MOBILE DEVICE WITH WRIST NUTRAL DATA COLLECTION

专利摘要:
A mobile device with pulse-neutral data collection is provided. The device comprises: a housing; a data assurance component adapted to change a target pattern; a screen; an orientation sensor adapted to detect an orientation; one or more touch sensors on the housing; a memory which stores pulse-neutral touch data associated with a pulse-neutral grip corresponding to predetermined grip position locations on the touch sensor (s); and a controller adapted to: when touch data received by the touch sensor (s) corresponds to pulse neutral touch data stored in the memory, controls the target pattern of the data assurance component according to the orientation sensed by the orientation sensor; and when touch data does not match wrist neutral touch data, a notification device controls providing an indicator that the housing is outside the wrist neutral grip.
公开号:BE1025467B1
申请号:E2017/5885
申请日:2017-12-01
公开日:2019-03-13
发明作者:Chandra M. Nair；Jaeho Choi；Konstantinos Tsiopanos
申请人:Symbol Technologies Llc；
IPC主号:

专利说明:

MOBILE DEVICE WITH WRIST NUTRAL DATA COLLECTION
BACKGROUND
Storage, transportation and logistics workers often use mobile devices equipped with scanners to scan barcodes and the like from articles at different heights and from different orientations, depending on where the articles are placed. This can vary from scanning items on the floor (for example, on pallets), to scanning items on shelves or shelf labels, to scanning small packages that could be handled. Mobile devices with fixed angle scanners can cause uncomfortable and potentially serious wrist abnormalities, for example, ulcer defects towards the little finger. Such strenuous wrist variations could lead to fatigue among workers as a result of: an increase in physical effort to perform a scan, reduced strength over time, reduction in spare capacity and increase in recovery time, which could depend on environment and type and volume of scanning. Also, scanning transaction verification can result in such severe wrist abnormalities because they are often performed by a worker lifting his arm to bring a screen of the mobile device to a suitable viewing angle. This could be an inefficient movement, and when the movement is repeatedly performed, it could again cause a physical stress.
SUMMARY OF THE INVENTION
According to an aspect of the invention there is provided a portable device comprising a housing with a front side and a rear side; a data assurance component provided on the rear of the
BE2017 / 5885 housing, the data collection component being arranged to change a target pattern; a screen provided on the front of the housing; an orientation sensor adapted to detect an orientation of the housing; one or more touch sensors on the housing; a memory storing pulse neutral touch data related to a pulse neutral grip corresponding to predetermined grip position locations at the one or more touch sensors; and a controller adapted to, when touch data received at the one or more touch sensors corresponds to pulse neutral touch data stored in the memory, control the target pattern of the data assurance component according to the orientation detected by the orientation sensor; and when the touch data does not match the wrist neutral touch data, a notification device controls providing an indicator of the housing being outside the wrist neutral grip.
Advantageously, the memory may further store target pattern data related to one or more orientations, and the controller may further be arranged to control the target pattern of the data assurance component according to the orientation noted by the, if the touch data corresponds to the wrist neutral touch data. orientation sensor.
The controller may further be arranged to enter a learning mode for determining target pattern data for each of the one or more orientations.
Preferably, target pattern data associated with one or more orientations may include a low target pattern data associated with a low orientation, a middle target pattern data associated with a middle orientation, and a high target pattern data associated with a high orientation.
Advantageously, the controller could be further arranged to enter a learning mode for receiving wrist neutral
BE2017 / 5885 touch data from the one or more touch sensors, and to store the wrist neutral touch data in the memory.
The controller can further be arranged to control the alignment pattern of the data-gathering component according to the orientation by changing the alignment pattern plus 10 ° or minus 10 ° from a basic position.
The orientation can preferably be defined relative to the front of the housing.
The data collection component may advantageously comprise one or more of a scanner and a camera.
The notification device may preferably comprise one or more of the screen, an auditory notification device, a visual notification device, and a haptic notification device.
The orientation sensor may advantageously comprise one or more of an accelerometer, a three-axis accelerometer, a three-axis micro-electromechanical system (MEMS) accelerometer, a three-dimensional orientation sensor, a magnetometer and a gyroscope.
According to a further aspect of the invention, a method is provided, comprising:
provided with a device, for example a portable device according to one of the preceding claims, comprising: a housing with a front side and a rear side; a data assurance component provided on the rear of the housing, the data assurance component adapted to change a target pattern; a screen provided on the front of the housing; an orientation sensor adapted to detect an orientation of the housing; one or more touch sensors on the housing; a memory storing pulse-neutral touch data associated with a pulse-neutral grip corresponding to predetermined grip position locations at the one or more touch sensors; and a controller,
BE2017 / 5885 when touch data received by the one or more touch sensors corresponds to pulse-neutral touch data stored in the memory, using the controller, control the alignment pattern of the data assurance component according to the orientation detected by the orientation sensor; and when the touch data does not match the wrist neutral touch data, using the controller, controls a notification device to provide an indicator that the housing is outside the wrist neutral grip.
Advantageously, the memory may further store target pattern data associated with one or more orientations, and the method may further include, when the touch data corresponds to the pulse-neutral touch data, controlling the target pattern of the data assurance component according to the target pattern data associated with the orientation marked by the orientation sensor .
The method may further include the controller entering a learning mode for determining the target pattern data for each of the one or more orientations.
The target pattern data associated with one or more orientation may preferably include low target pattern data associated with a low orientation, middle target pattern data associated with a middle orientation, and high target pattern data associated with a high orientation.
The method may further comprise entering a learning mode by the controller for receiving pulse-neutral touch data from the one or more touch sensors; and storing pulse-neutral touch data in the memory.
The method may further comprising controlling the alignment pattern of the data collateral component according to the orientation by changing the alignment pattern by plus 10 ° or minus 10 ° from a base position.
BE2017 / 5885
The orientation can preferably be defined with respect to the front of the housing.
The data collection component may advantageously comprise one or more of a scanner and a camera.
The notification device may preferably comprise one or more of the screen, an auditory notification device, a visual notification device, and a haptic notification device.
The present invention will be further elaborated upon with reference to figures of exemplary embodiments.
BRIEF DESCRIPTIONS OF THE SEVERAL VIEWS OF THE DRAWINGS
The accompanying figures, in which the same reference numbers refer to identical or functionally similar elements in all individual views, are included in and form part of the description, together with the detailed description below, and serve to further clarify embodiments of concepts which the claimed claims invention, and illustrate various principles and advantages of these embodiments.
FIG. 1 describes a front view of a portable device with pulse-neutral data collection, according to non-limiting embodiments.
FIG. 2 describes a side view of the mobile device of FIG. 1, according to non-limiting embodiments.
FIG. 3 describes a rear view of the mobile device of FIG. 1, according to non-limiting embodiments.
FIG. 4 describes a schematic diagram of the mobile device of FIG. 1, according to non-limiting embodiments.
FIG. 5 describes a block diagram of a method for pulse-neutral data collection, according to non-limiting embodiments.
BE2017 / 5885
FIG. 6 describes an illustration of angles in which a wrist may deviate, according to non-limiting embodiments.
FIG. 7 describes the mobile device of FIG. 1 which is held in a wrist neutral position, according to non-limiting embodiments.
FIG. 8 describes the mobile device of FIG. 1 in a learning mode for determining wrist neutral touch data, according to non-limiting embodiments.
FIG. 9 describes the mobile device of FIG. 1 that stores wrist-neutralized touch data detected by touch sensors in a memory, according to non-limiting embodiments.
FIG. 10 describes the mobile device of FIG. 1 which is held outside of a wrist-neutral position, and specifically in an ulcer deviation according to non-limiting embodiments.
FIG. 11 describes the mobile device of FIG. 1 which compares touch data detected by touch sensors with pulse neutral touch data, according to non-limiting embodiments.
FIG. 12 describe the mobile device of FIG. 1 which provides an indicator for moving the mobile device back into a wrist neutral position, according to non-limiting embodiments.
FIG. 13 describes a range of targeting patterns of the mobile device of FIG. 1, according to non-limitative embodiments.
FIG. 14 describes the mobile device of FIG. 1 in a learning mode for providing target pattern data, according to non-limiting embodiments.
FIG. 15 describes the mobile device of FIG. 1 in an alternative learning mode for providing target pattern data, according to non-limitative embodiments.
BE2017 / 5885
FIG. 16 describes the mobile device of FIG. 1 which stores target pattern data for a data collateral component, according to non-limitative embodiments.
FIG. 17 describes the mobile device of FIG. 1 which controls a target pattern of a data garaging component according to a low orientation, according to non-limiting embodiments.
FIG. 18 describes the mobile device of FIG. 1 which controls a target pattern of a data-gathering component according to a center orientation, according to non-limiting embodiments.
FIG. 19 describes the mobile device of FIG. 1 which controls a directional pattern of a data assurance component according to a high orientation, according to non-limiting embodiments.
Skilled artisans will appreciate that parts are shown in the figures for simplicity and clarity and are not necessarily drawn to scale. For example, the dimensions and positions of some parts in the figures may be exaggerated relative to other parts, to help increase understanding of the embodiments of the present invention.
The apparatus and method components, when appropriate, are represented in the figures by conventional symbols, which show only those specific details relating to the understanding of the embodiments of the present invention, so as not to obscure the description with details that are easy to understand. be clear to the person skilled in the art, who has the advantage of the present description.
DETAILED DESCRIPTION
An aspect of the description provides a portable device comprising: a housing with a front and a rear; a data garaging component provided on the rear of the housing, the data garaging component being arranged to have a target pattern
BE2017 / 5885; a screen provided on the front of the housing; an orientation sensor adapted to detect an orientation of the housing; one or more touch sensors on the housing; a memory which stores pulse-neutral touch data associated with a pulse-neutral grip corresponding to predetermined grip positions on the one or more touch sensors; and a controller adapted to: when touch data received by the one or more touch sensors corresponds to the pulse-neutral touch data stored in the memory, controlling the alignment pattern of the data assurance component according to the orientation sensed by the orientation sensor, using the controller; and when the touch data does not match the wrist neutral touch data, controlling a notification device to provide an indicator that the housing is outside the wrist neutral handle.
The memory may further store target pattern data associated with one or more orientations, and the controller may further be arranged to: when the touch data corresponds to the wrist neutral touch data, control the target pattern of the data assurance component according to the target pattern data associated with the orientation sensed by the orientation sensor.
The controller can further be arranged to enter a learning mode for determining target pattern data for each of the one or more orientations.
The target pattern data associated with one or more orientations may include: low target pattern data associated with a low orientation, middle target pattern data associated with a middle orientation, and high target pattern data associated with a high orientation.
The controller can further be arranged to enter a learning mode to: receive the pulse-neutral touch data from the one or more touch sensors; and storing the wrist neutral touch data in the memory.
BE2017 / 5885
The controller may further be arranged to control the alignment pattern of the data collection component according to the orientation by changing the alignment pattern plus 10 ° or minus 10 ° from a base position.
The orientation can be defined relative to the front of the housing.
The data collection component may comprise one or more of a scanner and a camera.
The notification device may comprise one or more of the screen, an auditory notification device, a visual notification device, and a haptic notification device.
The orientation sensor may comprise one or more of an accelerometer, a three-axis accelerometer, a three-axis micro-electromechanical system (MEMS) accelerometer, a three-dimensional orientation sensor, a magnetometer, and a gyroscope.
Another aspect of the description provides a method comprising: an apparatus comprising: a housing with a front side and a rear side; a data assurance component provided on the rear of the housing, the data assurance component adapted to change a target pattern; a screen provided on the front of the housing; an orientation sensor adapted to detect an orientation of the housing; one or more touch sensors on the housing; a memory storing pulse-neutral touch data associated with a pulse-neutral grip corresponding to predetermined grip position locations at the one or more touch sensors; and a controller, when touch data received by the one or more touch sensors corresponds to pulse neutral touch data stored in the memory, using the controller, controls the target pattern of the data assurance component according to the orientation detected by the orientation sensor; and when the touch data is not
BE2017 / 5885 corresponds to the wrist neutral touch data, controlling, using the controller, a notification device for providing an indicator that the housing is outside the wrist neutral grip.
The memory may further store target pattern data associated with one or more orientations, and the method may further include: when touch data corresponds to wrist neutral touch data, controlling the target pattern of the data garaging component according to the target pattern data with the orientation detected by the orientation sensor.
The method may further include going into a learning mode of the controller to determine the target pattern data for each of the one or more orientations.
The target pattern data associated with one or more orientations may include: low target pattern data associated with a low orientation, middle target pattern data associated with a middle orientation, and high target pattern data associated with a high orientation.
The method may further include entering a learning mode by the controller to: receive wrist neutral touch data from the one or more touch sensors; and storing pulse-neutral touch data in the memory.
The method may further include controlling the target pattern of the data collection component according to the orientation by changing the target pattern plus 10 ° or minus 10 ° of a base position.
The orientation can be defined with respect to the front of the housing.
The data collection component may comprise one or more of a scanner and a camera.
The notification device may comprise one or more of the screen, an auditory notification device, a visual notification device, and a haptic notification device.
BE2017 / 5885
Another aspect of the specification provides a non-transitional computer readable medium that stores a computer program, wherein execution of the computer program is for: a device comprising: a housing with a front and a rear; a data assurance component provided on the rear of the housing, the data assurance component being arranged to change a target pattern; a screen provided on the front of the housing; an orientation sensor adapted to detect an orientation of the housing; one or more touch sensors on the housing; a memory which stores pulse-neutral touch data associated with a pulse-neutral grip corresponding to predetermined grip positions on the one or more touch sensors; and a controller, when touch data received by the one or more touch sensors corresponds to the pulse-neutral touch data stored in the memory, using the controller, controls the alignment pattern of the data assurance component according to the orientation noted by the orientation sensor, using the controller; and when the touch data does not match the wrist neutral touch data, controlling a notification device to provide an indicator that the housing is outside the wrist neutral handle using the controller.
Attention is directed to FIG. 1, FIG. 2, FIG. 3 and FIG. 4 which respectively describe: a front view of a portable device 100 with wrist neutral data collection functionality (hereafter interchangeably referred to with device 100); a right side view of device 100; a rear view of device 100; and a schematic diagram of device 100.
Device 100 comprises: a housing 101 with a front side 102f and a rear side 102r; a data assurance component 105 provided on back 102r, data assurance component 105 adapted to change a target pattern; a display 107 provided on the front
BE2017 / 5885
102f; an orientation sensor 109 adapted to detect an orientation of housing 101 (and / or device 100); one or more touch sensors 111-1, 111-2 on housing 101; a memory 122 which stores wrist neutral touch data 223 which is associated with a wrist neutral grip corresponding to predetermined grip position location on one or more touch sensors 111-1, 111-2; and a controller 120 adapted to: when touch data received on one or more touch sensors 1111, 111-2 corresponds to pulse-neutral touch data 223, control the target pattern of data assurance component according to the orientation sensed by orientation sensor 109; and when the touch data does not match wrist-neutral touch data 223, a notification device controls providing an indicator that housing 101 is outside the wrist-neutral grip. For example, controller 120 can control display 107 to provide an indicator that housing 101 is outside of the wrist neutral grip and / or can control any other notification device on device 100 in providing an indicator that housing 101 is outside of the wrist neutral grip. For example, one or more of an auditory notification device, a visual notification device and a haptic notification device can be controlled by providing an indicator that housing 101 is outside the wrist-neutral grip.
Referring to FIG. 1, FIG. 2 and FIG. 3, device 100 further comprises a plurality of input devices including: a data assurance component actuator 115, a keypad 117, one or more buttons 119-1, 119-2, all of which may be optional. Referring to FIG. 1, device 100 further comprises an optional speaker 132 and an optional microphone 134. Referring to FIG. 4, device 100 further comprises an optional communication interface 224, hereinafter referred to as interface 224, and one or more notification devices 299 (which may include one or more of display 107 and speaker 132).
BE2017 / 5885
One or more touch sensors 111-1, 111-2 will be referred to alternately hereinafter, together, as touch sensors 111 and, generally, as a touch sensor 111; one or more buttons 119-1, 119-2 will be referred to alternately hereinafter, collectively, as buttons 119 and generally as a button 119. Data garaging component actuator 115 will hereinafter be referred to as actuator 115.
Generally, actuator 115 is arranged to actuate data collateral component 105. In other words, actuator 115 includes a button and the like which, when activated, causes data garaging component 105 to collect data. Alternatively, data collateral component 105 may be actuated using one or more buttons of keyboard 117, one or more optional buttons 119, and / or an optional digital button, and the like, displayed on the display 107.
Data collection component 105 may include one or more of a scanner and / or a data scanner and a camera including, but not limited to, image processors and / or laser-based scanner data collection components. As shown, data garaging component 105 is provided on rear side 102r of device and hence a directional direction and / or field of view of data garaging component 105 extends from rear side 102r of device 100. Further, a directional direction and / or orientation pattern and / or field of view of data garaging component 105 can be controllable. Data garaging component 105 may, for example, comprise a laser scanner and a scanning angle of the laser scanner may be adjustable with the aid of movable mirrors, and / or other optical components. Data garaging component 105 can similarly comprise a camera with an external lens, with a directional direction of at least the lens being movable using motors, servo motors, ultrasonic motors and the like. Anyway
BE2017 / 5885, when the actuator 115 is actuated, controller 120 can control a directional direction and / or directional pattern of data collateral component 105 and data collateral component 105 to collect data.
Indeed, the terms aiming direction and aiming pattern may be interchangeable, although generally a aiming pattern includes, but is not limited to, a range of aiming directions and / or an angle through which data is collected by data garaging component 105. For example, when data garaging component 105 includes a laser scanner, a laser pattern can be moved along a range of angles and gather data in laser light from barcodes, and the like, in the range of angles. Indeed, the directional orientation of the laser scanner in these embodiments is moved over the range of angles in a directional pattern. Therefore, controlling the pattern may include controlling a range of angles over which data is collected by data garaging component 105, but is not limited thereto.
As is best seen in FIG. 1, device 100 includes two touch sensors 111 provided on each side and / or corner of housing 101 which connects front 102f to rear 102r, and which are adjacent to keyboard 117 and / or actuator 115 (e.g., on a left corner and a right corner of housing 101 ). In particular, touch sensors 111 are provided at locations on housing 101 where grip location locations on device 100 are detectable, and in particular touch sensors 111 are provided where fingers and / or other parts of a hand which engages device 100 may be positioned. As shown, each of touch sensors 111 includes a pressure sensitive touch strip, each of which may further comprise a plurality of pressure sensors which may detect pressure at grip positions, as will be described in further detail below. Further, as shown, touch sensors 111 on each of the left corner and right corner of housing 101 are integrated into the touch strip, although, in other
BE2017 / 5885, the touch sensors 111 may comprise a plurality of discrete touch sensors and / or pressure sensors in the housing 101. Indeed, any type of touch sensor 111 falls within the scope of the present embodiments, including, but not limited to, capacitive touch sensors and / or resistive touch sensors or others.
Display 107 includes any suitable or combination of flat panel displays (e.g., LCD (liquid crystal display), plasma displays, OLED (organic light emitting diode) displays), CRTs (cathode ray tubes) and the like, as well as one or more optional touch screens (including capacitive touch sensors and / or resistive touch sensors).
Referring to FIG. 4, orientation sensor 109 may include one or more of an acceleration meter, a three-axis accelerometer, a three-axis micro-electromechanical system (MEMS) accelerometer, a three-dimensional orientation sensor, a magnetometer, and a gyroscope. In general, the orientation sensor 109 may be arranged to provide orientation data to the controller 120 corresponding to an orientation of housing 101 and / or device 100 relative to the ground and / or ground, and / or an arbitrary position determined during a determination process . For example, such orientations, in some embodiments, may be defined with respect to face 102f to determine when display 107 is visible in a position for a user holding the device 100, which may be combined with data from touch sensors 111 to further determine when device 100 is held in a wrist-neutral grip, as described in further detail below.
Controller 120 is connected to memory 122, (storing pulse-neutral touch data 223, application 251, and target pattern data 273), interface 224, data assurance component 105, display 107,
BE2017 / 5885 orientation sensor 109, touch sensors 111, actuator 115, optional buttons 119, speaker 132 and microphone 134, and notification device 299.
Notification device 299 may include one or more of display 107 and speaker 132, but may include another visual notification device, auditory notification device, and / or haptic notification device, including, but not limited to, lights, LEDs, other speakers, vibration motors, and the like.
Although not described in FIG. 4 it is assumed that controller 120 is further connected to any other electronic and / or communication component of device 100 which may include, but is not limited to, a radio frequency identification device (RFID) and / or reader, a near field communication (NFC) ) device and / or reader, and the like, another camera device (for example not used as a scanner and / or for storage use), a PTT (push-to-talk) device and / or radio, and a messaging device (e.g. one or use multiple radios and / or graphical user interfaces for receiving, compiling and / or sending messages, including, but not limited to, e-mails, SMS (short message server) messages and the like.
Device 100 generally includes a portable device that includes any usable combination of electronic devices, communication devices, computer devices, portable electronic devices, mobile computer devices, portable computer devices, tablet computer devices, telephones, personal digital assitants (PDAs), mobile phones, smartphones, etc. readers, mobile camera devices and the like may include, but are not limited to, each including a data collection component. Other usable devices fall within the scope of the current embodiment. For example, while, as described, device 100 can be arranged as a mobile communication device with telephone capabilities, which is also arranged for data collection functionality, use
BE2017 / 5885 data collateral component 105, device 100 need not include a mobile communication device, but it can actually include a device specifically configured for specialized functionality. For example, device 100 could be specifically adapted to keep track of storage inventory and / or other data collection functionality, which may include, but is not limited to, one or more of a radio frequency identification (RFID) reading, a Near Field Communication (NFC) reading , and / or other types of data collateral components. In even further embodiments, device 100 may be mountable in a vehicle. However, other devices are within the scope of current embodiments.
Further referring to FIG. 4, controller 120 may include a processor and / or a plurality of processors, including but not limited to one or more central processors (CPUs) and / or one or more processor units; in any case, controller 120 comprises a hardware element and / or a hardware processor. Indeed, in some embodiments, controller 120 may include an ASIC (application specific integrated circuit) and / or an FPGA (field-programmable field array) that is specifically adapted to implement pulse-neutral grasp functionality of device 100 for scanning and / or data collection. In other words, controller 120 may be arranged to determine whether device 100 is held in a wrist neutral grip based on data from touch sensors 111 and, if so, control a target pattern of data assurance component 105 follow an orientation sensed by orientation sensor 109; and further adapted to, if device 100 is not held in wrist-neutral grip, control notification device 299 to provide an indication thereof. Therefore, device 100 is preferably not a generic computer device, but a device that is specifically adapted to implement specifically wrist-neutral grasp functionality and associated data garment functionalities. For example can
BE2017 / 5885 device 100 and / or controller 120 specifically include a computer executable engine configured to implement specific wrist neutral grip functionality and associated data concealment functionalities.
Memory 122 may include a non-volatile storage unit (e.g., an Erasable Electronic Programmable Read Only Memory ("EEPROM"), flash memory) and a volatile storage unit (e.g., random access memory ("RAM")). Programming instructions that implement the functionalities of device 100 as described herein are typically held, retained, in memory 122 and used by controller 120 which makes suitable use of volatile storage during the execution of such programming instructions. Those skilled in the art recognize that memory 122 is an example of a computer readable medium that can store programming instructions that are executable on controller 120. Furthermore, memory 122 is also an example of a memory unit and / or memory module and / or a non-volatile memory.
As shown, memory 122 further stores application 251 which, when executed by controller 120, enables controller 120 to implement pulse-neutral hold functionality and associated data garaging functionality at device 100. In other words, as described below, application 251 can be executed by controller 120 to: when touch data received by one or more touch sensors 111 corresponds to pulse-neutral touch data, controlling the alignment pattern of the data assurance component 105 according to the orientation detected by the orientation sensor 109; and when the touch data does not match the wrist-neutral touch data 223, controlling notification device 299 to provide an indicator that the housing 101 is outside the wrist-neutral grip.
Application 251 can therefore include an application that can be used to control data collateral component 105 to control data,
BE2017 / 5885 such as pictures, barcodes and the like to collect, and optionally save. Therefore, application 251 may comprise a storage application and / or application 251 may comprise a module of a storage application.
As described, controller 120 also connects to interface 224, which can be arranged as one or more radios and / or connectors and / or network adapters, arranged to communicate wired and / or wireless with network architecture used to implement one or more communication links between other devices and / or a network, including but not limited to any suitable combination of USB (universal serial bus) cables, serial cables, wireless connections, mobile phone connections, mobile network connections (including but not limited to 2G, 2.5G, 3G, 4G + such as UMTS (Universal Mobile Telecommunications System), GSM (Global System for Mobile Communications), CDMA (Code division multiple access), FDD (frequency division duplexing), LTE (Long Term Evolution), TDD (time division duplexing), TDD- LTE (TDD Long Term Evolution), TD-SCDMA (Time Division Synchronous Code Division Multiple Access)) and the like, wireless data, WLAN (wireless local area) network) connections, WiFi connections, WiMax connections, package-based connections, the internet, analogue networks, the PSTN (public switched telephone network), access points, and the like, and / or a combination thereof. However, interface 224 may be optional and device need not be arranged to communicate with networks, although device 100 may generally be arranged to send data to other devices, for example using wired and / or wireless network connections, and the like, with other devices.
Controller 120 may further be adapted to communicate with other and / or optional input devices (not described) of device 100, which, when present, may be adapted to receive input data including, but not limited to, any suitable combination of
BE2017 / 5885 a keyboard, a pointing device, a mouse, a track wheel, a track ball, a touch pad and the like. Other suitable input devices fall within the scope of the present embodiments. Indeed, device 100 may include a touch screen 107 which is generally used as an input device to control other functionalities at device 100, such as, for example, the use of graphical user interfaces, digital buttons, pull down menus and the like.
Although not shown, device 100 further includes a power source, including but not limited to a connection to a mains power source and / or a power adapter (e.g., an AC-to-DC (alternating current to direct current) adapter), and alternatively a battery, a power pack, and such ones. Generally, such a power source energizes components of device 100.
Therefore, it should be understood that generally a wide variety of embodiments of device 100 have been devised and device 100 may include other components, for example related to telephoning, message sending, entertainment, and / or other components associated with a portable device can be used.
The attention is now directed to FIG. 5 which shows a block diagram of a flowchart of a method 500 for providing wrist-neutral grip functionality and associated data garaging functionality. To aid in explaining method 500, it will be assumed that method 500 is performed using device 100, and specifically by controller 120 of device 100, when controller 120 executes instructions stored on memory 122, e.g., application 251. Indeed method 500 is a way in which device 100 can be arranged. Furthermore, the following explanation of method 500 will lead to further understanding of device 100, and its various components. However, it should be understood that device 100 and / or method 500 can be varied,
BE2017 / 5885 and not exactly as described need to work in conjunction with each other, and that such variations are within the scope of the present embodiments.
Regardless of this, it must be emphasized that method 500 need not be carried out in exactly the order as described, unless otherwise specified: and in the same way, different blocks can be executed in parallel other than in order; therefore, the elements of method 500 are referred to as blocks instead of steps. It is to be understood that, however, method 500 can also be implemented on variations of device 100.
As an optional block 501, controller 120 enters a learning mode: receiving pulse-neutral touch data 233 from one or more touch sensors 111; and store wrist neutral touch data 223 in memory 122.
As an optional block 503, controller 120 enters a learning mode to: determine target pattern data 237 for each of and one or more orientations.
At block 503, controller 120, when touch data received at one or more touch sensors 111 corresponds to pulse-neutral touch data 223, controls the target pattern of data assurance component 105 according to the orientation sensed by the orientation sensor.
At block 507, the controller 120 controls when the touch data does not match wrist neutral touch data 223 notification device 299 to provide an indicator that housing 101 is outside the wrist neutral grip.
It will be understood that each of the blocks 501, 503 can be optional and / or implemented in any order. Furthermore, block 507 can be implemented independently of and / or in parallel with blocks 503, 505.
BE2017 / 5885
Method 500 will now be described with reference to FIG. 6 to FIG. 19.
Attention is now directed to FIG. 6, which describes an illustration of angles between which a wrist may deviate (e.g., side to side). In particular, FIG. 6 a hand 601 in three positions 602-1, 602-2, 602-3 relative to a wrist 603. In position 602-1, hand 601 is straightened from wrist 603 at an angle of 0 ° with respect to wrist 603; from the point of view of ergonomics, at the angle of 0 °, hand 601 is able to exert 100% force on an object held in hand 601. Furthermore, such 100% hand force can be maintained within a range of +/- 10 ° with respect to 0 °, as indicated by triangle 605; such a range can be determined from ergonomics and the like.
As also described in FIG. 6, hand 601 can move to position 602-2 by flexing hand 601 at wrist 603 in a direction of the little finger of hand 601 (for example, the little finger moves towards 603, which is known as an ulcer deviation). Such an ulcer deviation can cause a 25% reduction in manual force, for example with an ulcer deviation of angles around 40 °.
Similarly, as also shown in FIG. 6, hand 601 can move to position 602-3 by flexing hand 601 at wrist 603 in a direction of the thumb of hand 601 (e.g., the thumb moves toward 603, which is known as a spoke bone defect). Such a spoke bone deviation can cause a 25% decrease in manual force, for example in the case of spoke bone deviation angles of around 25 °. Hence, hand 601 is ideally held in position 602-1 when work is being provided, such as gathering data using device 100 held in hand 601.
Attention is directed to FIG. 7 which describes device 100 which is indeed held in a wrist neutral grip by hand 601;
BE2017 / 5885 specifically, hand 601 is at 0 ° to wrist 603. Furthermore, the fingers of hand 601 and palm 700 of hand 601 are in contact with touch sensors 111 at certain grip position locations. Touch sensors 111 may be arranged to detect both a grip position location of hand parts (e.g., fingers of a hand, a palm of a hand, and the like) that are in contact with touch sensors 111 and a pressure applied to touch sensors 111 at each grip position location.
For example, little finger 701, ring finger 703, and middle finger 705 of hand 601 are in contact with touch sensor 111-2 at certain grip position locations, and touch sensor 111-2 can produce certain touch data indicating each of a grip position location; similar, while touch sensor 111-1 is not visible in FIG. 7, palm 700 of hand 601 is in contact with touch sensor 111-1 and can produce touch sensor 111-1 touch data indicating a grip position location (and / or an average position and / or a range of positions) of palm 700. Hence, each of finger 701, ring finger 703 and middle finger 705 express touch sensor 111-2 at the handle position locations, the pressure of each of which is indicated by arrows 711, 713, 715 respectively on the handle.
Further, as indicated by arrow 711, palm 700 of hand 601 applies pressure to touch sensor 111-1. Hence, touch data noticed by touch sensor 111 in the grip position of hand 601 described in FIG. 7 correspond to pulse-neutral touch data 223.
Furthermore, from FIG. 7 understood that an index finger of hand 601 does not touch any of the touch sensors 111. Indeed, in a wrist neutral position, not all fingers need to touch a touch sensor 111; however, touch sensors 111 are generally provided so that a portion of hand 601 reacts with touch sensors 111 when device 100 is held at least in a wrist-neutral grip. The
However, BE2017 / 5885 exact parts of hand 601 that respond with touch sensors 111 may differ from user to user.
Further, touch sensors 111 may be provided at positions other than a left side and right side of housing 101, as long as touch sensors 111 can detect positions and / or pressure from at least a portion of a hand holding device 100. For example, touch sensors 111 may be provided in any region of housing 101 where hand device 100 holds, including, but not limited to, rear end 102r of housing 101 and front end 102f of housing 101.
In some embodiments, wrist-neutral touch data 223 may be provided at memory 122 when application 251 is provided in memory 122. For example, average handle position locations and / or average pressures at touch sensors 111 while a human hand device 100 grasps in a wrist-neutral position can be heuristically determined from human factors studies and the like, and stored in memory 122. Furthermore, such heuristically determined wrist-neutral touch data 223 can be provided for each of left-handed users and right-handed users, and controller 120 can provide an option to use device 100 in a left-handed mode or a right-handed user. mode, with associated heuristically determined wrist neutral touch data 223 selected, for example using pull down menus, graphical user interfaces (GUI) and the like.
Alternatively, wrist neutral touch data 223 can be provided to device 100 by causing device 100 to enter a learning mode (e.g., at block 501 of method 500). For example, attention is directed to FIG. 8 and FIG. 9, (which are substantially the same as FIG. 1 and FIG. 4, respectively, in which the same elements have the same numbers) in which device 100 is arranged to enter a learning mode, for example using pull down menus, GUIs and the like. In the learning mode, as described in FIG. 8, controls regulator 120
BE2017 / 5885 display 107 to display instructions for holding device 100 in a wrist neutral grip, as well as instructions for collecting wrist neutral touch data 223 once device 100 is held in a wrist neutral grip. In particular, FIG. 8 arrows 711, 713, 715, 717 which are applied to certain grip position locations on touch sensors 111, which indicate both a position and a pressure of parts of a hand that react with touch sensors 111 in a wrist-neutral grip (e.g. as in FIG. 7). Once the wrist neutral grip is achieved, actuator 115 can be actuated, and, as described in FIG. 9, controller 120 can ensure that pulse-neutral touch data 223 is collected at touch sensors 111 and stored in memory 122.
Certainly, wrist-neutral touch data 233 can be specifically for a particular user. For example, a first user may have all four fingers interacting with touch sensors 111 in a wrist neutral position, while a second user may only have his little finger interacting with touch sensors 111 in a wrist neutral position. Furthermore, wrist-neutral touch date 223 is generally different for right-handed users than for left-handed users. The learning mode as described in FIG. 8 and FIG. 9 can ensure that wrist-neutral touch data 223 can be adjusted and / or provided for a specific user. Hence, controller 120 can be further configured to enter a learning mode to: receive wrist neutral touch data 223 from one or more touch sensors 111; and store wrist neutral touch date 223 in memory 122.
Certainly, when pulse-neutral touch data 223 is determined using the learning mode, such pulse-neutral touch data 223 can be stored in memory 122 associated with user certificates and / or sent to a server with the user certificates, and the like, in a cloud-based environment (e.g., use
BE2017 / 5885 creating user interface 224) for storage associated with the user certificates. Each time the associated user certificates are used to log into device, the wrist-neutral touch data 223 can be provided to device 100 by the server (again using interface 224) and / or used to determine wrist-neutral grasp of device 100.
Furthermore, controller 120 can receive touch data from touch sensors 111 and compare such touch data with pulse-neutral touch data 223 to determine whether device 100 is held in a wrist-neutral grip, or whether the device 100 is not held in wrist-neutral grip (e.g., at block 507 of method 500) .
For example, attention is directed to Fig. 10 which shows hand 601 keeping device 100 outside of a wrist neutral grip; in particular, hand 601 is in an elbow-tube deviation position such that hand 601 is at an angle θ with respect to wrist 603. For example, handle position locations and / or pressure of each of palm 700, little finger 701, ring finger 703, and middle finger 705 on touch sensors 111 may change relative to what is described in FIG. 7, as indicated by arrows 1017, 1011, 1013, 1015 respectively. In particular, arrows 1017, 1011, 1013, 1015 indicate different positions and / or pressures than positions and / or pressures indicated by arrows 717, 711, 713 715 of FIG. 7. For example, in such an ulcer, pressure on touch sensor 111-2 exerted by little finger 701 may increase, and pressure on touch sensor 111 exerted by palm 700 and fingers 703, 705 may also change. Such changes may depend on a user; however, such changes generally cause touch data noticed at touch sensors 111 to be different from wrist neutral touch data 223.
Hence, referring to FIG. 11 (which is substantially similar to FIG. 4, wherein the same elements have the same numbers), controller 120 can receive touch data 1123 correspondingly
Compare BE2017 / 5885 with positions and / or pressures indicated by arrows 1017, 1011, 1013, 1015 and touch data 1123 with wrist neutral touch data 223, for example on a continuous basis and / or periodically. In other words, controller 120 monitors touch data from touch sensors 111.
A non-limiting embodiment of block 507 of method 500 is now described, prior to describing blocks 503, 505, because block 507 can be implemented associated with and / or in parallel with blocks 503, 505.
In any case, when touch data 1123 does not match wrist neutral touch data 223 (e.g., at block 507), and referring to FIG. 12 (which is substantially similar to FIG. 1, wherein the same element has the same numbers), controller 120 (e.g., at block 507) controls notification device 299, and in particular display 107, to provide an indicator 1201 with the outside of the wrist-neutral grip of housing 101 and / or device 100.
For example, as described in FIG. 13, regulator 120 monitor 107 displaying instructions to move device 100 back into a wrist-neutral grip. In embodiments shown, such instructions may include an arrow 1203 indicating a direction in which device 100 to move back into the wrist neutral grip; a direction of arrow 1203 can be based on touch data 1123. For example, controller 120 can determine, when pressure through little finger 701 increases relative to wrist neutral touch data 223, that device 100 has undergone an ulcer deviation and instructions provided to move device 100 away from the ulcer deviations (as described); similarly, controller 120 can determine, when pressure through little finger 701 decreases relative to wrist-neutral touch data 223, that device 100 has undergone a spoke deviation and provides instructions to move device 100 away from the spoke deviation. However, such an increase and decrease in pressure of the little finger 701 and / or other fingers may depend on one
BE2017 / 5885 user; certainly in the learning mode described in FIG. 8 and FIG. 9 controller 120 instructs the user to move device 100 in an ulcer and / or a spoke bone abnormality, collect and store associated ulcer disease, touch data and / or spoke bone abnormality, and compare touch data 1123 for determining a direction of movement in which device 100 is positioned to return device 100 to a wrist neutral position.
Certainly illustrate. 10, FIG. 11 and FIG. 12 that block 507 of method 500 can be executed independently of the remaining blocks of method 500.
Furthermore, in other embodiments, an indication that housing 101 and / or device 100 may be located outside of a wrist neutral grip using other types of notification devices, including, but not limited to, speaker 132 (e.g., an audio message and / or alarm can be provided to indicate that housing 101 and / or device 100 is outside a wrist neutral grip) and / or any other notification device, including, but not limited to, lamps, LEDs, haptic devices, and the like. For example, if touch data 1123 does not match wrist neutral touch data 223, controller 120 may cause a light and / or an LED to flash and / or change color, and / or control a vibration motor to vibrate, for example, according to a particular pattern.
Attention is now directed to FIG. 13 which describes different alignment patterns and / or alignment pattern positions and / or alignment directions of data assurance component 105 of device 100. In particular, a base position 1301 of target pattern of data meeting component 105 may include a target direction and / or a field of view of a camera, an annular range over which a laser scanner can scan, and the like. Basic position 1301 may include a central position of data collection component 105. As shown, base position 1301 extends from rear 102r
BE2017 / 5885 of a certain angle, which can be determined by a location of data collection component 105 in housing 101 and a form of housing 101. Indeed, basic position 1301 can be provided and / or selected so that data collection by data collection component 105 can occur at rear 102r of device 100 when device 100 is held at an angle of 45 ° to the ground and / or ground as described. However, basic position 1301 can generally be selected based on ergonomics and / or human factor studies and / or heuristically.
FIG. 13 further describes deviations 1303, 1305 from base position 1301 of the alignment pattern; for example, each of deviations 1303, 1305 indicate that a directional pattern and / or a directional direction can be changed plus 10 ° and / or minus 10 ° from base position 1301. In other words, in some embodiments, a directional pattern and / or a directional direction of data garaging component 105 are controlled +/- 10 ° from base position 1301. However, other orientation patterns and / or orientation directions and / or base positions, and / or deviations from base positions fall within the scope of current embodiments.
In particular, controller 120 is generally arranged to control the alignment pattern of data assurance component 105 according to an orientation marked by orientation sensor 109 (e.g. at block 505 of method 500), as described below, assuming that device 100 is held in a wrist neutral position such as described above.
In some embodiments, target pattern data 273 can be provided in memory 122 by controlling the target pattern of data assurance component 105 when application 251 is provided in memory 122. For example, average target patterns of data assurance component 105 for one or more orientations of housing 101 and / or device 100 while a human hand device 100 grasps in a wrist neutral position, from human factor studies and
BE2017 / 5885, heuristically determined, and stored in memory 122. Furthermore, such heuristically-determined target pattern data 273 can be provided for each of left-handed users and right-handed users, and controller 120 can provide an option for device 100 to be used in a left-handed user. mode or a legal mode, with heuristically determined target pattern data 273 selected thereon. For example, a direction from base position 1301 may be different for each of left-handed users and right-handed users.
Similarly, heuristically determined target pattern data 273 can be determined for a plurality of orientations. For example, a first orientation may correspond to a low orientation, in which device 100 is generally "down"; a second orientation may correspond to a center orientation, wherein device 100 is generally directed directly away from a user holding device 100 (e.g., as shown by FIG. 13); and a third orientation may correspond to a high orientation, wherein device 100 is generally "up". Although each of these orientations are described in relative terms, each can be associated with a respective angle, a respective range of angles and / or a respective set of orientation data noticed by orientation sensor 109, which can be determined and / or measured when the heuristic certain target pattern data 273 is becoming generated. Alternatively, each of the orientations may be associated with predetermined angles and / or predetermined ranges of angles and / or predetermined set of orientation data which may also be heuristically determined.
For example, target pattern data 273 may alternatively be provided to device 100 by entering a learning mode of device 100 (e.g., at block 503 of method 500). For example, attention is directed to FIG. 14, FIG. 15 and FIG. 16, (FIG. 14 and FIG. 15 being substantially similar to FIG. 1 and FIG. 16 being substantially
BE2017 / 5885 similar to FIG. 4, in which the same elements have the same numbers) in which device 100 is arranged to enter a target pattern learning mode, using, for example, pull down menus, GUIs and the like.
In the learning mode, as described in FIG. 14, controller 120 controls display 107 to optionally display an indicator 1401 which includes instructions and select an orientation in which target pattern data will be collected (e.g., a low, middle, or high position, which can be selected using a touch screen, use a pull down menu, a GUI and the like), as well as instructions for collecting target pattern data 273.
Additionally, in the described target pattern learning mode, controller 120 controls display 107 to optionally display one or more digital controls 1403 for controlling the target pattern of data assurance component 105; for example, as described, one or more digital controls 1403 include digital buttons for raising (e.g., a digital button with an up arrow) and lowering (e.g., a digital button with an down arrow) alignment pattern (and / or a direction) as described above with respect to FIG. 13. However, any other type of actuator can be used to control the directional pattern and / or direction of data collateral component 105.
Further, when the alignment pattern is controlled in an orientation compatible position, actuator 115, or any other actuator, can be actuated to store, in memory 122, alignment pattern data corresponding to the current alignment pattern of the selected orientation. Orientation data corresponding to the orientation noted by the orientation sensor 109 can also be stored in memory 122.
In some implementations, while the targeting pattern is adjusted using digital controls 1403 and
BE2017 / 5885, device 100 may be held in a wrist-neutral grip in the associated orientation, with data to be collected provided in the field of view, and the like, of data garaging component 105, such as a barcode, and the like.
Referring to FIG. 15, when the data is collected, controller 210 can control display 107 to display an indicator 1501 thereof, and store the target pattern data corresponding to the current target pattern in memory 122 in the selected orientation. Orientation data corresponding to the orientation as noted by orientation sensor 109 can also be stored in memory 122. Certainly, as described, indication 1501 includes a display of collected data (e.g., a barcode) and an indicator that the target pattern was stored for a particular position (e.g., a low position). Alternatively, at least part of indicator 1501 can be provided when target pattern data is stored for the determined orientation.
Regardless of referring to FIG. 16, controller 120 stores target pattern data 273 corresponding to a current learning mode target pattern in memory 122.
Although not shown, it must be recognized that a reference orientation of device 100 can be provided in the target pattern learning mode. For example, when device 100 is oriented in a "center" orientation, orientation data corresponding to the center orientation can be stored as a reference orientation, and other orientations of device 100 are determined with reference to the reference orientation. In other words, the orientation of device 100 can be determined from an arbitrary position, with orientation data from orientation sensor 109 arranged in accordance with this. Alternatively, orientation data from orientation sensor 109 may be provided in absolute coordinates.
Furthermore, a target pattern of data garaging component 105 should be compatible with display 107 being seen from any
BE2017 / 5885 orientation in which target pattern data 273 is determined, by providing one or more of indicators 1401, 1501 with display 107 while target pattern data 273 is determined.
Further, when the target pattern learning mode of block 503 is implemented to obtain target pattern data, block 507 can be implemented in parallel to block 503 so that target pattern data is obtained in the learning mode only when housing 101 and / or device 100 is in a wrist neutral position; in other words, indicators 1401, 1501 can be replaced at least temporarily by indicator 1201 and the like, to ensure that housing 101 and / or device 100 is returned to a wrist-neutral position when housing 101 and / or device 100 reaches the wrist-neutral position in the learning mode of FIG. 14 and FIG. 15 leaves. Indeed, in some embodiments, target pattern data 273 is only stored when device 100 is in wrist neutral position.
As with pulse-neutral touch data 233, target pattern data 273 may be for a particular user in particular. For example, a first user device 100 may hold slightly higher or lower in a particular orientation and / or have a different grip that causes base position 1301 to be in a different orientation with respect to the ground and / or ground, compared to a second user. The learning mode as described in FIG. 14, FIG. 15 and FIG. 16 can ensure that target pattern data 273 can be adjusted and / or provided for a particular user. Hence, controller 120 can be further arranged to enter a learning mode to: determine target pattern data 273; and storing target pattern data 273 in memory 122.
Certainly, when target pattern data 273 is determined using a learning mode, such target pattern data 273 can be stored in memory 122 associated with user certificates and / or sent to a server, and the like, in a cloud-based environment
BE2017 / 5885 (for example, using interface 224) for storage in association with the user certificates. Each time the associated user certificates are used to log into device, the target pattern data 273 can be provided to device 100 from the server (again using interface 224) and / or used by controller 120 to implement block 505 of method 500 .
In particular, in some embodiments, memory 122 may store target pattern data 273 associated with one or more orientations (e.g., from housing 101 and / or device 100), and controller 120 may further be arranged to: when touch data 1123 corresponds to wrist neutral touch data 223, control the alignment pattern of data collection component 105 according to alignment pattern data 273 associated with the orientation marked by orientation sensor 109. In some of these embodiments, controller 120 may be further arranged to enter a learning mode for determining alignment pattern data for each of the one or more orientations. In some of these embodiments, target pattern data 273 associated with one or more orientations may include: low target pattern data associated with a low orientation, middle target pattern data associated with a middle orientation, and high target pattern data associated with a high orientation, each of the low, middle, and high orientations being defined with a certain angle, range of angles and / or set of orientation data.
Attention is then directed to FIG. 17, FIG. 18, and Fig. 19 respectively describing device 100 held in hand 601 in three orientations: a low orientation in FIG. 17, middle orientations in FIG. 18 and a high orientation in FIG. 19. In each of FIG. 17, FIG. 18, and FIG. 19 is hand 601 in a wrist neutral position and / or a wrist neutral angle with respect to wrist 603, as indicated by line 1701. However, in the center orientation of FIG. 18, hand 601 and wrist 603 are lifted compared to the low orientation of FIG. 17, and / or lowered
BE2017 / 5885 compared to the high orientation of Fig 19; in other words, a user lifts and / or lowers his arm to collect data using device 100 (e.g., objects at another position), with hand 601 held in the wrist neutral position while the arm is raised and / or lowered . However, such lifting and / or lowering can change the orientation of device 100 (and / or housing 101). In particular, device 100 can be positioned in any orientation such that display 107 is visible to user, as described respectively in each of FIG. 17, FIG. 18 and Fig 19 by arrows 1702, 1802, 1902.
Hence, on each of the orientations as described in each of FIG. 17, FIG. 18 and Fig. 19 controller 120 controls the orientation pattern and / or orientation direction of data assurance component 105 according to the orientation noted by orientation sensor 109. For example, an average orientation pattern and / or average orientation direction of data assurance component 105 changes into which data is gathered from orientation to orientation according to orientation pattern data 273 ( for example, at block 505 of method 500) and a directional direction of data collateral component 105 indicated in each of FIG. 17, FIG. 18 and Fig. 19 by arrows 1703, 1803, 1903. The directional pattern data 273 defining such directional directions can be determined as described above with respect to FIG. 14, FIG. 15 and FIG. 16.
Furthermore, the user does not need to tilt device 100 to see data garment confirmation, because with each orientation described in each of FIG. 17, FIG. 18 and Fig. 19, screen 17 is visible to a user; on the other hand, the alignment pattern of data collateral component 105 is controlled in any orientation to collect data in a direction compatible with such viewing of display 107.
Provided for this is a device for wrist-neutral data collection which includes touch sensors for detecting handle position locations around
BE2017 / 5885 to determine if the device is being held in a wrist-neutral position. If not, an indicator is provided, and which can be provided alternately until the device is returned to the wrist neutral position and / or before data collection occurs. Such a device promotes wrist-neutral ergonomics for data collection such as scanning barcodes and verifying barcodes under different data garment orientations and / or scanning conditions, which can also eliminate and / or reduce a need to tilt the device to see a display thereof since a target pattern of the data assurance component is controlled relative to an orientation of the device, and the targeting pattern can be controlled so that the display is visible to the user. Such embodiments may suffer from limited wrist abnormality, limited wrist stress, limited fatigue, a reduction in wasted movements, an increase in comfort and therefore an increased spare capacity, increased accuracy, and increased productivity, may further enable workers to do data collection with reduced physical effort.
Specific embodiments have been described in the foregoing description. However, it will be apparent to one skilled in the art that multiple modifications and changes can be made without departing from the scope of the inventions set forth in the claims below. Accordingly, the description and the figures must be viewed in a clarifying, rather than limiting, sense, and all such modifications are intended to be included in the scope of the present teachings. For the purpose of clarity and a concise description, features are described herein as part of the same or different embodiments, although it will be understood that the scope of the invention may include embodiments that have combinations of all or some of the features described. It will be clear
BE2017 / 5885 are that the embodiments shown have the same or identical parts, except where they are described as different.
The benefits, solutions of problems, and any (all) element (s) that (can) cause any benefit, or solution, or become more pronounced (Zkunnen) are not to be explained as a crucial , required, or essential feature or component in any or all of the claims. The invention is only defined by the appended claims, including some improvements made during the granting procedure of this application and all equivalents of those claims as issued.
In addition, in this document, related terms such as first and second, above and below, and the like, may only be used to distinguish an entity or action from another entity or action, without necessarily requiring or implying an actual relationship or order between such entities or promotions. The terms "include," "including," "has," "including," "includes," "includes," "includes," or any other variation thereof, are intended as a non-exclusive inclusion, so that a process, method, article, or device that includes, includes, contains a list of elements, not only contains those elements, but possibly contains other elements that are not explicitly listed or that are not inherent in such a process, method, article, or device. An element preceded by "includes ... a," "has ... a," "includes ... a," "contains ... a," without limitation, does not exclude the existence of additional identical elements in the process, method, article, or device that comprises the element, is provided with, or contains. The term "one" is defined as one or more unless explicitly stated otherwise herein. The terms "substantially," "essential," "approximately," or any other variation thereof, are defined as being close to that understood by a person skilled in the art, and in a certain non-limiting embodiment, the term is defined as being within 10%,
BE2017 / 5885 in another embodiment as being within 5%, in another embodiment as being within 1%, and in another embodiment as being within 0.5%. The term "coupled" as used herein is defined as connected, although not necessarily directly and not necessarily mechanically. A device or structure that is "configured" in a certain way is at least configured that way, but may also be configured in ways that are not listed.
It will be understood that for this description, terms such as "at least one of X, Y, and Z" and "one or more of X, Y, and Z" can be constructed as only X, only Y, only Z, or any combination of two or more parts X, Y, and Z (e.g., XYZ, XY, YZ, XY, and the like). The same logic can be applied to two or more parts in any event of "at least one of ..." and "one or more of ..." terms.
It will be understood that some embodiments may include one or more generic or specialized processors (or "processing devices") such as microprocessors, digital signal processors, custom processors, and FPGAs (field-programmable gate arrays), and unique, stored program instructions (including both software and firmware) that control one or more processors to perform, in combination with certain circuitry without processors, some, most, or all functions of the method and / or device described herein. Alternatively, some or all of the functions may be performed by a state machine that has no stored program instructions, or in one or more application-specific integrated circuits (ASICs), in which each function or some combinations of the functions are implemented as custom logic. Naturally, a combination of the two approaches can be used.
BE2017 / 5885
In addition, an embodiment may be implemented as a computer program product provided with computer readable code stored thereon for programming a computer (e.g., including a processor) to perform a method as described and claimed herein. Examples of such computer program products include, but are not limited to, a hard disk, a CD-ROM, an optical storage device, a magnetic storage device, a ROM (read only memory), a PROM (programmable read only memory), an EPROM (erasable programmable) read-only memory), an EEPROM (electrically erasable programmable read-only memory) and a flash memory. Furthermore, it can be expected that a person skilled in the art, notwithstanding possible significant difficulties and many design choices motivated by, for example, available time, current technology, and economic considerations, when guided by the concepts and principles described herein, will be able to easily with minimal experimentation. generating such software instructions and programs and integrated circuits.
The extract of the description is provided to allow the reader to quickly ascertain the nature of the technical description. It is submitted with the intention that it will not be used to explain or limit the scope of protection or the meaning of the claims. In addition, it can be seen in the foregoing detailed description that various features are grouped together in various embodiments for the purpose of simplifying the description. This method of describing should not be interpreted as expressing the intention that the claimed embodiments require more features than are explicitly stated in each claim. Rather, as the following claims show, inventive subject matter is contained in less than all the features of a single described embodiment. Thus are the following claims
BE2017 / 5885 hereby included in the detailed description, with each conclusion standing alone as a separately claimed subject matter. The mere fact that certain measures are cited in different claims gives no indication that a combination of these measures cannot be used to achieve an advantage. Many variants will be clear to the skilled person. All variants must be construed as being included in the scope of the invention as defined in the following claims.

权利要求:
Claims (19)
[1]
A mobile device comprising:
a housing comprising a front side and a rear side;
a data gathering component provided on the rear of the housing, wherein the data gathering component is arranged to change a target pattern;
a screen provided on the front of the housing;
an orientation sensor adapted to detect an orientation of the housing;
one or more touch sensors on the housing;
a memory which stores pulse-neutral touch data associated with a pulse-neutral grip corresponding to predetermined grip positions on the one or more touch sensors;
and a controller adapted to:
when touch data received by the one or more touch sensors corresponds to the pulse neutral touch data stored in the memory, controlling the alignment pattern of the data collateral component according to the orientation noted by the orientation sensor; and when the touch data does not match the wrist neutral touch data, controlling a notification device to provide an indicator that the housing is outside the wrist neutral handle.
[2]
The mobile device of claim 1, wherein the memory further stores target pattern data associated with one or more orientations, and the controller is further adapted to control the target pattern of the data assurance component associated with the target pattern data associated with the pulse-neutral touch data with the orientation noticed by the orientation sensor.
BE2017 / 5885
[3]
The mobile device of claim 2, wherein the controller is further adapted to enter a learning mode for determining the target pattern data for each of the one or more orientations.
[4]
The mobile device according to claim 2 or 3, wherein the target pattern data associated with one or more orientations comprises: low target pattern data associated with a low orientation, middle target pattern data associated with a middle orientation, and high target pattern data associated with a high orientation.
[5]
The mobile device of any one of the preceding claims, wherein the controller is further adapted to enter a learning mode to: receive the wrist neutral touch data from the one or more touch sensors; and storing the wrist neutral touch data in the memory.
[6]
The mobile device according to any of the preceding claims, wherein the controller is further adapted to control the alignment pattern of the data collection component according to the orientation by changing the alignment pattern plus 10 ° or minus 10 ° of a base position.
[7]
The mobile device according to any of the preceding claims, wherein the orientation is defined with respect to the front of the housing.
[8]
The mobile device according to any of the preceding claims, wherein the data assurance component comprises one or more of a scanner and a camera.
[9]
The mobile device according to any of the preceding claims, wherein the notification device comprises one or more of a display, an auditory notification device, a visual notification device and a haptic notification device.
[10]
The mobile device according to any of the preceding claims, wherein the orientation sensor comprises one or more of an accelerometer, a three-axis accelerometer, a three-axis microelectromechanical system
BE2017 / 5885 (MEMS) accelerometer, a three-dimensional orientation sensor, a magnetometer and a gyroscope.
[11]
11. A method comprising:
provided with a device, for example a mobile device according to one of the preceding claims, comprising: a housing with a front side and a rear side; a data assurance component provided on the rear of the housing, the data assurance component adapted to change a target pattern; a screen provided on the front of the housing; an orientation sensor adapted to detect an orientation of the housing; one or more touch sensors on the housing; a memory storing pulse-neutral touch data associated with a pulse-neutral grip corresponding to predetermined grip position locations at the one or more touch sensors; and a controller, when touch data received by the one or more touch sensors corresponds to pulse neutral touch data stored in the memory, using the controller, controls the target pattern of the data assurance component according to the orientation detected by the orientation sensor; and when the touch data does not match the wrist neutral touch data, using the controller, controls a notification device to provide an indicator that the housing is outside the wrist neutral grip.
[12]
The method of claim 11, wherein the memory further stores target pattern data associated with one or more orientations, and the method further comprises, when the touch data matches the wrist neutral touch data, controlling the target pattern of the data assurance component according to the target pattern data associated with the orientation noticed by the orientation sensor.
BE2017 / 5885
[13]
The method of claim 12, wherein the method further comprises going into a learning mode of the controller for determining the target pattern data for each of the one or more orientations.
[14]
The method of claim 12 or 13, wherein the target pattern data associated with one or more orientations comprises: low target pattern data associated with a low orientation, middle target pattern data associated with a middle orientation, and high target pattern data associated with a high orientation.
[15]
The method of any one of the preceding claims 11-14, wherein the method further comprises going into a learning mode of the controller for: receiving the wrist neutral touch data from the one or more touch sensors; and storing the wrist neutral touch data in the memory.
[16]
The method of any one of the preceding claims 11-15, wherein the method further comprises controlling the target pattern of the data collection component according to the orientation by changing the target pattern plus 10 ° or minus 10 ° of a base position.
[17]
The method of any one of the preceding claims 11-16, wherein the orientation is defined with respect to the front of the housing.
[18]
The method of any one of the preceding claims 11-17, wherein the data assurance component comprises one or more of a scanner and a camera.
[19]
The method of any one of the preceding claims 11-18, wherein the notification device comprises one or more of a display, an auditory notification device, a visual notification device and a haptic notification device.

类似技术:

---

公开号 | 公开日 | 专利标题

---

US10613742B2|2020-04-07|Method of providing user interaction with a wearable device and wearable device thereof

---

EP3252640B1|2019-05-01|Method for launching application and terminal

---

US10528780B2|2020-01-07|Wearable mobile electronic devices

---

US10438409B2|2019-10-08|Augmented reality asset locator

---

US11244264B2|2022-02-08|Interleaving surprise activities in workflow

---

US20170123598A1|2017-05-04|System and method for focus on touch with a touch sensitive screen display

---

KR101855233B1|2018-06-26|Device and method for inputting of terminal device using a pen

---

WO2016100548A2|2016-06-23|Floating soft trigger for touch displays on electronic device

---

EP3399461B1|2019-12-11|Optical fingerprint verification method and mobile terminal

---

US10810541B2|2020-10-20|Methods for pick and put location verification

---

JP2014085954A|2014-05-12|Portable terminal device, program and input operation accepting method

---

EP3686720A1|2020-07-29|Method and apparatus for identifying fingerprint, electronic device, and computer readable storage medium

---

US20180011631A1|2018-01-11|Floating soft trigger for touch displays on electronic device

---

US10585498B2|2020-03-10|Apparatus and method for identifying object

---

BE1025467B1|2019-03-13|MOBILE DEVICE WITH WRIST NUTRAL DATA COLLECTION

---

CN107665434B|2020-09-25|Payment method and mobile terminal

---

KR20160095433A|2016-08-11|Method for providing a notification and electronic device supporting the same

---

US20120262399A1|2012-10-18|Apparatus, method, computer program and user interface

---

CN108052820B|2021-06-15|Unlocking control method, terminal equipment and related product

---

US10546204B1|2020-01-28|Item information discovery with a wearable device

---

CA2947858C|2019-11-12|Apparatus and method for performing a variable data capture process

---

CN106708389B|2019-11-05|A kind of method and mobile terminal of control display interface scaling

---

CN108463798B|2021-08-24|Size adjustable icons for touch screens on electronic devices

---

US10234826B2|2019-03-19|Wearable device and control method therefor

---

US20160355352A1|2016-12-08|Systems and methods for controlling checkout belt speed

同族专利:

---

公开号 | 公开日

---

BE1025467A1|2019-03-06|

---

WO2018106364A1|2018-06-14|

---

US10303908B2|2019-05-28|

---

US20180157880A1|2018-06-07|

引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

US5796088A|1995-08-15|1998-08-18|Teletransactions, Inc.|Hand held portable bar code dataform reader having a rotatable reader module portion|

---

US20090121026A1|2006-08-20|2009-05-14|Scantask Ltd.|Palm-back support and a tool supported by|

---

US20110290889A1|2010-05-28|2011-12-01|Datalogic Scanning, Inc.|Data reader with multiple modes of operation|

---

WO2015100244A1|2013-12-26|2015-07-02|Drexel University|Soft magnetic composites for electric motors|

---

US20150323997A1|2014-05-06|2015-11-12|Symbol Technologies, Inc.|Apparatus and method for performing a variable data capture process|

---

US7924323B2|2003-12-24|2011-04-12|Walker Digital, Llc|Method and apparatus for automatically capturing and managing images|

---

US8635309B2|2007-08-09|2014-01-21|Hand Held Products, Inc.|Methods and apparatus to change a feature set on data collection devices|

---

US9129172B2|2011-06-20|2015-09-08|Metrologic Instruments, Inc.|Indicia reading terminal with color frame processing|

---

WO2013067671A1|2011-11-07|2013-05-16|Honeywell Scanning And Mobility|Optical indicia reading terminal with color image sensor|

---

US9202095B2|2012-07-13|2015-12-01|Symbol Technologies, Llc|Pistol grip adapter for mobile device|US10503391B2|2017-11-17|2019-12-10|Motorola Solutions, Inc.|Device, system and method for correcting operational device errors|

法律状态:
2019-05-02| FG| Patent granted|Effective date: 20190313 |

优先权:

---

申请号 | 申请日 | 专利标题

---

US15/370,330|US10303908B2|2016-12-06|2016-12-06|Mobile device with wrist neutral data capture|

---

US15370330|2016-12-06|

---