• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to an image forming pixel. The imaging pixel includes a photodetector that outputs charge signals in response to light and incident laser pulses, as well as a high frequency path. A detector bias circuit is also provided, which polarizes high frequency signals of the charge signals that are associated with the laser pulses to follow the high frequency path. The detector bias circuit effectively filters low frequency signal components of the charge signals from the high frequency path tracking.
    公开号:BE1024892B1
    申请号:E2017/5017
    申请日:2017-01-13
    公开日:2018-08-21
    发明作者:Minlong Lin;Joshua Lund
    申请人:Sensors Unlimited Inc.;
    IPC主号:
    专利说明:

    (30) Priority data:
    01/15/2016 US 14997184 (73) Holder (s):
    SENSORS UNLIMITED INC. 08540, PRINCETON United States (72) Inventor (s):
    LIN Minlong
    08536 PLAINSBORO
    United States
    LUND Joshua 75214 DALLAS United States (54) Pulse detection bandpass filter with gain stage
    i.® (57) The invention relates to an image forming pixel. The imaging pixel includes a photodetector which outputs charge signals in response to light and incident laser pulses, as well as a high frequency path. A detector bias circuit is also provided which polarizes high frequency signals from charge signals which are associated with the laser pulses to follow the high frequency path. The detector bias circuit effectively filters components of low frequency signals from load signals from the tracking of the high frequency path.
    , 110 "- * · <
    BELGIAN INVENTION PATENT
    FPS Economy, SMEs, Middle Classes & Energy
    Publication number: 1024892 Deposit number: BE2017 / 5017
    Intellectual Property Office International Classification: F41G 7/22 H04N 5/30 Date of issue: 08/21/2018
    The Minister of the Economy,
    Having regard to the Paris Convention of March 20, 1883 for the Protection of Industrial Property;
    Considering the law of March 28, 1984 on patents for invention, article 22, for patent applications introduced before September 22, 2014;
    Given Title 1 “Patents for invention” of Book XI of the Code of Economic Law, article XI.24, for patent applications introduced from September 22, 2014;
    Having regard to the Royal Decree of 2 December 1986 relating to the request, the issue and the maintenance in force of invention patents, article 28;
    Given the patent application received by the Intellectual Property Office on January 13, 2017.
    Whereas for patent applications falling within the scope of Title 1, Book XI of the Code of Economic Law (hereinafter CDE), in accordance with article XI. 19, §4, paragraph 2, of the CDE, if the patent application has been the subject of a search report mentioning a lack of unity of invention within the meaning of the §ler of article XI.19 cited above and in the event that the applicant does not limit or file a divisional application in accordance with the results of the search report, the granted patent will be limited to the claims for which the search report has been drawn up.
    Stopped :
    First article. - It is issued to
    SENSORS UNLIMITED INC., 330 Carter Road, Suite 100, 08540 PRINCETON United States;
    represented by
    OFFICE KIRKPATRICK S.A., Avenue Wolfers 32, 1310, LA HULPE;
    a 20-year Belgian invention patent, subject to the payment of the annual fees referred to in article XI.48, §1 of the Code of Economic Law, for: Bandpass filter for pulse detection with gain stage.
    INVENTOR (S):
    LIN Minlong, 16 Harvest Drive, 08536, PLAINSBORO;
    LUND Joshua, 5321 Ridgelawn Drive, 75214, DALLAS;
    PRIORITY (S):
    01/15/2016 US 14997184;
    DIVISION:
    divided from the basic application: filing date of the basic application:
    Article 2. - This patent is granted without prior examination of the patentability of the invention, without guarantee of the merit of the invention or of the accuracy of the description thereof and at the risk and peril of the applicant (s) ( s).
    Brussels, 08/21/2018, By special delegation:
    BE2017 / 5017
    PULSE DETECTION BAND PASS FILTER WITH GAIN STAGE
    BACKGROUND OF THE INVENTION
    1. Field of 1 1 invention
    The present invention relates to pulse detection, and more particularly to pulse detection by means of a bandpass filter with a gain stage.
    . Description of Related Art
    Multiband image sensors can be used for the simultaneous capture and playback of images whose signal content spans a wide spectrum of time frequencies. However, conventional imaging pixels are limited in their ability to distinguish signals based on their time frequencies. For example, an image may include a short signal, such as a laser pulse, and a constant signal, such as reflected sunlight. A conventional pixel is limited in its ability to distinguish and precisely detect these signals
    BE2017 / 5017 whose content has very different time frequencies.
    In a military application, coded laser pulses can be applied to an imaged object to identify the object on the image. The objective is to generate a single image which shows the object identified on the basis of the coded laser pulses. There is a big difference between the signal frequency associated with the laser pulses and the signal frequency associated with the imaged object. It often happens that an absolute signal intensity of a laser pulse signal in photons is much lower than a background signal intensity of the imaged object. In conventional image-forming devices, an individual pixel is unable to capture an image of the laser with adequate sensitivity because it cannot distinguish between the energy of the laser pulse signal and the background signal energy of the image.
    Although conventional methods and systems have been generally considered satisfactory for the use for which they were intended, there is still a need in this technical field for pixels to have an increased bandwidth for multiband detection in order to allow detection signals having content at high time frequencies, such as signals associated with laser pulses, with high sensitivity while simultaneously imaging a background scene having content at low time frequencies. We need an individual pixel to be able to capture an image of a
    BE2017 / 5017 laser output and an object targeted by the laser. The present invention provides a solution to this problem.
    SUMMARY OF THE INVENTION
    The objective and the advantages of the embodiments illustrated and described below will be explained and will appear more clearly in the description which follows. Other advantages of the illustrated embodiments will be realized and attained by the devices, systems and methods presented in more detail in the written description and the associated claims, as well as through the appended drawings.
    To take advantage of these and other advantages, and in accordance with the objective of the illustrated embodiments, the present invention relates, in a first aspect, to an image forming pixel. The imaging pixel includes a photodetector which outputs charge signals in response to light and incident laser pulses, as well as a high frequency path. A detector bias circuit is also provided which polarizes high frequency signals from charge signals which are associated with the laser pulses to follow the high frequency path. The detector bias circuit effectively filters low frequency signals from load signals from the tracking of the high frequency path.
    In embodiments, the detector bias circuit may include a transistor.
    The detector bias circuit may change the impedance in response to a frequency of a signal received by the detector bias circuit. In addition, the
    BE2017 / 5017 high frequency path can be independent of the detector bias circuit.
    Furthermore, in embodiments, the image forming pixel may further include an adaptive low-pass filter coupled to the high frequency path that receives the high frequency signals. The adaptive low-pass filter can suppress signal components exceeding a frequency threshold from high frequency signals, and output a component of low frequency signals from high frequency signals. The adaptive low-pass filter can be configured with a bandwidth chosen to correspond to a limit rate of laser pulses. The low frequency component output from the adaptive low pass filter can retain charge information in the laser pulses.
    On the other hand, in embodiments, the imaging pixel may further include an adaptive high pass filter which can receive the component of low frequency signals and suppress spurious low frequency components from the component of high frequency signals received. The suppressed parasitic low frequency component may correspond to slowly varying background variations in the low frequency signal component.
    Furthermore, in embodiments, the image forming pixel may further include a gain stage which can receive and amplify the output of the adaptive high pass filter and output a signal having a shape suitable for reading. digital.
    In one aspect, the invention relates to an image forming device which includes a matrix
    BE2017 / 5017 focal plane which includes an image forming pixel array.
    According to one aspect, the invention relates to a method for processing, by bandpass filter, multiband signals outputted in an imaging pixel to obtain useful pulse information. The method includes receiving charge signals which correspond to light and detected incident laser pulses, polarizing high frequency signals of charge signals which are associated with the laser pulses to follow a high frequency path, and efficient filtering. of low frequency signals load signals from tracking the high frequency path.
    In embodiments, the method may include removing from the high frequency signals signal components exceeding a frequency threshold, and outputting a low frequency signal component from the high frequency signals. The method may further include removing spurious low frequency components from the high frequency signal component.
    BRIEF DESCRIPTION OF THE FIGURES
    So that the person skilled in the art to which the present invention is directed can easily understand how to make and use the devices and methods of the present invention without resorting to unnecessary experiments, several embodiments of the invention will be described in detail below. after referring to the figures, in which:
    Fig. 1 represents a schematic diagram of an exemplary embodiment of a training pixel
    BE2017 / 5017 image providing bandwidth processing for processing laser pulses captured according to embodiments of the present invention; and Fig. 2 is a functional diagram of an image forming device comprising an array of image forming pixels as shown in FIG. 1.
    DETAILED DESCRIPTION
    The following description will refer to the drawings in which like reference numbers identify structural elements or similar aspects of the invention. For purposes of explanation and illustration without limitation, a schematic diagram of an embodiment having the value of an improved pixel for multiband processing according to the invention is presented in FIG. 1 and generally designated by the reference number 100. Other embodiments of an improved pixel according to the invention, or certain aspects of it, are presented in FIG. 2, as will be described later.
    An improved pixel 100 for multiband processing is shown by way of example in FIG. 1. The enhanced pixel 100 includes a photodetector 102 which transmits charge signals in response to a detected excitation signal, such as photons from an IR radiation light source or a laser. The photodetector 102 converts the excitation signal into electrical charge signals. Load signals can include high frequency (HF) laser pulse signals and low frequency (LF) image signals. The improved pixel 100 further includes one or more components
    BE2017 / 5017 circuit, which may include a detector bias circuit 104, an adaptive low-pass filter 106, an adaptive high-pass filter 108 and a gain stage 110. The circuit components 104, 106,
    108 and 110 may be individual electronic devices, or one or more of the circuit components 104, 106, 108 and 110 may share one or more electronic devices.
    The detector bias circuit 104 and the photodetector 102 are both coupled to a node 112 of the enhanced pixel 100. The detector bias circuit 104 responds to charge signals output from the photodetector 102 based on a frequency of the charge signals. While maintaining a DC voltage across the photodetector 102, the detector bias circuit 104 responds to high frequency load components output from the photodetector 102 by causing high frequency currents associated with the photodetector 102 charge signals. Due to a high input impedance of both the detector bias circuit 104 and the adaptive low pass filter 106, the high frequency incident load signals have instantaneous load integration at node 112 associated with the capacitance of the photodetector 102 and the parasitic capacitances at the node 112.
    The detector bias circuit 104 may include one or more electrical devices that change the impedance in response to the frequency of the load signals. An example of such electrical devices which change the impedance in response to the frequency of a received signal is a transistor with a
    BE2017 / 5017 fixed DC polarization applied to its grid. Another example of an electrical device is a transistor having a gate controlled by the output of an operational amplifier which includes one or more transistors. The transistor can sample a voltage at 112 and form a negative feedback loop. Depending on the bias of the photodetector 102, the transistor can be an NMOS transistor or a PMOS transistor. The impedance across the detector bias circuit 104 may increase when the frequency associated with the load signal is high, allowing charge signals having a low frequency to flow through the detector bias circuit 104 to a low frequency path (not shown), and allows load signals having a high frequency to accumulate at an input of the detector bias circuit 104 and to follow a high frequency path 114. The load signals having a low frequency are effectively filtered and prevented from traveling through the high frequency path 114.
    By responding to the frequency output by the photodetector 102, the detector bias circuit 104 can provide real-time adaptive filtering of the current associated with the load output by the photodetector 102. In particular, by increasing the impedance in response to an increase in frequency, the detector polarization circuit 104 polarizes the charge at the output of the photodetector 102 to propagate it on the high frequency path 114 serving as an alternative path to the crossing of the detector polarization circuit 104.
    BE2017 / 5017
    The high frequency signals which propagate on the high frequency path 114 are filtered by the adaptive low pass filter 106. The adaptive low pass filter 106 may include, for example, a buffer, an amplifier or an electrical circuit having '' an equivalent resistance followed by a capacitor. The adaptive high-pass filter 108 is set to pass low frequency components of the signal, in which a bandwidth of the frequency that is allowed to pass corresponds to an optimized frequency bandwidth which excludes low noise interference frequency while preserving high frequency laser signals.
    The impedance of the adaptive low-pass filter 106 varies intrinsically in response to changes in the frequency content of signals that reach the adaptive low-pass filter 106. As the frequency increases, the impedance increases, preventing high-frequency components of the laser pulse signals to pass through the adaptive low-pass filter 106. In an embodiment having the value of a non-limiting example, the bandwidth of the adaptive low-pass filter 106 can be adjusted, by varying a bias current applied to an amplifier integrated in the adaptive low-pass filter 106. The bandwidth of the adaptive low-pass filter 106 can be optimized to include most of the energy included in the signals. laser pulses while retaining high frequency signals. Thus, by only letting through the set bandwidth of the charge signal associated with a laser pulse signal, the adaptive low-pass filter 106 preserves the charge information in the pulse signals.
    BE2017 / 5017 laser, while reducing noise to a minimum. In doing so, the adaptive low-pass filter can suppress signal components above a frequency threshold from high frequency signals, and output a component of low frequency signals from high frequency signals.
    The detector bias circuit 104, which controls the propagation of high frequency signals on the high frequency path 114, effectively performs high pass filtering. Thus, the detector bias circuit 104 in combination with the adaptive low pass filter 106 forms an effective band pass filter which filters high frequency pulses from the multiband signals and which further filters a low frequency portion of the pulses. , which allows to keep the associated charge information.
    In embodiments, the adaptive high pass filter 108 is included to provide additional band pass filtering to clean up the pulse signal output from the adaptive low pass filter 106 by removing unwanted low frequency components. The adaptive high-pass filter 108 may include, for example, an electrical circuit in which a capacitor is followed by an equivalent resistance. For example, the adaptive high pass filter 108 can suppress unwanted slowly varying background noise.
    The cleaned signal which leaves the adaptive high-pass filter 108 comprises a low frequency part of the desired high frequency component which has been polarized by the detector bias circuit 104 to propagate on the high frequency path 114,
    BE2017 / 5017 which is freed from parasitic DC background noise with slow variation by the adaptive high-pass filter 108. The gain stage 110 can be a single-stage or multi-stage amplifier which amplifies the signal output by the adaptive high pass filter 108 for providing a signal having a shape which is suitable for sampling in the form of analog voltage and for reading by a reading circuit (not shown). In nonlimiting examples, the gain stage 110 may include a common source amplifier, a common gate amplifier, a comparator followed by an amplifier, or any device (s) capable of amplifying signals. output from the adaptive high pass filter 108 to levels which can be sampled or differentiated as signals having voltages distinctly below or above a threshold voltage.
    In embodiments, the adaptive high-pass filter 106 can be configured to be an integral part of the detector bias circuit 104. In this embodiment, the architecture remains the same as that described, except that the filter adaptive low pass 106 is integrated in the detector bias circuit 104, in which the output of the adaptive low pass filter 106 is always supplied to the adaptive high pass filter 108. The output of the gain stage 110 can be controlled by a switching circuit (not shown) which can be associated with a signal reading circuit (not shown).
    According to one embodiment, a method having the value of an example is provided for processing, by bandpass filter, multiband signals output at a
    BE2017 / 5017 image forming pixel for obtaining useful pulse information. The method includes receiving charge signals which correspond to light and detected incident laser pulses, deflecting high frequency signals from charge signals which are associated with the laser pulses to follow a high frequency path, and efficient filtering. of low frequency signals load signals from tracking the high frequency path.
    In embodiments, the method may include suppressing high frequency components from the high frequency signals, and outputting a component of low frequency signals from the high frequency signals. The method may further include removing spurious low frequency components from the high frequency signal component.
    Referring now to FIG. 2, an image forming device 200 is illustrated which includes a focal plane array 202 (for example, an integrated reading circuit (ROIC)) having an array of enhanced pixels 100 disposed on a substrate 204. The forming apparatus Image 200 may further include optical elements, row and column control circuits, decoders, signal processing circuits, and image control circuits (not shown). In addition, the image forming device 200 may include one or more processing devices (not shown) which execute stored programmable instructions for controlling and / or performing functions of the image forming device 200.
    BE2017 / 5017
    The methods and systems of the present invention, as described above and represented in the drawings, make it possible to provide bandwidth processing of the charge of photodetectors output to produce a clean signal which corresponds to pulses and which stores the charge information associated with the laser pulses, and ensures an amplification of the own signal to provide a signal suitable for digital processing. Although the apparatus and methods of the present invention have been presented and described with reference to embodiments, those skilled in the art will readily perceive that various changes and / or modifications may be made thereto without departing from the spirit and scope of the present invention.
    BE2017 / 5017
    权利要求:
    Claims (18)
    [1]
    1. Image forming pixel including:
    a photodetector outputting charge signals in response to light and incident laser pulses;
    a high frequency path;
    a detector bias circuit for biasing high frequency signals of charge signals which are associated with laser pulses to follow the high frequency path and which effectively filter low frequency signals from charge signals from path following high frequency; and an adaptive low pass filter which changes the impedance in response to frequency changes of the high frequency signals, the adaptive low pass filter being coupled to the high frequency path which receives the high frequency signals and outputs a component of low frequency signals signals from
    [2]
    2 0 high frequency.
    2. An imaging pixel according to claim
    1, in which the detector bias circuit comprises a transistor,
    [3]
    3. Image forming pixel according to claim 1, in which the high frequency path is independent of the detector bias circuit,
    [4]
    The image forming pixel of claim 2, wherein the low pass filter
    Adaptive BE2017 / 5017 removes signal components above a frequency threshold from high frequency signals.
    [5]
    5. The imaging pixel of claim
    4, in which the adaptive low-pass filter is configured with a bandwidth chosen to correspond to a limit rate of the laser pulses.
    [6]
    6. The imaging pixel of claim
    5, in which the low-frequency component output by the adaptive low-pass filter stores the charge information in the laser pulses.
    [7]
    The image forming pixel of claim 4, further comprising an adaptive high pass filter which receives the component of low frequency signals and suppresses spurious low frequency components from the received component of high frequency signals .
    [8]
    The image forming pixel of claim 7, wherein the suppressed spurious low frequency component corresponds to slowly varying background variations in the low frequency signal component.
    [9]
    The image forming pixel of claim 7, further comprising a gain stage which receives and amplifies the output of the adaptive high pass filter and outputs a signal having a shape suitable for digital reading.
    BE2017 / 5017
    [10]
    10. An image forming device having a focal plane array which includes an array of imaging pixels, the array of imaging pixels
    5 image including:
    a plurality of imaging pixels, the imaging pixels comprising:
    a photodetector outputting charge signals in response to light and incident laser pulses;
    a high frequency path; and a detector bias circuit for biasing high frequency signals of charge signals which are associated with the laser pulses to track
    The high frequency path and which effectively filter low frequency signals from the load signals from the tracking of the high frequency path; and an adaptive low-pass filter that changes the impedance in response to frequency changes
    20 high frequency signals, the adaptive low-pass filter being coupled to the high frequency path which receives the high frequency signals and outputting a component of low frequency signals of the high frequency signals.
    [11]
    11. An image forming device according to claim 10, wherein the high frequency path is independent of the polarization circuit of
    30 detector.
    BE2017 / 5017
    [12]
    The image forming device according to claim 10, the adaptive low pass filter suppressing from high frequency signals components of signals exceeding a frequency threshold.
    Γ-.
    -J
    [13]
    The image forming device according to claim 12, further comprising an adaptive high pass filter which receives the component of low frequency signals and removes components of bass
    10 parasitic frequency from the received high frequency signal component.
    [14]
    The image forming device according to claim 13, further comprising a gain stage
    [15]
    15 which receives and amplifies the output of the adaptive high-pass filter and delivers as output a signal having a shape suitable for digital reading.
    15. Method of detecting laser pulses by a
    20 image forming pixel, the method comprising:
    receiving charge signals which correspond to light and detected incident laser pulses;
    polarizing high frequency signals of the charge signals which are associated with the laser pulses to follow a high frequency path effectively filtering low frequency signals from the charge signals from the tracking of the high frequency path; and
    30 adaptive low pass filtering which changes the impedance in response to frequency changes of high frequency signals, the adaptive low pass filter
    BE2017 / 5017 being coupled to the high frequency path which receives the high frequency signals and outputting a component of low frequency signals of the high frequency signals.
    Γ-1
    -j
    [16]
    16. The method according to claim 15, further comprising:
    the suppression from high frequency signals of signal components exceeding a threshold of
    10 frequency.
    [17]
    17. The method of claim 15, further comprising suppressing spurious low frequency components from the high signal component
    15 frequency,
    [18]
    18. The method of claim 15, further comprising:
    amplifying the high frequency signals after removing the low frequency components outputting the amplified high frequency signals with a shape which is conducive to digital reading.
    BE2017 / 5017
    BE2017 / 5017
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    公开号 | 公开日
    IL249194D0|2017-01-31|
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    US20170208266A1|2017-07-20|
    US9769400B2|2017-09-19|
    引用文献:
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    法律状态:
    2018-10-18| FG| Patent granted|Effective date: 20180821 |
    优先权:
    申请号 | 申请日 | 专利标题
    US14997184|2016-01-15|
    US14/997,184|US9769400B2|2016-01-15|2016-01-15|Pulse detection bandpass filter with gain stage|
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