimedia devices, personal gaming devices, tablets and laptops, among other types of portable computing devices. However, several implementations described in this document are not limited in application to portable computing devices. In fact, several principles and techniques disclosed here can be applied to traditionally non-portable devices and systems, such as computer monitors, television screens, kiosks, vehicle navigation devices and audio systems, among other applications. In addition, several implementations described in this document are not limited in application to devices that include screens.
[0051] [0051] The mobile device 100 generally includes a housing (also known as "compartment" or "box") 102 within which various circuits, sensors and other electrical components reside. In the exemplary implementation illustrated, the mobile device 100 also includes a touch screen (also referred to here as a “touch screen”) 104. The touch screen 104 generally includes a screen and a touch screen arranged over or otherwise embedded or integrated into the screen. Screen 104 can generally be representative of any of a variety of suitable screen types that employ any of a variety of suitable display technologies. For example, screen 104 can be a digital micro-shutter (DMS) based screen, a light emitting diode (LED) screen, an organic LED screen (OLED), a liquid crystal screen (LCD), a LCD screen that uses LEDs as a backlight, a plasma screen, a screen based on an interferometric modulator (IMOD) or another type of screen suitable for use in conjunction with touch-sensitive user interface (UI) systems.
[0052] [0052] The mobile device 100 may include several other devices or components to interact with or otherwise communicate information or receive information from a user. For example, the mobile device
[0053] [0053] The mobile device 100 may include an ultrasonic detection system 118 capable of scanning and generating images of an object signature, such as a fingerprint, palm print or hand print. In some implementations, the 118 ultrasonic detection system can function as a touch sensitive control button. In some implementations, a touch sensitive control button can be implemented with a pressure sensitive mechanical or electrical system that is positioned under or otherwise integrated with the 118 ultrasonic detection system. In other words, in some implementations, a busy region by the ultrasonic detection system 118 it can function as a user input button to control the mobile device 100, as well as a fingerprint sensor to activate security features, such as user authentication features. In some implementations, the 118 ultrasonic detection system can be positioned under the screen protection glass or under a part of the screen itself, as described in this document. In some implementations, the ultrasonic detection system 118 can be positioned on a side wall or at the rear of the housing of the mobile device 102.
[0054] [0054] Figure 2A shows a block diagram representation of components of an exemplary ultrasonic detection system 200 according to some implementations. As shown, the ultrasonic detection system 200 can include a sensor system 202 and a control system 204 electrically coupled to sensor system 202. Sensor system 202 may be able to scan an object and provide useful measured raw image data to obtain an object signature, such as, for example, a fingerprint of a human finger. The control system 204 may be able to control the sensor system 202 and process the raw measured image data received from the sensor system. In some implementations, the ultrasonic detection system 200 may include an interface system 206 capable of transmitting or receiving data, such as raw or processed measured image data, to or from various components within or integrated with the ultrasonic detection system 200 or, in some implementations, to or from various components, devices or other systems external to the ultrasonic detection system.
[0055] [0055] Figure 2B shows a block diagram representation of components of an exemplary mobile device 210 that includes the ultrasonic detection system 200 of Figure 2A. For example, mobile device 210 can be a block diagram representation of mobile device 100 shown in and described with reference to Figure 1 above. The sensor system 202 of the ultrasonic detection system 200 of the mobile device 210 can be implemented with an ultrasonic sensor array 212. The control system 204 of the ultrasonic detection system 200 can be implemented with a controller 214 which is electrically coupled to the matrix ultrasonic sensor 212. Although controller 214 is shown and described as a single component, in some implementations, controller 214 may collectively refer to two or more separate control units or processing units in electrical communication with each other. In some implementations, controller 214 may include one or more of a general purpose single-chip or multi-chip processor, a central processing unit (CPU), a digital signal processor (DSP), an application processor, a application-specific integrated circuit (ASIC), an array of field programmable ports (FPGA) or other programmable logic device (PLD), discrete port or transistor logic, discrete hardware components, or any combination thereof designed to perform the functions and operations described in this document.
[0056] [0056] The ultrasonic detection system 200 of Figure 2B can include an image processing module
[0057] [0057] In some implementations, in addition to the ultrasonic detection system 200, the mobile device 210 may include a separate processor 220, a memory 222, an interface 216 and a power supply 224. In some implementations, the controller 214 of the system ultrasonic detection 200 can control ultrasonic sensor array 212 and image processing module 218, and processor 220 of mobile device 210 can control other components of mobile device 210. In some implementations, processor 220 communicates data to controller 214 including , for example, instructions or commands. In some of these implementations, controller 214 can communicate data to processor 220 including, for example, raw or processed image data (also referred to as "image information"). It should also be understood that, in some other implementations, the functionality of controller 214 can be fully implemented, or at least partially, by the processor
[0058] [0058] Depending on the implementation, one or both controller 214 and processor 220 may store data in memory 222. For example, data stored in memory 222 may include raw measured image data, filtered or otherwise processed image data , estimated image data, or final refined image data. Memory 222 can store executable code per processor or other executable computer-readable instructions capable of executing by one or both controller 214 and processor 220 to perform various operations (or cause other components, such as the ultrasonic sensor array 212, the image processing module 218, or other modules for performing operations), including any of the calculations, computations, estimates, or other determinations described in this document. It should also be understood that memory 222 can collectively refer to one or more memory devices (or "components"). For example, depending on the implementation, the 214 controller can access and store data on a memory device other than the processor
[0059] [0059] In some implementations, controller 214 or processor 220 may communicate data stored in memory 222 or data received directly from the image processing module 218 through an interface 216. For example, such communicated data may include image data or derived data or otherwise determined from the image data. Interface 216 can collectively refer to one or more interfaces of one or more various types. In some implementations, interface 216 may include a memory interface for receiving data from or storing data in external memory, such as a removable memory device. Additionally or alternatively, interface 216 may include one or more wireless network interfaces or one or more cable network interfaces allowing the transfer of raw or processed data to, as well as receiving data from, an external computing device, system or server.
[0060] [0060] A power supply 224 can supply power to some or all components of the mobile device 210. Power supply 224 can include one or more of a variety of energy storage devices. For example, power supply 224 may include a rechargeable battery, such as a nickel-cadmium battery or a lithium ion battery. In addition or alternatively, power supply 224 may include one or more supercapacitors. In some implementations, the 224 power supply may be chargeable (or "rechargeable") using the energy accessed from, for example, a wall outlet (or "outlet") or a photovoltaic device (or "solar cell" or "matrix" of solar cells ”) integrated with the mobile device 210. Additionally or alternatively, the power supply 224 can be charged wirelessly. The power supply 224 can include an integrated power management circuit and a power management system.
[0061] [0061] As used below, the term “processing unit” refers to any combination of one or more of an ultrasonic system controller (for example, controller 214), an image processing module (for example , the image processing module 218) or a processor separate from a device that includes the ultrasonic system (for example, processor 220). In other words, the operations that are described below as being performed by or using a processing unit can be performed by one or more of an ultrasonic system controller, an image processing module or a processor separate from a device that includes the system ultrasonic detection.
[0062] [0062] Figure 3A shows a cross-sectional projection view of a diagrammatic representation of a portion of an exemplary ultrasonic detection system 300 according to some implementations. Figure 3B shows an enlarged cross-sectional side view of the exemplary ultrasonic detection system 300 of Figure 3A according to some implementations. For example, the ultrasonic detection system 300 can implement the ultrasonic detection system 118 described with reference to Figure 1 or the ultrasonic detection system 200 shown and described with reference to Figure 2A and Figure 2B. The ultrasonic detection system 300 can include an ultrasonic transducer 302 superimposed on a substrate 304 and underlying a glass plate (for example, a “protective plate” or “protective glass”) 306. The ultrasonic transducer 302 can include both a ultrasonic transmitter 308 and an ultrasonic receiver 310.
[0063] [0063] The ultrasonic transmitter 308 is generally configured to generate and transmit ultrasonic waves towards the glass plate 306 and, in the illustrated implementation, towards a human finger 312 positioned on the upper surface of the glass plate 306. In some implementations, the ultrasonic transmitter 308 can, more specifically, be configured to generate and transmit flat ultrasonic waves towards the glass plate 306. For example, the piezoelectric material of the ultrasonic transmitter 308 can be configured to convert electrical signals provided by the detection system controller ultrasonic in a continuous or pulsed sequence of flat ultrasonic waves at a scan frequency. In some implementations, the ultrasonic transmitter 308 includes a layer of piezoelectric material, such as, for example, polyvinylidene fluoride (PVDF) or a PVDF copolymer, such as PVDF-TrFE. In some implementations, other piezoelectric materials can be used in the ultrasonic transmitter 308 and / or the ultrasonic receiver 310, such as aluminum nitride (A1N), lead zirconate titanate (PZT) or bismuth sodium titanate. In some implementations, the ultrasonic transmitter 308 and / or the ultrasonic receiver 310 may, additionally or alternatively, include ultrasonic capacitive devices, such as micro-machined capacitive ultrasonic transducers (CMUTs) or piezoelectric ultrasonic devices, such as piezoelectric micro-ultrasonic transducers (PMUTs, also referred to as “piezoelectric micromechanical ultrasonic transducers”).
[0064] [0064] The ultrasonic receiver 310 is generally configured to detect ultrasonic reflections 314 resulting from interactions of the ultrasonic waves transmitted by the ultrasonic transmitter 308 with grooves 316 and valleys 318 that define the fingerprint of the finger 312 being scanned. In some implementations, the ultrasonic transmitter 308 overlays the ultrasonic receiver 310 as, for example, illustrated in Figures 3A and 3B. In some implementations, the ultrasonic receiver 310 may override the ultrasonic transmitter 308 (as shown in Figure 4A described below). The ultrasonic receiver 310 can be configured to generate and emit electrical output signals corresponding to the detected ultrasonic reflections. In some implementations, the ultrasonic receiver 310 may include a second piezoelectric layer different from the piezoelectric layer of the ultrasonic transmitter 308. For example, the piezoelectric material of the ultrasonic receiver 310 can be any suitable piezoelectric material, such as, for example, a PVDF layer or a PVDF-TrFE copolymer. The piezoelectric layer of the ultrasonic receiver 310 can convert vibrations caused by ultrasonic reflections to electrical output signals. In some implementations, the 310 ultrasonic receiver even includes a thin film transistor (TFT) layer. In some of these implementations, the TFT layer may include an array of sensor pixel circuits configured to amplify or dampen the electrical output signals generated by the piezoelectric layer of the ultrasonic receiver 310. The electrical output signal signals provided by the circuit matrix of sensor pixels can then be supplied as raw measured image data to the processing unit for use in processing the image data, identifying a fingerprint associated with the image data and, in some applications, user authentication associated with fingerprint. In some implementations, a single piezoelectric layer can serve as the ultrasonic transmitter 308 and the ultrasonic receiver 310 (as shown in Figure 4B below). In some implementations, substrate 304 may be a substrate of glass, plastic or silicon, on which electronic circuits can be manufactured. In some implementations, an array of sensor pixel circuits and associated interface circuits of the ultrasonic receiver 310 can be configured from CMOS circuits formed on substrate 304. In some implementations, substrate 304 can be positioned between the glass plate 306 and the ultrasonic transmitter 308 and / or the ultrasonic receiver 310. In some implementations, substrate 304 can serve as a 306 glass plate. One or more protective layers, acoustic correspondence layers, anti-stain layers, adhesive layers, decorative layers, conductive layers or other coating layers (not shown) can be included on one or more sides of substrate 304 and glass plate 306.
[0065] [0065] The glass plate 306 can be formed of any suitable material that can be acoustically coupled to the ultrasonic transmitter 308. For example, the glass plate 306 can be formed of one or more of glass, plastic, ceramic, sapphire, metal or metal alloy. In some implementations, the glass plate 306 can be a protective plate, such as, for example, a protective glass or a glass lens from an underlying screen. In some implementations, the glass plate 306 may include one or more polymers, such as one or more types of parylene, and may be substantially thinner. In some implementations, the 306 glass plate can have a thickness in the range of about 10 microns (μm) to about 1000 μm or more.
[0066] [0066] In some implementations, the ultrasonic detection system 300 may also include a focusing layer (not shown). For example, the focusing layer can be positioned above the 308 ultrasonic transmitter. The focusing layer can generally include one or more acoustic lenses capable of altering the ultrasonic wave paths transmitted by the 308 ultrasonic transmitter. In some implementations, the lenses can be implemented as cylindrical lenses, spherical lenses or zone lenses. In some implementations, some or all of the lenses may be concave lenses, while in some other implementations, some or all of the lenses may be convex lenses or include a combination of concave and convex lenses.
[0067] [0067] In some implementations that include this focusing layer, the ultrasonic detection system 300 may additionally include an acoustic matching layer to ensure proper acoustic coupling between the focusing lens and an object, such as a finger, positioned on the plate of glass
[0068] [0068] Figure 4A shows an exploded view of exemplary components of the exemplary ultrasonic detection system 300 of Figures 3A and 3B according to some implementations. The ultrasonic transmitter 308 may include a substantially flat piezoelectric transmitting layer 422 capable of functioning as a flat wave generator. Ultrasonic waves can be generated by applying a voltage across the piezoelectric transmitting layer 422 to expand or contract the layer, depending on the voltage signal applied, thus generating a flat wave. In this example, the processing unit (not shown) is capable of causing a transmitter excitation voltage to be applied to the piezoelectric transmitter layer 422 through a first transmitter electrode 424 and a second transmitter electrode
[0069] [0069] Ultrasonic waves can move towards a target object, such as a finger, passing through the glass plate 306. A portion of the ultrasonic waves not absorbed or transmitted by the target object can be reflected back through the plate glass 306 and received by the ultrasonic receiver 310, which, in the implementation illustrated in Figure 4A, overlaps the ultrasonic transmitter 308. The ultrasonic receiver 310 may include a matrix of sensor pixel circuits 432 arranged on a substrate 434 and a piezoelectric receiving layer 436. In some implementations, each 432 sensor pixel circuit may include one or more TFT or silicon-based CMOS transistor elements, electrical interconnect traces, and in some implementations, one or more additional circuit elements, such as diodes, capacitors and the like. Each sensor pixel circuit 432 can be configured to convert the surface charge generated in the piezoelectric receiving layer 436 next to the pixel circuit into an electrical signal. Each sensor pixel circuit 432 can include a pixel input electrode 438 that electrically couples the piezoelectric receiving layer 436 to the sensor pixel circuit
[0070] [0070] In the illustrated implementation, a receiver polarization electrode 440 is disposed on one side of the piezoelectric receiver layer 436 next to the glass plate 306. The receiver polarization electrode 440 can be a metallized electrode and can be grounded or polarized to control which the signals can be transmitted to the array of sensor pixel circuits 432. The ultrasonic energy that is reflected from the exposed (top / top) surface 442 of the glass plate 306 can be converted into the surface charge by the piezoelectric receiving layer 436. The charge generated surface can be coupled to the pixel input electrodes 438 and underlying the pixel circuits of sensor 432. The charge signal can be amplified or damped by the pixel circuits of sensor 432 and provided to the processing unit. The processing unit can be electrically connected (directly or indirectly) with the first transmitting electrode 424 and the second transmitting electrode 426, as well as with the receiving polarization electrode 440 and the sensor pixel circuits 432 on the substrate 434. In some implementations , the processing unit can function substantially, as described above. For example, the processing unit may be able to process the signals received from the 432 sensor pixel circuits.
[0071] [0071] Some examples of suitable piezoelectric materials that can be used to form the piezoelectric transmitting layer 422 or the piezoelectric receiving layer 436 include piezoelectric polymers having appropriate acoustic properties, for example, an acoustic impedance between 2.5 MRayls and 5 MRayls. Specific examples of piezoelectric materials that can be used include ferroelectric polymers, such as polyvinylidene fluoride (PVDF) and polyvinylidene-trifluoroethylene fluoride (PVDF-TrFE) copolymers. Examples of PVDF copolymers include 60:40 (mole percent) PVDF-TrFE, 70:30 PVDF-TrFE, 80:20 PVDF-TrFE and 90:10 PVDR-TrFE. Other examples of piezoelectric materials that can be used include polyvinylidene chloride (PVDC) homopolymers and copolymers, polytetrafluoroethylene (PTFE) and diisopropylammonium bromide (DIPAB) homopolymers and copolymers. In some implementations, other piezoelectric materials can be used in the piezoelectric transmitting layer 422 and / or in the piezoelectric receiving layer 436, such as aluminum nitride (AIN), lead zirconate titanate (PZT) or bismuth sodium titanate.
[0072] [0072] The thickness of each of the piezoelectric transmitting layer 422 and the piezoelectric receiving layer 436 is selected so as to be suitable for generating and receiving ultrasonic waves, respectively. In one example, a PVDF 422 piezoelectric transmitting layer is approximately 28 μm thick and a PVDF-TrFE 436 receiving layer is approximately 12 μm thick. Exemplary frequencies of ultrasonic waves can be in the range of about 1 megahertz (MHz) to about 100 MHz, with wavelengths on the order of one millimeter or less.
[0073] [0073] Figure 4B shows an exploded view of exemplary components of an ultrasonic transceiver matrix in an ultrasonic detection system 300 of Figures 3A and 3B according to some implementations. In this example, the ultrasonic detection system 300 includes an ultrasonic transceiver matrix 450 under a glass plate 306. The ultrasonic transceiver matrix 450 can serve as the ultrasonic sensor matrix 212 which is shown in Figure 2B and described above. The ultrasonic transceiver matrix 450 may include the substantially flat piezoelectric transceiver layer 456 capable of functioning as a plane wave generator. Ultrasonic waves can be generated by applying a voltage across the transceiver layer
[0074] [0074] The ultrasonic transceiver array 450 may include an array of sensor 432 pixel circuits arranged on a sensor substrate 434. In some implementations, each sensor 432 pixel circuit may include one or more elements based on TFT or silicon, traces of electrical interconnection and, in some implementations, one or more additional circuit elements, such as diodes, capacitors and the like. Each sensor pixel circuit 432 can include a pixel input electrode 438 that electrically couples the piezoelectric transceiver layer 456 to the sensor pixel circuit 432.
[0075] [0075] In the illustrated implementation, the transceiver polarization electrode 460 is disposed on one side of the piezoelectric transceiver layer 456 next to the glass plate
[0076] [0076] The control system 204 can be electrically connected (directly or indirectly) to the polarization electrode transceiver 460 and to the pixel circuits of sensor 432 on sensor substrate 434. In some implementations, the control system 204 can function substantially as described above. For example, the control system 204 may be able to process the amplified or damped electrical output signals received from the 432 sensor pixel circuits.
[0077] [0077] The control system 204 may be able to control the ultrasonic transceiver matrix 450 to obtain ultrasonic image data, which may include fingerprint image data. According to some implementations, the control system 204 may be able to provide functionality, as described in this document, for example, as described in this document with reference to Figures 1-3B, 5-14B, and 16A-16D.
[0078] [0078] In other examples of an ultrasonic sensor system with an ultrasonic transceiver matrix, the rear part of sensor substrate 434 can be directly or indirectly coupled to an underlying glass plate 306. In operation, the ultrasonic waves generated by the transceiver layer piezoelectric 456 can travel through sensor substrate 434 and glass plate 306, reflect off the surface 442 of glass plate 306, and travel back through the glass plate
[0079] [0079] Many electronic devices, including mobile devices and smartphones, use fingerprint authentication as a method of access control. An ultrasonic fingerprint sensor can authenticate a user's fingerprint, in which ultrasonic waves generated by a piezoelectric material can travel through a glass plate on which a person's finger is placed. Some portions of an ultrasonic wave find the skin that is in contact with the glass plate, for example, fingerprint grooves, while other portions of an ultrasonic wave find the air, for example, valleys between two fingerprint grooves. The ultrasonic waves are reflected back at different intensities towards an ultrasonic sensor array. The reflected signals associated with the finger can be processed and converted to a digital value representing the signal strength of the reflected signal, and a fingerprint image can be obtained.
[0080] [0080] Figure 5 shows an example of using a fingerprint sensor in which the fingerprint sensor is not under the screen according to some implementations. In Figure 5, an electronic device 505 (for example, mobile device 210) includes a controller circuit (for example, controller 214 in Figure 2B) that can operate a 525 sensor (for example, at least one of the ultrasonic sensors or ultrasonic sensor array 212 of the 202 ultrasonic sensor system in Figure 2B). In some implementations, the controller circuit can switch sensor 525 to operate between a capacitive detection mode and an ultrasonic detection mode. For example, the 525 sensor can be configured to be in a capacitive detection mode to determine whether an object has touched or is positioned close to the polarization electrode receiving the ultrasonic sensor and then subsequently configured to be in an ultrasonic detection mode for determine if that object is a 515 finger.
[0081] [0081] As shown in Figure 5, at time 550, a finger 515 is placed above sensor 525 which is part of an ultrasonic authentication button (for example, “home button”) of electronic device 505. In some implementations, the sensor 525 can be part of an electromechanical button that can authenticate a user and is inserted through a clipping region in the protective glass of screen 510. Consequently, sensor 525 can be positioned separately from where the visual content of the image is displayed on screen 510. At time 550, electronic device 505 may be in a locked, off state, or in a relatively low power “sleep” mode. An object or finger 515 can be determined to have been positioned close to or on the screen 510, sensor 525 or another detection electrode. Then, at time 555, the controller circuit can “activate” an application processor and cause screen 510 to be activated if a fingerprint of the 515 finger is authenticated. For example, an application processor can obtain the fingerprint image data (for example, receiving the corresponding data stored in memory by the controller circuit) and then determine whether the fingerprint image data represents a fingerprint of an authorized user of the electronic device
[0082] [0082] Figure 6 shows an example of using a fingerprint sensor in which the fingerprint sensor is under the screen according to some implementations. In Figure 6, an electronic device 605 (for example, mobile device 210) includes a controller circuit (for example, controller 214 in Figure 2B) that can operate a 625 sensor (for example, at least one of the ultrasonic sensors or ultrasonic sensor array 212 of the 202 ultrasonic sensor system in Figure 2B). In contrast to Figure 5, where sensor 525 is placed in a cutout region of the screen protection glass 510, sensor 625 in Figure 6 is placed in a region of screen 610 through which the visual image content can be displayed. Having sensor 625 in a screen area of screen 610 can improve the user interface and increase the functionality of screen 610 of electronic device 605. Sensor 625 does not have to be part of an electromechanical button as discussed in Figure 5. Therefore , when a finger 615 is placed close to or on sensor 625, sensor 625 can authenticate a user's fingerprint. The 625 sensor can authenticate the user's fingerprint using an ultrasonic fingerprint sensor system as described below.
[0083] [0083] Figure 7 shows a cross-sectional view of an ultrasonic sensor system under an exemplary glass plate with a flexible printed circuit (FPC). In Figure 7, an ultrasonic sensor system 700 is located underneath or under the glass plate 710. The glass plate 710 can be considered “in front of”, “above” or “superimposed” on the ultrasonic sensor system 700, and the ultrasonic sensor system 700 can be considered "behind", "below" or "underlying" the glass plate 710. Such terms as used in this document are relative terms depending on the orientation of the device. In some implementations, the 700 ultrasonic sensor system is attached to the glass plate 710 by a first adhesive
[0084] [0084] The ultrasonic sensor system 700 may include a sensor substrate 740, a plurality of sensor circuits 745 arranged on the sensor substrate 740, a transceiver layer 720 and an electrode layer
[0085] [0085] The plurality of sensor circuits 745 can be formed on or on sensor substrate 740, such as TFT circuits formed on a TFT substrate or complementary metal-oxide semiconductor (CMOS) circuits formed on a silicon substrate. In some implementations, the transceiver layer 720 can be positioned on the plurality of sensor circuits 745. The transceiver layer 720 can serve as both an ultrasonic wave transmitter and receiver, where the transceiver layer 720 is configured to transmit at least one ultrasonic signal / wave and receive or detect at least one ultrasonic signal / wave. Therefore, the transceiver layer 720 may include one or more piezoelectric layers and one or more electrode layers to allow the transceiver layer to transmit and receive ultrasonic waves.
[0086] [0086] An ultrasonic wave is an acoustic wave that has a frequency above about 20 kHz. In some implementations, ultrasonic waves have a frequency between about 1 MHz and about 100 MHz, such as between about 5 MHz and about 20 MHz. Acoustic waves are longitudinal waves that have the same direction of vibration as their direction of displacement. Acoustic waves push particles into a medium, whether the medium is a solid, liquid or gas. Acoustic waves move at the speed of sound, which depends on the medium through which they pass. The acoustic impedance in a material measures the opposition to the acoustic flow resulting from an acoustic pressure applied to the material. Acoustic impedance allows the determination of reflection and transmission of acoustic energy in the contours. If the acoustic impedance of two media is very different, then most of the acoustic energy will be reflected, rather than transmitted through the contour. The acoustic impedance can be measured in terms of pascal-seconds per meter (Pa-s / m or kg / s / m2) with Rayls or MRayls units.
[0087] [0087] The plurality of sensor circuits 745 may include a thin film transistor circuit array. For example, sensor circuits 745 may include an array of pixel circuits, where each pixel circuit may include one or more TFTs. A pixel circuit can be configured to convert an electrical charge generated by the transceiver layer close to the pixel circuit into an electrical signal in response to an incoming ultrasonic wave. The output signals from the 745 sensor circuits can be sent to a controller or other circuit for signal processing.
[0088] [0088] In some implementations, the transceiver electrode layer 715 may be arranged, positioned, placed or formed on the transceiver layer 720. The transceiver electrode layer 715 may include one or more electrically conductive layers / strokes that are coupled to the transceiver layer 720. In some implementations, the transceiver electrode layer 715 may include silver ink. In some implementations, the transceiver electrode layer 715 may include copper. Ultrasonic waves can be generated and transmitted by providing an electrical signal to the transceiver electrode layer 715. In addition, a passivation layer (not shown) can be arranged, positioned, placed or formed over at least portions of the transceiver electrode layer 715. A passivation layer may include one or more layers of electrically insulating material. The sensor substrate 740 and the sensor circuits 745, the piezoelectric transceiver layer 720 and the transceiver electrode layer 715 can be positioned under a glass plate 710.
[0089] [0089] Figure 7 shows a flexible printed circuit (FPC) 725 coupled to the sensor substrate 740. However, it will be understood in this report that the sensor substrate 740 can be attached to a rigid printed circuit board (PCB) or other circuits. The FPC 725 can be referred to as a flexible ribbon, flexible cable, flexible circuit or simply “flex”. The FPC 725 can include one or more dielectric layers and one or more interconnections (for example, traces, tracks and pads). In some implementations, the FPC 725 can be electrically coupled to a controller or other circuit for signal processing to / from sensor circuits 745. In some implementations, the FPC 725 may involve a front end of the ultrasonic sensor system 700 on the back side of the 700 ultrasonic sensor system.
[0090] [0090] In Figure 7, the ultrasonic sensor system 700 can be attached to the glass plate 710 using a first adhesive 760 and an edge seal 755. The ultrasonic sensor system 700 can also include a cover or sensor compartment 730 for protect the ultrasonic sensor system 700. The sensor compartment 730 can be attached to a portion of the glass plate 710 via a second adhesive 765 and can be attached to a portion of the sensor substrate 740 and a portion of the FPC 725 via of a third adhesive 750. In some implementations, the sensor compartment 730 can be largely cantilevered over the active area of the sensor substrate 740. The sensor compartment 730 can be coupled to the sensor substrate 740, such that a cavity 735 is formed between the rear side of the sensor substrate 740 and the sensor compartment 730. In some implementations, the sensor compartment 730 may include one or more layers of plastic or metal. In some implementations, the sensor compartment 730 and the cavity 735 may allow the interface between the sensor substrate 740 and the cavity 735 to operate as an acoustic barrier for the ultrasonic sensor system 700. In some implementations, the cavity 735 can provide a space to accommodate an acoustic shield structure that is configured to absorb, retain or otherwise attenuate ultrasonic waves. The FPC 725 may be wrapped in the sensor substrate 740 and in the sensor compartment 730, where the FPC 725 is coupled to the rear side of the sensor compartment 730.
[0091] [0091] An ultrasonic sensor system under glass plate 700 can be provided in a display device as shown in Figure 7, but an ultrasonic sensor system under screen is not necessarily provided in a display device as in a sensor system ultrasonic under screen. Therefore, a display device that includes an ultrasonic sensor system under a screen can be constructed differently from an ultrasonic sensor system under a glass plate.
[0092] [0092] Figure 8A shows a schematic cross-sectional view of an exemplary device including a glass plate and a screen underlying the glass plate according to some implementations. A display device may include an 865 screen, such as a DMS-based screen, an LED screen, an OLED screen, an LCD, a plasma screen, an IMOD-based screen, or another type of screen suitable for use in conjunction with a touch-sensitive user interface. In some implementations, the 865 screen can be modified to reduce or remove air gaps that can impair the ability of ultrasonic imaging. In Figure 8A, screen 865 is an OLED screen underlying the 805 glass plate, such as a protective glass, protective lens or outer layer of the OLED stack or any associated touch screen.
[0093] [0093] The OLED screen 865 in Figure 8A can include a plurality of layers of thin film 810, 815, 820,
[0094] [0094] Typically, an OLED screen 865 can include one or more layers of support 855, 860. The one or more layers of support 855, 860 can separate the OLED screen
[0095] [0095] In some implementations, the one or more layers of support 855, 860 may include an electrical shield layer 860. The electrical shield layer 860 may include one or more electrically conductive materials and may be electrically grounded. The electrical shield layer 860 can serve to prevent or otherwise limit electrical interference on the OLED screen 865, particularly when the OLED screen 865 is in operation or on. For example, the electrical shield layer 860 can limit electrical interference from nearby electronic components, such as a battery charger, digital or analog electronic components, RF components, etc. In addition, the electrical shield layer 860 can provide heat dissipation and improve temperature uniformity at the back of the screen, since high temperature gradients can occur near the OLED screen 865, which can be caused by electronic circuits and other devices (for example, batteries), near the OLED screen 865. In some implementations, the electrical shield layer 860 on the OLED screen 865 may include a thick copper strip. For example, the copper strip can be more than about 50 μm thick, more than about 20 μm thick, more than about 10 μm thick, or more than about 6 μm thick.
[0096] [0096] However, one or both of the light blocking layer 855 and the electrical shielding layer 860, as described above, may include pores, voids or air gaps that do not allow ultrasonic waves to pass effectively. Air voids and gaps can also exist at an interface with one or both of the light blocking layer 855 and the electrical shield layer 860. Air voids and gaps can also exist between a glass covering layer and a substrate glass on a glass OLED screen. In addition, the electrical shield layer 860 can be excessively thick and reduce the signal of ultrasonic waves that propagate through it.
[0097] [0097] A display device, as disclosed herein, may include an ultrasonic fingerprint sensor system integrated with a screen, such as an OLED 865 screen in Figure 8A, which retains the light blocking and electrical shield functionality of an OLED screen 865 without degrading the performance of the ultrasonic fingerprint sensor system. Integration can occur, for example, by connecting (for example, lamination) the ultrasonic fingerprint sensor system at the back of the 865 screen. The integration of the ultrasonic fingerprint sensor system with the 865 screen can occur without degrading the performance of the display device. In some implementations, the integration of the ultrasonic fingerprint sensor system can provide ease of replacement and / or repair of one or both of the ultrasonic fingerprint sensor system and the 865 screen without damaging the display device and its components.
[0098] [0098] Figure 8B shows a schematic cross-sectional view of an exemplary ultrasonic fingerprint sensor system according to some implementations. The 895 ultrasonic fingerprint sensor system in Figure 8B can include a sensor substrate 870, a piezoelectric transceiver layer 880 coupled to the sensor substrate 870, a transceiver electrode layer 885, a passivation layer 890 and an FPC 875 coupled to the sensor substrate 870. Aspects of the 895 ultrasonic fingerprint sensor system in Figure 8B can be identical or similar to the ultrasonic fingerprint sensor systems in Figures 1, 2A-2B, 3A-3B, 4A-4B and 5-7 . However, the integration of an 895 ultrasonic fingerprint sensor system with an 865 OLED screen in Figure 8A can limit or degrade the performance of one or both of the 895 ultrasonic fingerprint sensor system and the 865 screen. For example, the integration of the 895 ultrasonic fingerprint sensor system can introduce voltages that can distort the appearance and degrade the performance of the OLED screen
[0099] [0099] One or both of the 865 screen and the 895 ultrasonic fingerprint sensor system can be modified to effectively integrate the 895 ultrasonic fingerprint sensor system with the 865 screen without degrading the performance of the ultrasonic fingerprint sensor system 895 or screen 865. Figure 9A shows a schematic cross-sectional view of an exemplary device 900 including a protective glass 905, a screen 965 underlying protective glass 905, and a light blocking layer 955 and a layer of electrical shield 960 underlying screen 965 according to some implementations. Figure 9B shows a schematic cross-sectional view of an exemplary 995 ultrasonic fingerprint sensor system to be attached or attached to the device 900 of Figure 9A and to be underlying the screen 965 according to some implementations. As described above, the 995 ultrasonic fingerprint sensor system includes a sensor substrate 970, a piezoelectric transceiver layer 980 coupled to the sensor substrate 970, a transceiver electrode layer 985, a passivation layer 990, and an FPC 975 coupled to the 970 sensor substrate.
[0100] [0100] In Figure 9A, the light blocking layer 855 of Figure 8A is replaced by a non-porous light blocking layer 955 in Figure 9A to allow effective transmission of ultrasonic waves, and the electrical shielding layer 860 of Figure 8A is replaced by a thin electrical shield layer 960 in Figure 9A to allow effective transmission of ultrasonic waves. The non-porous light blocking layer 955 and / or the electrical shielding layer 960 can be positioned locally between the active area of the 995 ultrasonic fingerprint sensor system in some implementations, while in other implementations the blocking layer does not. porous 955 and / or the electrical shielding layer 960 can extend beyond the active area of the 995 ultrasonic fingerprint sensor system and can extend to the edges of screen 965. In some implementations, when screen 965 in Figure 9A includes a glass cover layer, voids and / or air gaps between the glass cover layer and a substrate glass can be filled with a filling material, such as a substantially transparent polymer or oil, thus allowing effective wave transmission ultrasonic. The non-porous light blocking layer 955 and the thin electrical shielding layer 960 can be part of a multifunctional film positioned between a 965 screen and an ultrasonic fingerprint sensor system, such as a 995 ultrasonic fingerprint sensor system. in Figure 9B or any of the ultrasonic fingerprint sensor systems described in Figures 11A-11F, 12A-12F and 13A-13B.
[0101] [0101] Screen 965 in Figure 9A may include an OLED screen stack, wherein the OLED screen stack includes a plurality of thin film layers 910, 915, 920, 925, 930, 935, 945 and 950. The stack OLED screen displays may include a plurality of 940 pixels arrayed. In some implementations, the light blocking layer 955 disposed between the OLED screen stack and the 995 ultrasonic detection system may include an index matching layer that has index matching with the bottom layers of the OLED screen stack. For example, the optical refractive index of the light blocking layer 955 can match or substantially match the optical refractive index of the lower layer of the OLED screen stack to minimize optical reflections from the interface between the OLED screen stack and the light blocking 955. The optical index of the light blocking layer 955 can be controlled within, for example, 0.05 of the optical index of the lowest layer in the OLED screen stack to prevent unwanted internal reflections. In some implementations, the light blocking layer 955 may include an optically clear index-controlled adhesive or an optically clear resin that has been combined with a suitable light blocking component, such as paint, dye, pigment, dye, colored fibers or carbon, graphite, graphene or metal particles. Metal particles or other conductive materials in the light blocking layer 955 can also serve as electrical shielding. In some implementations, a part of a foam layer in the OLED screen stack can be injected with a light blocking material to minimize voids and allow effective transmission of ultrasonic waves through the OLED screen stack. In some implementations, the foam layer on the OLED screen stack can be electrically conductive and serve as an electrical insulation layer. In some implementations, the light blocking layer 955 or the injected foam layer may extend over the entire active area and, in some instances, extend to the edges of the 965 screen.
[0102] [0102] In Figure 9B, a mechanical stress insulation layer 993 and an adhesive layer 994 can be added to the ultrasonic fingerprint sensor system 995 to allow attachment or fixation to the screen 965 with minimal stress transfer on the screen 965 and / or ultrasonic fingerprint sensor system
[0103] [0103] The multifunctional film can include the non-porous light blocking layer 955 and the thin electrical shielding layer 960 so that the 995 ultrasonic fingerprint sensor system engages with a 965 screen (eg OLED screen) ultrasonically, allow ultrasonic waves to pass from the 995 ultrasonic fingerprint sensor system through the 965 screen, eliminate or reduce visible light transmission to the 995 ultrasonic fingerprint sensor system, and eliminate or reduce electrical noise to the sensor system. ultrasonic fingerprint 995. In some implementations, the multifunctional film may include an adhesive layer 994 over a 993 mechanical stress insulation layer so that the 995 ultrasonic fingerprint sensor system eliminates or reduces stresses (for example, lamination stresses ) that can be introduced from the coupling or fixation of the 995 ultrasonic fingerprint sensor system or that can be can be introduced from the edge sealing application process.
[0104] [0104] The 993 mechanical stress insulation layer can be laid on or in the 995 ultrasonic fingerprint sensor system. In some implementations, a surface area of the 993 mechanical stress insulation layer extends beyond a system surface. of a 995 ultrasonic fingerprint sensor to which the 993 mechanical stress insulation layer is attached or attached. As shown in Figure 9B, the 993 mechanical stress insulation layer can extend beyond a periphery of the 995 ultrasonic fingerprint sensor system. In some implementations, the 993 mechanical stress insulation layer can span the entire display region. screen 965 and,
[0105] [0105] Figure 10A shows a schematic cross-sectional view of an example device 1000 including a 1095 ultrasonic fingerprint sensor system underlying a screen 1065 and an acoustic path 1050 of the 1095 ultrasonic fingerprint sensor system according to some implementations. As described above, a 1095 ultrasonic fingerprint sensor system can include a sensor substrate 1070, a piezoelectric transceiver layer 1080 coupled to the sensor substrate 1070, a transceiver electrode layer 1085, a passivation layer 1090, and an FPC 1075 coupled to the sensor substrate 1070. The 1095 ultrasonic fingerprint sensor system can be configured to transmit and receive ultrasonic waves on an acoustic path 1050 through a screen 1065 of a display device 1000, where the print sensor system digital ultrasonic 1095 underlies screen 1065 of the display device 1000. At least some of the ultrasonic waves transmitted from the 1095 ultrasonic fingerprint sensor system can be reflected back by an object 1030 (for example, a finger) positioned on a surface external screen 1065, touch screen, glass plate or protective glass 1005. The acoustic path 1050 can be defined by the propagation of ultrasonic waves to and from the 1095 ultrasonic fingerprint sensor system that allows a 1030 object, such as a finger placed in contact with the outer surface of the 1065 screen, touch screen, glass plate or glass protection 1005 is scanned.
[0106] [0106] Figure 10B shows a schematic cross-sectional view of an example device 1000 including a 1095 ultrasonic fingerprint sensor system underlying a screen 1065 and an acoustic path 1050 of the 1095 ultrasonic fingerprint sensor system according to some other implementations. In Figure 10B, the multifunctional film 1055 can be replaced by an adhesive layer 1060 that connects the 1095 ultrasonic fingerprint sensor system to the screen 1065. In some implementations, the adhesive layer 1060 includes an epoxy or pressure sensitive adhesive. An epoxy can include an epoxy based adhesive, wherein the epoxy based adhesive can include a thermoplastic paint that is configured to dissolve in a suitable organic solvent. In some implementations, the 1060 adhesive layer can provide functions in addition to adhering the 1095 ultrasonic fingerprint sensor system to the 1065 screen, including mechanical stress isolation and light blocking functions.
[0107] [0107] The mechanical stress insulation layer can be integrated with the ultrasonic fingerprint sensor system according to various implementations, as shown in Figures 11A-11F, 12A-12F and 13A-13B. Figures 11A-11F show schematic cross-sectional views of several exemplary 1100 ultrasonic fingerprint sensor systems in a “receiver down” orientation according to some implementations. Figures 12A-12F show schematic cross-sectional views of several exemplary 1200 ultrasonic fingerprint sensor systems in a "receiver up" orientation according to some implementations. The ultrasonic fingerprint sensor system can be oriented in a “receiver down” or “receiver up” orientation. In the “receiver down” orientation, a piezoelectric transceiver layer underlies a sensor substrate so that the sensor substrate is in the acoustic path. An FPC can be coupled to the sensor substrate so that the FPC is underlying the sensor substrate in the “receiver down” orientation. In the “receiver up” orientation, a piezoelectric transceiver layer is underlying a sensor substrate, so that the sensor substrate is not in the acoustic path. Instead, a transceiver electrode layer and a passivation layer are in the acoustic path. An FPC can be coupled to the sensor substrate so that the FPC is underlying the sensor substrate in the "receiver up" orientation.
[0108] [0108] In Figures 11A-11F, each of the 1100 ultrasonic fingerprint sensor systems includes a sensor substrate 1130, a piezoelectric transceiver layer 1140, a transceiver electrode layer 1145, a passivation layer 1150 (except in Figure 11F ), and an FPC 1120 coupled to the sensor substrate 1130. The piezoelectric transceiver layer 1140 may include a piezoelectric material configured to transmit ultrasonic waves by applying a voltage. Examples of a suitable piezoelectric material include PVDF or PVDF-TrFE copolymers. In some implementations, the appropriate material is configured to receive ultrasonic waves and generate a surface charge that is provided to sensor pixel circuits arranged on or on the sensor substrate
[0109] [0109] In each of the ultrasonic fingerprint sensor systems in Figures 11A-11F, an 1110 mechanical stress insulation layer can be laid over the sensor substrate 1130 in the “receiver down” orientation. Although a mechanical insulation layer 1130 is shown as a separate and discrete layer in Figures 11A-11F, it will be understood that the non-porous light blocking layer 955 in Figure 9A or a multifunctional film 1055 in Figure 10 can serve as a mechanical stress insulation layer in addition to or as an alternative to the mechanical stress insulation layer 1110 shown in Figures 11A-11F.
[0110] [0110] In each of the 1100 ultrasonic fingerprint sensor systems in Figures 11A-11D, the mechanical stress insulation layer 1110 is positioned between two adhesive layers 1105, 1125. In some implementations, a first adhesive layer 1105 positioned between the mechanical stress insulation layer
[0111] [0111] Figure 11A, as shown, does not include additional support layers or structures underlying the 1150 passivation layer of the 1100 ultrasonic fingerprint sensor system. In this configuration, air serves as an effective support layer. However, the air support layers can provide insufficient protection against inadvertent contact with other components, which can cause interference with the ultrasonic image and possible mechanical damage to the 1100 sensor system. In Figure 11B, the fingerprint sensor system ultrasonic further includes a foam support layer 1155 (also referred to as a “foam support” or “foam layer”) and a reinforcement 1160 underlying the foam support layer 1155 over the 1100 ultrasonic fingerprint sensor system from Figure 11A. In some implementations, the 1100 ultrasonic fingerprint sensor system includes an 1160 reinforcement and an electrical shield underlying the 1155 foam layer. The 1160 reinforcement, which can be a stamped layer of stainless steel or aluminum in some implementations, can be electrically grounded to provide effective electrical shielding.
[0112] [0112] The foam support layer 1155 can have an acoustic impedance very close to that of air and substantially less than that of the piezoelectric transceiver layer 1140, such that the acoustic wave transmission in the foam support layer 1155 and subsequent layers is significantly reduced. The foam support layer 1155 may have an acoustic impedance substantially different from the piezoelectric transceiver layer 1140. The incompatibility of acoustic impedance between the foam support layer 1155 and the piezoelectric transceiver layer 1140 is substantially different. The term "substantially different" with respect to acoustic impedance throughout this disclosure refers to an acoustic impedance value that is at least five times, at least eight times, at least ten times or at least 100 times greater or less than an acoustic impedance value to which it is being compared. In this way, the foam support layer 1155 can provide total or almost total reflection of the ultrasonic propagation waves. In addition, the foam support layer 1155 can provide mechanical support and shock absorber to protect the 1100 ultrasonic fingerprint sensor system. When external forces are applied to the 1100 ultrasonic fingerprint sensor system from other components or objects that touch the rear side of the sensor, the acoustic energy may be lost unless a foam support layer or other protection is provided (for example, a sensor compartment and an air cavity). Details relating to the foam support layer 1155 are further discussed with reference to Figures 13A-13B.
[0113] [0113] In Figure 11B, reinforcement 1160 can serve as a cover and can be attached to the back side of the 1100 ultrasonic fingerprint sensor system. In some implementations, reinforcement 1100 can comprise a wafer, substrate, panel, subpanel or one or more layers of plastic, metal, glass or silicon. In some implementations, the 1160 reinforcement may have a high flexural modulus and mechanical strength to structurally and environmentally protect the 1100 ultrasonic fingerprint detection system. The 1155 foam backing layer and the 1160 reinforcement can combine to provide the ability to seal the 1100 sensor system from external moisture and to improve moisture protection for greater reliability. In some implementations, an air support layer can be combined with the foam support layer 1155 and positioned between the transceiver electrode layer 1145 and the reinforcement 1160 to provide additional sound insulation.
[0114] [0114] In Figure 11C, the 1100 ultrasonic fingerprint sensor system still includes an 1160 reinforcement and a 1165 cavity relative to the 1100 ultrasonic fingerprint sensor system in Figure 11A. Cavity 1165 can be a defined air gap between reinforcement 1160 and passivation layer 1150 of the 1100 ultrasonic fingerprint sensor system. One or more spacers can be used to control the height of the gap or the height of cavity 1165. The cavity 1165 forms an air support layer that can provide a substantial incompatibility of acoustic impedance with the piezoelectric transceiver layer 1140, transceiver electrode layer 1145 and passivation layer 1150, so that the cavity 1165 can provide total or almost total reflection ultrasonic waves. An electrical shield can still be provided on the rear side of the 1100 ultrasonic fingerprint sensor system together with the 1160 reinforcement. In some implementations, the 1160 reinforcement can be electrically grounded and serve as an electrical shield.
[0115] [0115] In Figure 11D, the 1100 ultrasonic fingerprint sensor system still includes a 1170 sensor compartment and a cavity 1165 relative to the 1100 ultrasonic fingerprint sensor system in Figure 11A. Cavity 1165 forms an air gap or air support layer (also referred to as an “air support”) between the 1170 sensor compartment and at least the 1150 passivation layer of the 1100 ultrasonic fingerprint sensor system. implementations, the 1170 sensor compartment includes one or more layers of plastic or metal. The 1170 sensor compartment can be arranged in the 1110 mechanical stress insulation layer to provide the encapsulation of the 1100 ultrasonic fingerprint sensor system. An electrical shield can be provided on the rear side of the 1100 ultrasonic fingerprint sensor system along with the 1170 sensor compartment. As described with reference to Figure 11C, a reinforcement can be electrically grounded and serve as an electrical shield. The reinforcement can be included as part of the 1170 sensor compartment or the 1170 sensor compartment.
[0116] [0116] In the 1100 ultrasonic fingerprint sensor systems shown in Figures 11E-11F, the mechanical stress insulation layer 1110 can be formed as a molded structure around the 1100 ultrasonic fingerprint sensor system. adhesive layer positioned between the mechanical insulation layer 1110 and the sensor substrate 1130 and, instead of an edge seal around the 1100 ultrasonic fingerprint sensor system in the “receiver down” orientation, the voltage insulation layer mechanical 1110 can be shaped to wrap the 1100 ultrasonic fingerprint sensor system as a package. In this way, the 1110 mechanical stress insulation layer is formed on the front, edges and back of the 1100 ultrasonic fingerprint sensor system. In some implementations, a cavity can be formed in the molded mechanical stress insulation layer. 1110 behind the active sensor area to serve as an air support layer for better sound insulation.
[0117] [0117] In Figure 11E, the 1100 ultrasonic fingerprint sensor system includes a foam support layer 1155 underlying the passivation layer
[0118] [0118] In Figure 11F, the 1100 ultrasonic fingerprint sensor system includes an electrical shield 1175 underlying the 1110 mechanical stress insulation layer on the back side. However, in contrast to Figure 11E, the 1100 ultrasonic fingerprint sensor system does not include a foam backing layer or a passivation layer. In some implementations, an air support layer can be formed in the molded mechanical stress insulation layer 1110 behind the active area of the sensor.
[0119] [0119] In Figures 12A-12F, each of the 1200 ultrasonic fingerprint sensor systems is in a "receiver up" orientation and includes a sensor substrate 1230, a piezoelectric transceiver layer 1240, a transceiver electrode layer 1245, a passivation layer 1250, and an FPC 1220 coupled to the sensor substrate 1230 similar to that shown in Figures 11A-11F. Similar to the configurations shown in Figures 11A-11D, a mechanical stress insulation layer 1210 can be positioned between at least two adhesive layers 1205, 1225, as shown in Figures 12A-12D. Similar to the configurations shown in Figures 11E-11F, a mechanical stress insulation layer 1210 can be molded around the ultrasonic fingerprint sensor system 1200, as shown in Figures 12E-12F.
[0120] [0120] The ultrasonic fingerprint sensor system 1200 in the "receiver up" orientation includes the piezoelectric transceiver layer 1240 coupled and superimposed on the sensor substrate 1230 with a plurality of sensor 1235 pixel circuits arranged therein. The transceiver electrode layer 1245 can be coupled and overlapped with the piezoelectric transceiver layer 1240, and the passivation layer 1250 can be overlaid with the transceiver electrode layer 1245 or at least portions of the transceiver electrode layer 1245. In Figure 12B, a layer of foam support 1255 together with one or both of a reinforcement 1260 and an electrical shield underlying the sensor substrate 1230 on the back side of the ultrasonic fingerprint sensor system 1200. In Figure 12C, a cavity 1265 and one or both of a reinforcement 1260 and an electrical shield underlies the sensor substrate 1230 on the back side of the ultrasonic fingerprint sensor system 1200. In Figure 12D, a cavity 1265 and one or both of a 1270 compartment and an electrical shield underlies the sensor substrate 1230 on back side of the 1200 ultrasonic fingerprint sensor system. In Figure 12E, the mechanical stress insulation layer 1210 can be shaped around of the ultrasonic fingerprint sensor system 1200, where a foam support layer 1255 underlies the sensor substrate 1230, and an electrical shield 1275 underlies the mechanical stress insulation layer 1210 on the back side of the fingerprint sensor system ultrasonic 1200. In Figure 12F, the mechanical stress insulation layer 1210 can be molded around the ultrasonic fingerprint sensor system 1200, where an electrical shield 1275 underlies the mechanical stress insulation layer 1210 on the back side of the system of ultrasonic fingerprint sensor 1200. There is no foam support layer 1255. In some implementations, a cavity can be formed in the tension insulation material molded behind the active area of the sensor to serve as an air support layer. In the implementations shown in Figures 12B-12D, reinforcement 1260 can be electrically grounded and serve as an electrical shield. In the implementations shown in Figures 12E-12F, the electrical shield 1275 can be electrically grounded and serve as a mechanical reinforcement.
[0121] [0121] Figures 13A-13B show schematic cross-sectional views of several exemplary 1300 ultrasonic sensor systems including a foam support layer 1355 according to some implementations. The 1300 ultrasonic sensor systems in Figures 13A-13B are in a "receiver down" orientation, although it is understood that the foam support layer 1355 can also be provided in a "receiver up" orientation. Ultrasonic sensor systems 1300 include at least one sensor substrate 1330, a piezoelectric transceiver layer 1340 coupled to the sensor substrate 1330, a transceiver electrode layer 1345 coupled to the piezoelectric transceiver layer 1340, a passivation layer 1350, and an FPC 1320 coupled to the 1330 sensor substrate. In Figures 13A-13B, a multifunctional film 1310 can be positioned between the 1300 ultrasonic sensor system and a screen
[0122] [0122] In Figures 13A-13B, the foam support layer 1355 underlies the 1300 ultrasonic sensor system on the back side. In some implementations, the foam support layer 1355 can be attached or attached to the passivation layer 1350 through an adhesive layer
[0123] [0123] In Figure 13A, one or both of a 1360 reinforcement and an electrical shield underlies the foam support layer. One or both of the reinforcement 1360 and the electrical shield can be coupled or attached to the foam support layer 1355 through an adhesive layer 1357. In Figure 13B, a plastic layer 1365 underlies the foam support layer 1355, and a layer of 1370 metal underlies the plastic layer
[0124] [0124] More and more electronic devices include materials that are compatible with flexible display devices and flexible electronics. The incorporation of organic materials in display devices can introduce mechanical flexibility to the devices. In some implementations, ultrasonic sensor systems, as described in this document, can be implemented as a flexible ultrasonic sensor system. In some implementations, the flexible ultrasonic sensor system may include a flexible substrate including a polymeric material, such as polyimide, PEN or PET. In some implementations, the flexible substrate may include a thin layer of stainless steel, a sheet of stainless steel, thin glass, thin silicon, thin film silicon, or other flexible material. The thickness of the flexible substrates can be below about 250 μm and, in some examples, below about 100 μm and, in some examples, between about 50 μm and about 100 μm with TFT or CMOS circuits formed on the flexible substrates . Flexible substrates can be suitable for use with flexible screens, curved screens, curved protective glass, and screens
[0125] [0125] Figure 14A shows a schematic cross-sectional view of an exemplary 1495 flexible ultrasonic sensor system in a “receiver up” orientation according to some implementations. The 1495 flexible ultrasonic sensor system underlies a 1465 screen with a 1494 adhesive positioned between the 1495 flexible ultrasonic sensor system and the 1465 screen. In some implementations, the 1494 adhesive can be a pressure sensitive adhesive or an epoxy based adhesive . The screen 1465 may underlie a glass plate or protective glass 1405. In some implementations, the screen 1465 may include an OLED screen or an AMOLED screen or a pOLED (plastic OLED) also called a flexible OLED screen. In some implementations, an electrical shield layer 1460 may be positioned between the screen 1465 and the adhesive 1494. For example, the electrical shield layer 1460 may include an electrically conductive material, such as a metallic coating. In some implementations, a light blocking layer 1455 can be positioned between the screen 1465 and the adhesive 1494.
[0126] [0126] The flexible ultrasonic sensor system 1495 in the "receiver up" orientation can include a flexible substrate 1470 having a plurality of sensor pixel circuits 1496 arranged therein. A piezoelectric transceiver layer 1480 can be coupled and arranged on the flexible substrate 1470. An electrode layer 1485 can be coupled and arranged on the piezoelectric transceiver layer 1480, and a passivation layer 1490 arranged on at least a portion of the electrode layer
[0127] [0127] The generation of a pressure wave on the strong transmission side can make it easier for the 1495 flexible ultrasonic sensor system to be effective. The pressure wave on the strong transmission side can be generated by projecting film piles with strong acoustic impedance mismatch interfaces to reflect ultrasonic waves. Strong sound pressure creates greater reflection of ultrasonic waves to improve the quality of ultrasonic image. A strong acoustic impedance mismatch between material layers can result in total or near total reflection of ultrasonic waves. For example, an interface between air and plastic creates a low acoustic impedance mismatch, while an interface between air and metal or glass creates a high acoustic impedance mismatch.
[0128] [0128] Layers or materials with high acoustic impedance values can be referred to here as "hard" materials, and layers or materials with low acoustic impedance values can be referred to here as "soft" materials. The acoustic impedance values can be measured in MRayls. Table 1 below lists a series of materials and their acoustic impedance values. High values of acoustic impedance can be greater than about 5.0 MRayls, and low values of acoustic impedance can be between about 0.0 MRayls and about 5.0 MRayls.
[0129] [0129] In Figures 14A and 14B, an acoustic impedance mismatch between flexible substrate 1470 and layers 1410, 1415, 1420, 1425, 1430, 1435 and 1445 may not be sufficient or significant enough to create a pressure wave in the strong transmission side. While non-flexible ultrasonic sensor systems may include a “hard” substrate material, such as glass, adjacent to a 1480 piezoelectric transceiver layer, the 1495 flexible ultrasonic sensor system can compensate by incorporating “hard” materials between the piezoelectric transceiver layer 1480 and the screen 1465 and / or between the piezoelectric transceiver layer 1480 and a rear side of the flexible ultrasonic sensor system 1495. Incorporating a layer with a high acoustic impedance value to create a strong acoustic impedance mismatch can facilitate generation of the pressure wave on the strong transmission side. In some implementations, the layer with the high acoustic impedance value can be between the screen 1465 and the piezoelectric transceiver layer 1480. In addition or alternatively, a layer with a high acoustic impedance value can be between the piezoelectric layer 1480 and the rear side of the 1495 flexible ultrasonic sensor system.
[0130] [0130] In Figure 14A, in some implementations, the light blocking layer 1455 may include a material with a high acoustic impedance value. In some implementations, the electrical shield layer 1460 may include a material with a high acoustic impedance value. One or both of the light blocking layer 1455 and the electrical shielding layer 1460 can provide a high incompatibility of acoustic impedance at an interface with the adhesive 1494 or the piezoelectric transceiver layer
[0131] [0131] In some implementations, the support layer 1492 can have a high acoustic impedance. Thus, underlying the flexible substrate 1470 is a layer with a high acoustic impedance, which provides a substantial acoustic impedance incompatibility with one or more layers or adjacent materials (for example, air). For example, when support layer 1492 forms an interface with air, the acoustic impedance mismatch may be substantial enough to result in total or near total reflection of ultrasonic waves. In general, the air at the interface provides a boundary condition readily available for reflection of ultrasonic waves.
[0132] [0132] Figure 14B shows a schematic cross-sectional view of an exemplary 1495 flexible ultrasonic sensor system in a “receiver down” orientation according to some implementations. The 1495 flexible ultrasonic sensor system underlies a 1465 screen with a 1494 adhesive positioned between the 1495 flexible ultrasonic sensor system and the 1465 screen. In some implementations, the 1494 adhesive can be a pressure sensitive adhesive or an epoxy based adhesive . Screen 1465 may be underlying a glass plate or protective glass 1405. In some implementations, screen 1465 may include an OLED screen or an AMOLED screen. In some implementations, an electrical shield layer 1460 may be positioned between the screen 1465 and the adhesive 1494. For example, the electrical shield layer 1460 may include an electrically conductive material, such as a metallic coating. In some implementations, a light blocking layer 1455 can be positioned between the screen 1465 and the adhesive
[0133] [0133] The flexible ultrasonic sensor system 1495 in the "receiver down" orientation can include a flexible substrate 1470 having a plurality of sensor pixel circuits 1496 arranged on one side of flexible substrate 1470 facing the opposite side of the screen 1465. A piezoelectric transceiver layer 1480 can be coupled to and underlying the flexible substrate 1470. An electrode layer 1485 can be coupled and underlying the piezoelectric transceiver layer 1480, and a passivation layer 1490 can be underlying at least a portion of the electrode layer 1485 An FPC 1475 can be coupled to and underlying the flexible substrate 1470. The flexible ultrasonic sensor system 1495 can also include an optical support layer 1492 on the back side of the flexible ultrasonic sensor system 1495. Support layer 1492 can include one or both of an optically non-transparent layer and an electrically conductive blocking layer to provide a blocking function light and / or an electrical shielding function.
[0134] [0134] In Figure 14B, in some implementations, the light blocking layer 1455 may include a material with a high acoustic impedance value. In some implementations, the electrical shield layer 1460 may include a material with a high acoustic impedance value. One or both of the light blocking layer 1455 and the electrical shielding layer 1460 can provide a high acoustic impedance mismatch at an interface with adhesive 1494 or flexible substrate 1470. The adhesive 1494 and / or flexible substrate 1470 may include a “soft” material that has a low acoustic impedance value. In some implementations, the matrix of pixel circuits 1496 can be covered or clad with a metal or “hard” material that has a high acoustic impedance value to provide a high acoustic impedance incompatibility at an interface with the piezoelectric transceiver layer 1480. In some implementations, a layer (not shown) between the flexible substrate 1470 and the adhesive 1494 can include a material with a high acoustic impedance value. Examples of materials with high acoustic impedance values are shown above, which may include, but are not limited to, copper, coated electrodes or filled materials such as silver paint. High acoustic impedance values can result in an acoustic impedance mismatch that is substantial enough to result in total or near total reflection of ultrasonic waves.
[0135] [0135] Underlying the piezoelectric transceiver layer 1480 may be one or more layers of "hard" materials. In some implementations, the electrode layer 1485 may include a material with a high acoustic impedance value. The electrode layer 1485 can provide a high incompatibility of acoustic impedance in an interface with the piezoelectric transceiver layer 1480. In some implementations, the support layer 1492 can have a high acoustic impedance. Thus, underlying the piezoelectric transceiver layer 1480 is a layer with a high acoustic impedance, which provides a substantial acoustic impedance incompatibility with one or more adjacent layers or materials (for example, air). For example, when support layer 1492 forms an interface with air, the acoustic impedance mismatch may be substantial enough to result in total or near total reflection of ultrasonic waves.
[0136] [0136] The flexible ultrasonic sensor system allows the production of large area sensors. In some implementations, the flexible substrate encompasses an entire active area of the screen. In some implementations, the TFT array of sensor pixel circuits and the piezoelectric transceiver layer encompasses the entire active area of the screen. The piezoelectric transceiver layer and the plurality of sensor pixel circuits arranged on the flexible substrate are not necessarily located in a specific area of the screen. Instead, the substrate on which the piezoelectric transceiver layer and the plurality of sensor pixel circuits disposed therein may encompass the screen. Flexible ultrasonic sensor systems can cover an entire active area of the screen due, at least in part, to the easy lamination of a flexible substrate compared to a rigid substrate. Authentication of a user through the acquisition and authentication of a fingerprint image does not need to be performed in a specific region of the screen, allowing continuous authentication anywhere on the display device screen.
[0137] [0137] Figure 15 shows simulated data of acoustic signals reflected on “soft” and “hard” substrates and with different layers overlapping and / or underlying the “soft” substrates. The data in Figure 15 shows a percentage of acoustic signals reflected through a series of materials as a function of the transmitter's frequency. Each of the series of materials includes at least one substrate material, an electrode material and a passivation material. Each of the material series also includes a piezoelectric material. An electrode material in Figure 15 made of copper has a thickness of 9 μm or 15 μm. A passivation material in Figure 15 has a thickness of 0.1 μm or 12.5 μm. The “reference” data in Figure 15 shows the percentage of acoustic signals reflected on a glass substrate, a silicon substrate and a stainless steel substrate. The percentage of acoustic signals reflected in the “reference” data is relatively high, particularly for the glass substrate and the silicon substrate.
[0138] [0138] The percentage of reflected acoustic signals for a PET substrate in which the series of materials is arranged in a “receiver down” orientation is reduced. The addition of a coated material on the PET substrate substantially increases the percentage of acoustic signals reflected in the “receiver down” orientation, where the coated metal includes 12.5μm copper or 5 μm copper. The addition of a metal film between the screen and the PET substrate, however, did not increase the percentage of reflected acoustic signals. When the series of materials is arranged in a “receiver up” orientation, the percentage of acoustic signals reflected to the PET substrate is relatively high. Without being limited by any theory, the interface with the electrode layer and the interface with the air in the “receiver up” orientation provide substantial acoustic impedance incompatibilities that provide greater reflection of acoustic signals.
[0139] [0139] Figures 16A-16D show schematic cross-sectional views of several exemplary devices 1600 including a screen 1610 and incorporating a light blocking layer 1615, an electrical shield layer 1620 and an ultrasonic sensor system 1630 underlying the screen 1610 Each of the different implementations in Figures 16A-16D represent different ways to modify or manufacture a 1610 screen for coupling or fixing to a 1630 ultrasonic sensor system underlying the 1610 screen.
[0140] [0140] In Figure 16A, the screen may include a black porous foam as a second layer of 1625 light block and a thick copper tape as a second layer of electrical shield 1635. At least a portion of the black porous foam and tape thick copper wire can be removed to form a cutout region to expose the back side of the 1610 screen. A first 1615 light blocking layer, such as an opaque non-porous plastic material, can be attached to the back side of the 1610 screen. first layer of electrical shielding 1620, such as a thin metal layer or metallized plastic, can be attached to the back side of the first light blocking layer 1615. A 1630 ultrasonic sensor system, as described above in this document in Figures 8B, 9B, 10A-10B, 11A-11F, 12A-12F, 13A-13B and 14A-14B, can be attached to the rear side of the first layer of electrical shield
[0141] [0141] In Figure 16B, the black porous foam as the second layer of light blocking 1625 and the thick copper tape as the second layer of electrical shield 1635 are either completely removed or never provided on the rear side of the screen 1610. In these implementations, the first light blocking layer 1615, such as an opaque non-porous plastic material, can be attached directly to the rear side of the screen 1610. A first layer of electrical shield 1620, such as a thin metal layer or a layer of metallized plastic , can be attached to the back side of the first light blocking layer 1615. The first light blocking layer 1615 and the first layer of electrical shielding 1620 are not necessarily located in a region on the screen 1610, but can encompass an entire active area of screen 1610. A 1630 ultrasonic sensor system, as described above in this document, in Figures 8B, 9B, 10A-10B, 11A-11F, 12A-12F, 13A-13B and 14A-14B, can be attached to the rear side of the P first layer of electrical shield 1620.
[0142] [0142] In Figure 16C, a black porous foam and a thick copper tape can be provided with or subsequent to the attachment of the first light blocking layer 1615 and the first layer of electrical shield 1620 on the back side of the screen 1610. The foam porous black as a second layer of light blocking 1625 and thick copper tape as a second layer of electrical shield 1635 can be provided in portions of the first layer of electrical shield 1620. An ultrasonic sensor system
[0143] [0143] In Figure 16D, a black porous foam and thick copper tape can be provided with or after attaching the first layer of light block 1615 and the first layer of electrical shield 1620 to the back of screen 1610. The foam porous black as a second layer of light blocking 1625 and thick copper tape as a second layer of electrical shield 1635 can be arranged on the back side of the first layer of electrical shield 1620. Unlike Figure 16C, the black porous foam and the thick copper tape in Figure 16D cover a 1630 ultrasonic sensor system on the back side. A 1630 ultrasonic sensor system, as described above in this document in Figures 8B, 9B, 10A-10B, 11A-11F, 12A-12F, 13A-13B and 14A-14B, can be attached to the rear side of the first layer of electrical shielding 1620. This arrangement in Figure 16D may offer additional protection against light interference and electrical interference with the 1630 ultrasonic sensor system. Note that the dimensions of the features in Figures 16A-16D, as stated in this disclosure, may not be scaled. For example, the thickness of the 1630 ultrasonic fingerprint sensor system can be considerably thinner than the porous black foam and thinner than the layers in the screen stack.
[0144] [0144] In some implementations, a midframe structure that supports the screen and other electronic components in a phone set can be modified to serve as a protective cover for the ultrasonic fingerprint sensor system. The protective cap region can be supported with a layer of black porous foam and an adhesive layer that has cutout regions for the ultrasonic fingerprint sensor system and can wrap the ultrasonic fingerprint sensor system on each of the four sides and on the back. A layer of selectively configured copper tape can be included between the layer of black porous foam and the midframe structure. The midframe structure can serve as a sensor compartment. The midframe structure can allow a cavity or air support layer to be formed between the ultrasonic fingerprint sensor system and an internal surface of the midframe structure. The midframe structure can be contoured, embossed or otherwise formed to provide a suitable cavity region between the screen and the midframe structure for the ultrasonic fingerprint sensor to reside. In some implementations, a foam support layer may be included in the cavity region with or without an air support layer. In some implementations, an opening can be provided in the midframe structure of the phone to accommodate the ultrasonic fingerprint detection system and associated layers. In some implementations, a portion of an FPC associated with the ultrasonic fingerprint detection system can be positioned over the opening in the midframe structure to provide a cover for the detection system.
[0145] [0145] One or more of the electrical shielding layer, the light blocking layer and the mechanical tension insulation layer can provide a thermal function providing greater heat dissipation and better temperature uniformity at the rear of the screen. Heat can be generated non-uniformly, for example, from portions of the screen or from nearby components, such as batteries in a mobile device. In some implementations, a simple layer or a layer composed of selected materials positioned between the screen and the ultrasonic sensor system can provide the thermal function. For example, a simple copper layer can provide electrical shielding, light blocking and voltage isolation capabilities, in addition to thermal spreading and heat dissipation functions for better screen performance. In another example, a graphene layer with or without other electrical shielding layers, light blocking layers or mechanical stress insulation layers can provide the thermal function.
[0146] [0146] One or more layers of acoustic correspondence can be included in the ultrasonic fingerprint sensor system to minimize acoustic reflections within the sensor stack and between the sensor stack and the OLED screen. For example, one or more layers of acoustic correspondence can be inserted between any of the passivation layer, piezoelectric layer, electrode layer, substrate layer, light blocking layer, electrical shielding layer, mechanical stress insulation layer, thermally conductive layer or adhesive layers to improve the acoustic performance of the sensor stack.
[0147] [0147] Figure 17 shows an exemplary method of manufacturing a device including an ultrasonic sensor system underlying a screen. The 1700 process can be run in a different order or with fewer operations, additional operations or different operations.
[0148] [0148] In block 1710 of process 1700, a display device is provided, wherein the display device includes a glass plate and a screen underlying the glass plate. In some implementations, the glass plate may include a protective glass, a protective lens or an outer layer of the screen or any associated touch screen. In some implementations, the screen may include an OLED screen or an AMOLED screen. In some implementations, the screen may include a layer of black foam tape and a layer of copper tape on the back side of the screen.
[0149] [0149] In block 1720 of process 1700, at least part of the black foam tape layer and the copper tape layer is optionally removed from the display device. This can expose the back side of the screen. In some implementations, the black foam tape layer is sufficiently porous to prevent the effective transmission of ultrasonic waves, and the copper tape layer is thick enough to prevent the effective transmission of ultrasonic waves.
[0150] [0150] In block 1730 of process 1700, a light blocking layer, a layer of electrical shielding, a layer of mechanical stress insulation or combinations thereof can be attached to the screen, where the layer of electrical shielding is electrically conductive and grounded. In some implementations, attaching the light blocking layer, the electrical shielding layer and / or the mechanical voltage insulation layer includes laminating the light blocking layer, the electrical shielding layer and / or the voltage insulation layer mechanical to the screen. For example, the light blocking layer, the electrical shielding layer and / or the mechanical stress insulation layer can be laminated on a back side of the screen using roll lamination. In some implementations, the light blocking layer is substantially non-transparent and substantially non-porous. In some implementations, the electrical shielding layer may include a metal or metallized plastic having a thickness between about 0.05 μm and about 10 μm, or between about 0.1 μm and about 6 μm. In some implementations, the mechanical stress insulation layer may include a plastic material. The mechanical stress insulation layer can underlie an adhesive to reduce stresses that can be imparted to one or both of the screen and the ultrasonic sensor system.
[0151] [0151] In block 1740 of process 1700, an ultrasonic sensor system is attached to the light blocking layer, the electrical shielding layer, the mechanical stress insulation layer, or combinations thereof, in which the ultrasonic sensor system it is underlying the screen and configured to transmit and receive ultrasonic waves in an acoustic path through the screen and the glass plate, and in which the light blocking layer, the electrical shielding layer, the mechanical stress insulation layer, or combinations of them, are in the acoustic path. In some implementations, attaching the ultrasonic sensor system includes laminating the ultrasonic sensor to the light blocking layer, the electrical shielding layer and / or the mechanical stress insulation layer. For example, the ultrasonic sensor system can be laminated using vacuum lamination.
[0152] [0152] The ultrasonic sensor system may include a sensor substrate, a piezoelectric transceiver layer coupled to the sensor substrate, a transceiver electrode layer, a passivation layer, and an FPC coupled to the sensor substrate. In some implementations, the ultrasonic sensor system may further include one or more layers of support on the back side of the ultrasonic sensor system, wherein the one or more layers of support may include an electrically conductive and / or substantially optically non-transparent material.
[0153] [0153] In some implementations, at least one of the light blocking layer and the electrical shielding layer can be attached to the rear side of the screen, so that the ultrasonic sensor system is detachable (for example, removable) from the screen. Detachment can occur without damaging the ultrasonic sensor system or the screen. For example, at least one of the light blocking layer and the electrical shielding layer can be attached through an adhesive layer to the back side of the screen, where the adhesive layer can include a pressure sensitive adhesive or an epoxy based adhesive . In some implementations, the ultrasonic sensor system can be attached to at least one of the light blocking layer and the electrical shielding layer, so that the ultrasonic sensor system is detachable from the screen. Detachment can occur without damaging the ultrasonic sensor system or the screen. For example, the ultrasonic sensor system can be attached through an adhesive layer to at least one of the light blocking layer and the electrical shielding layer, where the adhesive layer can include a pressure sensitive adhesive or a base adhesive epoxy.
[0154] [0154] Figure 18 shows an example of using a capacitive detection mode and an ultrasonic detection mode with a 525 fingerprint sensor positioned behind a screen 510 of an electronic device 505 to activate the electronic device 505. The device Electronic 505 can include a driver 214 that can switch sensor 525 to operate between a capacitive detection mode and an ultrasonic detection mode. The electronic device 505 may be in a locked state, in which a screen 510 and an application processor of the electronic device 505 are turned off or in a power saving mode, as illustrated in Figure 18 in time 1850. When such an object like a 515 finger, is detected at or near the 525 sensor using the capacitive detection mode and / or the ultrasonic detection mode, a portion of the screen 510 can activate to indicate and highlight the position where the fingerprint sensor is located , as shown in Figure 18 at the time of 1855. As shown in Figure 18, the text indicating “Place your finger here to unlock” is displayed along with a graphically generated circular icon 565, although many other icons and / or text provided as a guide for a user to indicate the position of the fingerprint sensor have been contemplated. Capacitive and / or ultrasonic detection modes can continue to be used until the finger 515 is digitized, at which point the image data can be analyzed and the electronic device 505 unlocked if the authentication process is successful. The 525 sensor can be positioned under part of the screen 510, which can be an LCD screen, an OLED screen or another type of screen. In some implementations, one or more electrodes from a touch screen of the 505 electronic device can serve as a detection electrode for the 525 fingerprint sensor when operating in a capacitive detection mode, allowing signals from non-active portions of the screen 510 without the 525 fingerprint sensor are ignored by the 520 control circuit, while allowing the detection of signals due to the touch of a finger on active parts of the screen 510 with the 525 fingerprint sensor, further reducing the inadvertent activation of the 505 electronic device.
[0155] [0155] Figure 19 shows the side view of a 1900 configuration with a 525 fingerprint sensor positioned behind a portion of a 510 screen. The 525 fingerprint sensor is positioned under a 510 LCD or OLED screen and a protective glass or touch screen that serves as a 306 glass plate for sensor 525. Sensor 525 and associated detection electrodes can be configured to operate in a capacitive detection mode or in an ultrasonic detection mode. In some implementations, the 525 sensor may be located near the top, bottom, edge or somewhere on the inside of the screen, which may include a layer of TFT 1920 substrate and other 1940 layers of an LCD or OLED screen. In other examples, sensor 525 can be positioned below or behind screen 510. In other examples, sensor 525 can be integrated within the TFT substrate layer of the screen 1920. Sensor 525 can be integrated with the TFT substrate of the screen, sharing common TFT substrates with the active area of the 525 sensor covering part, none or all of the active area of the screen.
[0156] [0156] Figure 20 shows an example of a flow chart for a 2000 method of guiding a user of a device with OLED or LCD screen to position a finger above a fingerprint sensor under LCD or under OLED. Graphical display-based icons can be useful for on-screen configurations, since the use of colored inks or other permanent evidence to mark the position of the fingerprint sensor that can obstruct a user's view of the display device (for example, a mobile device or an electronic device) can be avoided. In some implementations, the presence of a finger can be detected by capacitive detection electrodes on a touch screen superimposed on the screen while the screen is off. In some implementations, dedicated detection electrodes as part of or near the ultrasonic fingerprint sensor can be used to detect the presence of a finger. In block 2005, a user's finger positioned on a surface of the screen can be detected using a capacitive detection mode with, for example, the touch screen or a dedicated detection electrode. In the 2010 block, after detecting the presence of the finger, a fingerprint sensor icon can be illuminated on the screen. In some implementations, the screen can be partially unlocked to display only the fingerprint sensor icon or other selective information to guide the user. In some implementations, a portion of the screen can be illuminated while in low power mode, and the icon can be enhanced or other selective information can be provided to the user when the finger is detected. In block 2015, a finger can be detected on the screen above the fingerprint sensor using a capacitive detection mode, an ultrasonic detection mode or a capacitive and ultrasonic detection mode. In block 2020, the user can be authenticated and the screen unlocked. In alternative configurations, such as using an OLED screen, the screen can continuously show the fingerprint sensor icon or other selective information using a subset of the screen's pixels to guide the user while the mobile device remains locked.
[0157] [0157] As used here, a phrase referring to “at least one of” a list of items refers to any combination of these items, including unique members. For example, “at least one of: a, b or c” is intended to cover: a, b, c, a-b, a-c, b-c and a-b-c.
[0158] [0158] The various logics, logic blocks, modules, circuits and illustrative processed algorithms, in connection with the implementations disclosed here, can be implemented as electronic hardware, computer software or combinations of both. The interchangeability of hardware and software has been described in general terms in terms of functionality and illustrated in the various components, blocks, modules, circuits and illustrative processes described above. The decision to implement such functionality in hardware or software depends on the specific application and design restrictions imposed on the general system.
[0159] [0159] The hardware and data processing apparatus used to implement the various logics, logic blocks, modules and illustrative circuits in connection with the aspects disclosed herein can be implemented or executed with a general purpose single chip or multichip processor, a digital signal processor (DSP), an application specific integrated circuit (ASIC), an array of field programmable ports (FPGA) or other programmable logic device, discrete or transistor logic port, discrete hardware components or any combination of designed to perform the functions described in this document. A general purpose processor can be a microprocessor or any conventional processor, controller, microcontroller or state machine. a processor can be implemented as a combination of computing devices, for example, a combination of a DSP and a microprocessor, a plurality of microprocessors, one or more microprocessors in conjunction with a DSP core or any other configuration. In some implementations, specific processes and methods can be performed by circuits that are specific to a particular function.
[0160] [0160] In one or more aspects, the functions described can be implemented in hardware, digital electronic circuits, computer software, firmware, the structures disclosed in this specification and their structural equivalents, or in any combination thereof. The implementations of the object described in this specification can be implemented as one or more computer programs, that is, one or more computer program instruction modules, encoded in a computer storage medium for execution by, or to control the operation of , data processing device.
[0161] [0161] If implemented in software, functions can be stored or transmitted as one or more instructions or code in a computer-readable medium, such as a non-transitory medium. The processes of a method or algorithm disclosed here can be implemented in an executable software module per processor that can reside in a computer-readable medium. Computer-readable media includes computer storage media and communication media, including any media that can be activated to transfer a computer program from one place to another. The storage medium can be any available medium that can be accessed by a computer. By way of example and not by way of limitation, the non-transitory medium may include RAM, ROM, EEPROM, CD-ROM or other optical disk storage, magnetic disk storage or other magnetic storage devices or any other medium that can be used for store the desired program code in the form of instructions or data structures that can be accessed by a computer. In addition, any connection can be properly called a computer-readable medium. Disk and disk, as used here, include compact disk (CD), laser disk, optical disk, digital versatile disk (DVD), floppy disk and Blu-ray disk, where disks are usually they reproduce data magnetically, while the discs (discs) reproduce data optically with lasers. The above combinations must also be included in the scope of computer-readable medium. In addition, the operations of a method or algorithm can reside as one or any combination or set of codes and instructions in a machine-readable medium and a computer-readable medium, which can be incorporated into a computer program product.
[0162] [0162] Various modifications to the implementations described in the present disclosure can be readily apparent to those skilled in the art, and the generic principles defined herein can be applied to other implementations without departing from the spirit or scope of the present invention. Accordingly, the invention is not intended to be limited to the implementations shown in this document, but must be in accordance with the broader scope consistent with the claims, principles and new features disclosed herein. The word "example" is used exclusively here to mean "serving as an example, instance or illustration". Any implementation described in this document as "exemplary" should not necessarily be interpreted as preferred or advantageous over other implementations.
[0163] [0163] Certain features that are described in this specification in the context of separate implementations can also be implemented in combination in a single implementation. On the other hand, several features that are described in the context of a single implementation can also be implemented in several implementations separately or in any suitable subcombination. In addition, although the features may be described above as acting on certain combinations and even initially claimed as such, one or more features of a claimed combination may, in some cases, be excluded from the combination, and the claimed combination may be directed to the subcombination or variation of a subcombination.
[0164] [0164] Likewise, although operations are represented in the drawings in a specific order, this should not be understood as requiring that such operations be performed in the specific order shown or in sequential order, or that all illustrated operations be performed to achieve desirable results. In certain circumstances, multitasking and parallel processing can be advantageous. In addition, the separation of various system components in the implementations described above should not be understood as requiring this separation in all implementations, and it should be understood that the program components and the systems described can be integrated into a single software product or bundled in various software products. In addition, other implementations are within the scope of the following claims. In some cases, the actions cited in the claims may be carried out in a different order and still achieve desirable results.
[0165] [0165] It will be understood that unless the features in any of the specific implementations described are expressly identified as incompatible with each other or the context determines that they are mutually exclusive and not easily combinable in a supportive and / or complementary sense , the whole of the present invention contemplates and predicts that specific characteristics of these complementary implementations can be selectively combined to provide one or more more comprehensive, but slightly different, technical solutions. Therefore, it will be appreciated that the above description has been provided by way of example only and that modifications to the details can be made within the scope of the present invention.

权利要求:
Claims (26)
[1]
1. Apparatus comprising: a screen; an ultrasonic sensor system underlying the screen and configured to transmit and receive ultrasonic waves in an acoustic path through the screen; a light blocking layer between the ultrasonic sensor system and the screen, the light blocking layer positioned in the acoustic path; and an adhesive layer between the screen and the ultrasonic sensor system, the adhesive layer positioned on the acoustic path and configured to allow the ultrasonic sensor system to be separated from the screen.
[2]
2. Apparatus, according to claim 1, further comprising: an electrical shield layer between the ultrasonic sensor system and the screen, the electrical shield layer being electrically conductive and grounded, the electrical shield layer positioned in the acoustic path.
[3]
Apparatus according to claim 2, wherein each of the electrical shielding layer and the light blocking layer is non-porous or substantially non-porous.
[4]
Apparatus according to claim 2, wherein the light blocking layer includes an opaque plastic material and the electrical shielding layer includes a metal or metallized plastic having a thickness between about 0.1 µm and about 9 μm.
[5]
5. Apparatus according to claim 1, wherein the screen is an organic light-emitting diode screen
(OLED).
[6]
6. Apparatus according to claim 5, wherein the screen is a flexible OLED screen formed on a plastic substrate.
[7]
Apparatus according to any one of claims 1-6, wherein the adhesive layer includes a pressure sensitive adhesive.
[8]
Apparatus according to any one of claims 1-6, wherein the adhesive layer includes an epoxy based adhesive, the epoxy based adhesive including a thermoplastic paint.
[9]
Apparatus according to any one of claims 1-6, further comprising: the mechanical stress insulation layer between the adhesive layer and the ultrasonic sensor system, wherein the mechanical stress insulation layer includes a plastic material.
[10]
Apparatus according to any one of claims 1-6, wherein the ultrasonic sensor system includes: a sensor substrate having a plurality of sensor pixel circuits disposed therein; a piezoelectric transceiver layer coupled to the sensor substrate and including a piezoelectric material configured to generate the ultrasonic waves; and an electrode layer coupled to the piezoelectric transceiver layer.
[11]
Apparatus according to claim 10, wherein the piezoelectric transceiver layer is underlying the sensor substrate and the electrode layer is underlying the piezoelectric transceiver layer.
[12]
Apparatus according to claim 10, wherein the piezoelectric transceiver layer is underlying the electrode layer and the sensor substrate is underlying the piezoelectric transceiver layer.
[13]
Apparatus according to claim 10, wherein the piezoelectric transceiver layer includes polyvinylidene fluoride (PVDF), polyvinylidene fluoride and trifluoroethylene copolymer (PVDF-TrFE), lead zirconate titanate (PZT), aluminum nitride (A1N) or composites thereof.
[14]
Apparatus according to claim 10, wherein the sensor substrate comprises a material selected from the group consisting of: glass, plastic, silicon and stainless steel.
[15]
15. Apparatus, comprising: a screen; an ultrasonic sensor system underlying the screen and configured to transmit and receive ultrasonic waves in an acoustic path through the screen; and an adhesive layer between the ultrasonic sensor system and the screen, the adhesive layer positioned on the acoustic path.
[16]
16. Apparatus according to claim 15, further comprising: a mechanical stress insulation layer between the adhesive layer and the ultrasonic sensor system, the mechanical stress insulation layer including a plastic material and positioned in the acoustic path.
[17]
17. Apparatus according to claim 15,
wherein the ultrasonic sensor system covers all or a substantial part of an active area of the screen.
[18]
18. Apparatus according to claim 15, wherein the screen is an organic light-emitting diode (OLED) screen.
[19]
19. Apparatus according to any one of claims 15-18, wherein the adhesive layer is reshapable and configured to allow the ultrasonic sensor system to be separated from the screen, the adhesive layer including a pressure sensitive adhesive or a pressure adhesive. epoxy base.
[20]
An apparatus according to any one of claims 15-18, further comprising: a light blocking layer between the adhesive layer and the screen, the light blocking layer positioned in the acoustic path; and a layer of electrical shielding between the adhesive layer and the screen, the layer of electrical shielding being electrically conductive and grounded, the layer of electrical shielding positioned in the acoustic path, in which each of the light blocking layer and the shielding layer electrical is non-porous or substantially non-porous.
[21]
21. Apparatus, comprising: a screen; an ultrasonic sensor system underlying the screen and configured to transmit and receive ultrasonic waves in an acoustic path through the screen; and a multifunctional film between the ultrasonic sensor system and the screen, wherein the multifunctional film includes a light blocking layer, an electrical shielding layer, an adhesive layer, a mechanical stress insulation layer, or combinations thereof, the multifunctional film positioned on the acoustic path.
[22]
22. Method of manufacturing an apparatus, the method comprising: providing a display device, wherein the display device includes a glass plate (platen) and a screen underlying the glass plate; attach a light blocking layer, an electrical shielding layer, a mechanical voltage insulation layer or combinations thereof to the screen, where the electrical shielding layer is electrically conductive and grounded; and attach an ultrasonic sensor system to the light blocking layer, the electrical shielding layer, the mechanical stress insulation layer, or combinations thereof, where the ultrasonic sensor system is underlying the screen and configured to transmit and receive ultrasonic waves in an acoustic path through the screen and the glass plate, in which the light blocking layer, the electrical shielding layer, the mechanical stress insulation layer or combinations thereof are in the acoustic path.
[23]
23. The method of claim 22, wherein fixing the light blocking layer, the electrical shielding layer, the mechanical stress insulation layer or combinations thereof include laminating the light blocking layer, the electrical shielding, the mechanical stress insulation layer or combinations thereof to the screen.
[24]
24. The method of claim 22, further comprising: attaching an adhesive layer to the screen to allow at least the ultrasonic sensor system to be separated from the screen, in which the adhesive layer is positioned in the acoustic path.
[25]
25. Apparatus comprising: a screen; an ultrasonic sensor system underlying the screen and configured to transmit and receive ultrasonic waves in an acoustic path through the screen, in which the ultrasonic sensor system comprises: a flexible substrate including a plurality of sensor pixel circuits arranged therein; and a piezoelectric transceiver layer coupled to the flexible substrate and including a piezoelectric material configured to generate the ultrasonic waves; and a first layer of high acoustic impedance between the piezoelectric transceiver layer and the screen.
[26]
26. Apparatus according to claim 25, wherein the first layer of high acoustic impedance includes one or both of a light blocking layer and an electrical shielding layer.
27. Apparatus according to claim 25, wherein the first layer of high acoustic impedance includes an electrode layer adjacent to the piezoelectric transceiver layer.
Apparatus according to any one of claims 25-27, wherein the layer with a high acoustic impedance value has an acoustic impedance value greater than about 5.0 MRayls.
29. Apparatus according to any one of claims 25-27, further comprising: an adhesive layer between the screen and the ultrasonic sensor system, the adhesive layer positioned in the acoustic path and configured to allow the ultrasonic sensor system to be separated of the screen.
Apparatus according to any one of claims 25-27, wherein the flexible substrate includes polyethylene terephthalate (PET), polyethylene naphthalate (PEN), a polyimide, stainless steel sheet, thin film silicon, or other flexible material.
31. Apparatus according to any one of claims 25-27, further comprising: a second layer of high acoustic impedance on the rear side of the ultrasonic sensor system.
1/26 100
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Figure 2A
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Controller 214
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Figure 2B
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Figure 14B
Reference Signal vs Frequency (MHz) Substrate Material Ref: 1. Ref: SI substrate
0. Ref: Substrate 2. Ref: Substrate Ref: 1. Ref: Si 3. PET Rx Down Cu 12.5um + PET Cu 5um + PET PET + 12.5um Cu PET + 25um Cu PET + 50um Cu PET_RxUp of Glass Substrate .. Steel Thickness of Subs-Thickness of Subs- Thickness of Subs-Thickness of Subs- Thickness of Subs- Thickness of Subs-Thickness of Subs- Thickness of Subs-Thickness of Subtract (one) contract (one) ) (one) (one) tract (one) tract (one) (one) (one) tract (one) tract tract tract tract Petition 870190134428, of 12/16/2019, p. 140/150 50 100 50 100 50 100 50 100 50 100 50 100 50 100 50 100 50 100 50 100 Sign 20/26 Figure 15
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1710 Provide a display device, where the display device includes a glass plate and a screen underlying the glass plate
1720
Remove at least part of the black foam tape layer and the copper tape layer from the display device
1730
Attach a light blocking layer, an electrical shielding layer, a mechanical voltage insulation layer or combinations thereof to the screen, where the electrical shielding layer is electrically conductive and grounded
1740
Attach an ultrasonic sensor system to the light blocking layer, the electrical shielding layer, the mechanical stress insulation layer, or combinations thereof, where the ultrasonic sensor system is underlying the screen and configured to transmit and receive waves ultrasonic in an acoustic path through the screen and the glass plate, in which the light blocking layer, the electrical shielding layer, the mechanical stress insulation layer, or combinations thereof, are in the acoustic path
Figure 17
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565 525 525 515 515
Figure 18
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Figure 19
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Detect finger on the screen using capacitive detection mode
2010
Illuminate the fingerprint sensor icon on the screen
2015
Detect your finger on the fingerprint sensor using ultrasonic detection mode
2020
Authenticate user and unlock screen
Figure 20

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引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

---

US9551783B2|2013-06-03|2017-01-24|Qualcomm Incorporated|Display with backside ultrasonic sensor array|

---

US10036734B2|2013-06-03|2018-07-31|Snaptrack, Inc.|Ultrasonic sensor with bonded piezoelectric layer|

---

CN105094227A|2015-07-10|2015-11-25|麦克思商务咨询有限公司|Electronic apparatus|

---

KR20170057133A|2015-11-16|2017-05-24|주식회사 모다이노칩|Pressure sensor and complex device and electronic device having the same|US10539539B2|2016-05-10|2020-01-21|Invensense, Inc.|Operation of an ultrasonic sensor|

---

US10562070B2|2016-05-10|2020-02-18|Invensense, Inc.|Receive operation of an ultrasonic sensor|

---

EP3520098A1|2016-09-27|2019-08-07|INURU GmbH|Nondestructive integration of electronics|

---

TWI614695B|2017-07-03|2018-02-11|敦泰電子有限公司|High screen ratio display device with fingerprint identification|

---

KR102367975B1|2017-07-06|2022-02-25|삼성디스플레이 주식회사|Panel bottom member and display device including the same|

---

CN109214257A|2017-07-07|2019-01-15|宸美（厦门）光电有限公司|Fingeprint distinguisher|

---

US10461124B2|2017-08-07|2019-10-29|Invensense, Inc.|Ultrasonic sensing device|

---

CN109427853A|2017-09-05|2019-03-05|乐金显示有限公司|Display device including fingerprint scanner|

---

KR102295557B1|2017-09-15|2021-08-27|엘지디스플레이 주식회사|Display device|

---

CN107978624A|2017-12-01|2018-05-01|京东方科技集团股份有限公司|OLED display panel and preparation method thereof, display device|

---

KR20190076081A|2017-12-21|2019-07-02|삼성디스플레이 주식회사|Display device|

---

KR20190078960A|2017-12-27|2019-07-05|엘지디스플레이 주식회사|Fingerprint sensing display apparatus|

---

KR20190079030A|2017-12-27|2019-07-05|엘지디스플레이 주식회사|Fingerprint sensing display apparatus|

---

KR20190080640A|2017-12-28|2019-07-08|엘지디스플레이 주식회사|Fingerprint sensing display apparatus|

---

KR20190080106A|2017-12-28|2019-07-08|엘지디스플레이 주식회사|Fingerprint sensing display apparatus|

---

KR20190080113A|2017-12-28|2019-07-08|엘지디스플레이 주식회사|Fingerprint sensing display apparatus|

---

KR20190081292A|2017-12-29|2019-07-09|엘지디스플레이 주식회사|Fingerprint sensing display apparatus|

---

KR20190081294A|2017-12-29|2019-07-09|엘지디스플레이 주식회사|Fingerprint sensing display apparatus|

---

US11151355B2|2018-01-24|2021-10-19|Invensense, Inc.|Generation of an estimated fingerprint|

---

KR20190098285A|2018-02-12|2019-08-22|삼성디스플레이 주식회사|Display device|

---

KR20190098877A|2018-02-14|2019-08-23|삼성디스플레이 주식회사|Biometric information sensor and display device having the same|

---

US20190325188A1|2018-04-17|2019-10-24|Samsung Electronics Co., Ltd.|Electronic device including multiple fixing members to fix biometric sensor to display and method for manufacturing the same|

---

KR20190123830A|2018-04-24|2019-11-04|삼성디스플레이 주식회사|Display device|

---

US11126814B2|2018-10-17|2021-09-21|Qualcomm Incorporated|Ultrasonic fingerprint sensor with flexible substrate|

---

KR20200048286A|2018-10-29|2020-05-08|엘지디스플레이 주식회사|Display apparatus including untrasonic fingerprint sensor|

---

CN109522885A|2019-01-08|2019-03-26|深圳市台技光电有限公司|Tempered glass protective film and preparation method suitable for ultrasonic fingerprint identification function|

---

US10929636B2|2019-01-18|2021-02-23|Qualcomm Incorporated|Ultrasonic fingerprint sensor with electrically nonconductive acoustic layer|

---

CN109817679B|2019-01-31|2020-10-16|武汉华星光电半导体显示技术有限公司|OLED display screen module|

---

CN113498500A|2019-02-15|2021-10-12|三星电子株式会社|Electronic device including display module including sensor and method of manufacturing the display module|

---

US10891458B2|2019-02-28|2021-01-12|Qualcomm Incorporated|Module architecture for large area ultrasonic fingerprint sensor|

---

KR20200108947A|2019-03-11|2020-09-22|삼성디스플레이 주식회사|Display device and method for driving the same|

---

CN110110612A|2019-04-18|2019-08-09|武汉华星光电技术有限公司|Ultrasonic fingerprint identifies mould group and the display panel including it|

---

CN110047899B|2019-04-26|2021-10-22|京东方科技集团股份有限公司|Display panel, display device and manufacturing method|

---

KR20200129571A|2019-05-09|2020-11-18|삼성전자주식회사|An electronic device including a display module including a sensor and a method of manufacturing the display module|

---

JP2020202208A|2019-06-06|2020-12-17|株式会社ジャパンディスプレイ|Flexible substrate|

---

WO2020263875A1|2019-06-24|2020-12-30|Invensense, Inc.|Fake finger detection using ridge features|

---

CN112130688A|2019-06-24|2020-12-25|Oppo广东移动通信有限公司|Display screen, electronic equipment and control method thereof|

---

WO2020264046A1|2019-06-25|2020-12-30|Invensense, Inc.|Fake finger detection based on transient features|

---

CN110348334A|2019-06-25|2019-10-18|武汉华星光电技术有限公司|Fingerprint recognition mould group and display device|

---

US11216632B2|2019-07-17|2022-01-04|Invensense, Inc.|Ultrasonic fingerprint sensor with a contact layer of non-uniform thickness|

---

US11176345B2|2019-07-17|2021-11-16|Invensense, Inc.|Ultrasonic fingerprint sensor with a contact layer of non-uniform thickness|

---

TWI701585B|2019-07-17|2020-08-11|友達光電股份有限公司|Ultrasonic pixel circuit and related display device|

---

US11087107B2|2019-08-20|2021-08-10|Qualcomm Incorporated|Ultrasonic sensor with bi-poled or uni-poled transmitter/receiver|

---

US11232549B2|2019-08-23|2022-01-25|Invensense, Inc.|Adapting a quality threshold for a fingerprint image|

---

US11182587B2|2019-09-05|2021-11-23|Qualcomm Incorporated|Ultrasonic fingerprint sensor with low-frequency vibration source|

---

TWI698849B|2019-10-03|2020-07-11|友達光電股份有限公司|Pixel circuit|

---

CN214376504U|2019-11-12|2021-10-08|神盾股份有限公司|Ultrasonic fingerprint sensor|

---

CN113811883A|2019-11-19|2021-12-17|指纹卡安娜卡敦知识产权有限公司|Ultrasound biometric imaging apparatus with reduced reflections|

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CN111428584A|2020-03-06|2020-07-17|南昌欧菲生物识别技术有限公司|Display module and electronic equipment|

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CN111410871A|2020-03-06|2020-07-14|南昌欧菲生物识别技术有限公司|Conductive ink, display module and electronic equipment|

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US11243300B2|2020-03-10|2022-02-08|Invensense, Inc.|Operating a fingerprint sensor comprised of ultrasonic transducers and a presence sensor|

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CN111508386B|2020-05-28|2021-11-23|京东方科技集团股份有限公司|Ultrasonic display panel and display device|

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US20220004728A1|2020-07-01|2022-01-06|Qualcomm Incorporated|Multiple-frequency ultrasonic sensor system|

法律状态:
2021-11-03| B350| Update of information on the portal [chapter 15.35 patent gazette]|

优先权:

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申请号 | 申请日 | 专利标题

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US201762525154P| true| 2017-06-26|2017-06-26|

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US62/525,154|2017-06-26|

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US16/006,640|US20180373913A1|2017-06-26|2018-06-12|Ultrasonic fingerprint sensor for under-display applications|

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US16/006,640|2018-06-12|

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PCT/US2018/037581|WO2019005498A1|2017-06-26|2018-06-14|Ultrasonic fingerprint sensor for under-display applications|

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