• 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:
    Image sensor. The object of the invention is an image sensor (100) with "on-chip" compressive sampling for the capture, understanding and transmission of complete images. More specifically, this image sensor (100) comprising a matrix of pixels (5) with rows and columns, to convert the incident light into an electrical signal, a first circuit, to generate a pseudo-random sequence of binary numbers that selects the pixels to be compressed, a second and a third circuit to receive the selection signal (4) of each pixel and generate for each compressed pixel a coding in frequency of pulses of the value of the pixel, and a fourth circuit that receives the coding in frequency of pulses of the pixel value of each compressed pixel, to obtain a compressed digital signal of the complete image. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2684521A1
    申请号:ES201730285
    申请日:2017-03-02
    公开日:2018-10-03
    发明作者:Marco TREVISI;Ricardo Carmona Galán;Ángel Rodríguez Vázquez
    申请人:Consejo Superior de Investigaciones Cientificas CSIC;Universidad de Sevilla;
    IPC主号:
    专利说明:

    PICTURE SENSOR
    DESCRIPTION
    5 OBJECT OF THE INVENTION
    The object of the invention is an image sensor with compressive sampling "on-chip" for the capture and transmission of compressed complete images.
    10 BACKGROUND OF THE INVENTION
    The image sensors comprise a matrix of pixels, with rows and columns, where each pixel in turn comprises a photosensitive element, such as a reverse polarized photodiode, to convert the incident light into an electrical signal. The level of illumination that each pixel receives is determined by integrating the electric current produced by the photosensitive element, since the number of electrons generated during integration is proportional to the amount of incident light.
    Currently, image sensors are mainly divided into two groups, 20 CMOS (Complementary Metal Oxide Semiconductor) sensors and CCD (Charge Coupled Device) sensors. Generally, these differ from each other because the CMOS sensor comprises an amplifier of the electrical signal for each photosensitive element, while the CCD sensor sends the electrical signal produced by each photosensitive element outside the pixel to be amplified.
    25
    Both types of image sensors digitize the electrical signal generated by the photosensitive elements and transmit it to memories, usually off-chip, ie memories that are not part of the image sensor. These memories are where images are stored in the form of digital data. Usually, to reduce the amount of data stored, these digital data are compressed, generating a compressed image of smaller size and stored in said memory.
    These compressed images require less bandwidth when transmitted at the expense of a computational effort for reconstruction. Because
    This lower bandwidth, currently different compression methods are applied in photography, tomography, magnetic resonance and radio astronomy, in order to obtain the maximum information in the compressed images and therefore of smaller size.
    5 The most common methods used to compress these digitized electrical signals and obtain the compressed images have a number of drawbacks. Among these disadvantages is a high time to acquire the complete digitized image because a large number of samples of the digitized image is necessary, a high electrical consumption of the analog / digital converters 10 that digitize the image and a high complexity of the own compression method that you may need from a completely dedicated processor to implement such compression.
    Currently, in order to reduce these inconveniences, it has begun to be implemented in 15 image sensors with compressive sampling techniques, obtaining the first image sensors with compressive sampling. The main feature of compression sampling techniques is contained in the following equation:
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    y = 00a (1)
    where "and" are the compressed electrical signal samples, "0" is the compression strategy, "0" is the scattering dictionary, and "a" are the coefficients of the original electrical signal.
    25 The fundamental requirement for successful compressive sampling is that the signal to be sufficiently dispersed ("sparse"). A scattered signal is one that has a small number of nonzero components compared to its total length. This property can occur either in the original domain or with respect to another base. For example, it is possible to express an image, in the Fourier domain, or in the form of 30 wavelets. The compression strategy 0 is the method by which linear combinations of the coefficients of the signal expressed in a domain in which it is especially dispersed are formed. The scattering dictionary 0 is a matrix that multiplied by an original signal returns a vector containing the transformation coefficients of the original signal of that domain.
    An application of compressive sampling in image sensors is the implementation of a compression strategy 0 within the sensor itself, so that each of the samples obtained is the linear combination of a group of pixels of the original image 5. To incorporate this compression strategy into the image sensor, there are currently two methodologies: selecting the elements of 0 from a random distribution, or randomly rearranging the rows of a matrix that constitutes an incoherent orthonormal basis. Each of these methods results in a different physical implementation. To date, the use of an incoherent orthonormal base is behind 10 interventions in the optical elements of the sensor, while the use of random distributions has been used to design specific optical or electronic elements for the implementation of the compression strategy.
    An example of an image sensor with compressive sampling performed by optical elements is the single pixel camera described in "An Architecture for Compressive Imaging" by MB Wakin, et al., Where a first attempt at implementing a strategy is described of compressive sampling.More specifically, the light is projected on a matrix of micro-mirrors whose position is controlled by a pseudo-random pattern.The selected mirrors project the light intensity on a photosensor that integrates all contributions resulting in a compressed sample consisting of the linear combination of the incident light intensities in all the micro-mirrors selected by the pattern.
    However, the image sensor with compressive sampling by optical elements has a very high cost of production because they require micro-electromechanical devices, such as micro-mirrors that are very expensive to manufacture. Another disadvantage is that these parts are mobile, which requires high-precision actuators that consume electricity and occupy an important space in the sensor. Additionally, since there are moving parts, they require preventive maintenance of these to ensure the correcting operation.
    Because of this, image sensors have been developed with compressive sampling performed by electronic elements. The first of these image sensors was described by V. Majidzadeh et al in "A (256x256) Pixel 76.7mW CMOS
    Imager / Compressor Based on Real-Time In-Pixel Compressive Sensing ”. This image sensor comprises a pixel in current mode and in-pixel selection elements, and by means of a programmable two-dimensional coding technique guarantees the randomness of the coefficients used in the successive samples. These random patterns are generated using an external source and distributed to each pixel through the use of shift registers. The currents generated by all the pixels that contribute to the sample are added with a transimpedance amplifier. The sample is then digitized using an 11-bit converter. This results in a loss of information due to the low resolution of the quantization performed during image processing.
    Another example of an image sensor with compressive sampling by electronic means is described by Y. Oike et al. in "CMOS Image Sensor With Per-Column IA ADC and Programmable Compressed Sensing (DOI: 10.1109 / JSSC.2012.2214851)” where 15 uses an AI modulator per column. The selection of pixel blocks and columns is done using a generator external patterns The compression strategy is performed on blocks of 16 ^ 16 pixels.To make the sum of the contributions within each block, averaging is performed, resulting in a loss of resolution and a poorer subsequent reconstruction of the image. 20 tablets
    Another image sensor with compressive sampling that operates on sub-images is also known, as described in "A Low Power CMOS Imager Based on Distributed Compressed Sensing (DOI: 10.1109 / VLSID.2014.99)" by B. Kaliannan, et al. 25 This image sensor operates in blocks of 8x8 pixels. More specifically, block sampling is performed according to a pseudo-random binary sequence that is stored on a chip. The linear combination is performed by averaging the selected pixels In order to reduce the dynamic range required for the sum of contributions, the pixels are selected by means of a Rademacher matrix, 30 so that there are positive and negative contributions.The latter are obtained by changing the polarity of the capacitors used to Perform averaging by redistributing cargo.
    It should be noted that the optimal solution to the problem of rebuilding a
    Image from the compressed samples is obtained when each of these samples has been obtained by linear combination of all image pixels multiplied each by a random weight. Currently, the strategies implemented are a simplification of this procedure that leads to a sub-optimal reconstruction. Such reconstruction is usually carried out by means of reconstruction methods such as the Nesterov algorithm which is an image reconstruction method based on the acceleration of the descending gradient method or rapid descent algorithm.
    10 Additionally, these image sensors with compression sampling are also limited in practice by the need to share the compression strategy between the image sensor and the image reconstruction mechanisms. For this, it is necessary to generate said strategy in the sensor and retransmit it to the reconstruction mechanisms, or have it stored in advance. In both cases, the 15 practical limitations of the implementation lead to the application of compression strategies to small pixel blocks, resulting in a sub-optimal reconstruction
    Another recurring problem in the application of compression sampling strategies to a pixel array is the dynamic range of compressive samples. Formally the dynamic range of the compressive samples needed will be as many times greater than the dynamic range of an original sample as pixels contain the image. That is, since a compressive sample is obtained from the linear combination of pixel values, it is quite common for the value of a compressive sample to be larger than the value of a single pixel, but it cannot be ruled out that The compressive sample is very small, so the dynamic range we need to express a compressed (compressed) sample is much larger than what we need to express a single pixel.
    30 In practice this means that in order to represent the compressed samples corresponding to the whole image we would need too many resources. Because of this, currently working with blocks of the image, whose compressed samples cover a more affordable dynamic range.
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    DESCRIPTION OF THE INVENTION
    The present invention describes an image sensor with compressive sampling comprising a matrix of pixels with rows and columns, wherein each pixel in turn comprises a photosensitive element for converting the incident light into an electrical signal. More specifically, the image sensor comprises:
    - a column bus for each column of the pixel matrix, where each column bus is linked to all the pixels of its corresponding column, and where each column bus in turn comprises two pulse transmission lines, one for positive pulses and another for negative pulses,
    - a first circuit, to generate a pseudo-random sequence of binary numbers, comprising respectively a vertical element and a horizontal element, for each row and column of the pixel matrix; wherein the vertical and horizontal elements are connected to each other in a ring, each vertical element is linked to all the pixels of its corresponding row, each horizontal element is linked to all the pixels of its corresponding column; and each vertical and horizontal element generates a pixel selection signal, which selects the pixels that contribute to compression,
    - a second circuit that receives the pixel selection signal to establish by which pulse transmission line, positive or negative, the contribution of each pixel is transmitted,
    - a third circuit to generate in each pixel a pulse frequency coding of the pixel value and transmit it to the transmission line selected by the second circuit of its corresponding column bus, and
    - a fourth circuit linked to at least the third circuit, through a column bus, for each column of the pixel matrix to receive the pulse frequency coding of the pixel value of each compressed pixel, to obtain a digital signal Compressed full image.
    Said first circuit is a digital circuit that implements a class III cellular automaton to generate, from an initial seed, the pseudo-random sequence of binary numbers.
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    In this way, the rows and columns of the pixel matrix are selected in a pseudo-random manner, without the need to store anything beyond the initial seed, and without the need to retransmit the pseudo-random sequence. This is because this pseudo-random sequence is reproduced in a decompression device using a similar digital circuit that will start from the same seed.
    In the present description, a mathematical model of a dynamic system that evolves and generates complex pseudo-random patterns from a logical rule is considered as a cellular automaton. This cellular automaton comprises cells that are implemented by digital electronics and linked to each other. Throughout the description we also refer to the cellular automaton as the first circuit or digital circuit that implements it, as well as to the cells or as the digital electronics that implements them.
    Each element of the first circuit is a digital element, as a cell of the cellular automaton, comprising three inputs: L, C, R and a current state output S, wherein said current state output S is fed back through the input C and is transmitted to the two anterior and posterior neighboring cells through their R and L inputs respectively so that the class III cellular automaton follows rule 30.
    When presenting a ring connection topology, preferably the anterior neighboring cell of the first cell of the column is the last cell of the row and the posterior neighboring cell of the last cell of the row is the last cell of the column.
    More specifically, each digital element, or cell, comprises:
    - an OR gate that receives inputs C and L,
    - a first XOR gate that receives the output of the OR gate and the R input, and whose output is equal to the next NS state of the cell, and
    - a type D flip-flop that receives the output of the XOR gate and a CLK clock input; and whose output, which is the pixel selection signal, will not be equal to the next NS state until the next flank of the CLK clock.
    Thus, the logical rule, specifically rule 30, relates the next state of each cell to its current state and the current states of its cells.
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    Nearest neighbors for each clock cycle, resulting in a truth table easily obtainable from the initial seed, and therefore it is possible to decompress the compressed image through reconstruction mechanisms that reverse the applied logic rule.
    Preferably, the clock is an electrical signal external to the array of pixels that in each clock cycle allows the image sensor to generate a new compressed sample. Specifically an FPGA ("Field Programmable Gate Array") previously programmed to generate this signal, or an IC 555 timer.
    Preferably, each photosensitive element is a photodiode and the third circuit for each photodiode comprises:
    - a first transistor,
    - a second transistor,
    - a node linked to the photodiode to receive the photogenerated current in the photodiode,
    - an operational amplifier comprising a positive input and a negative input, the negative input being linked to said node, with the positive input linked to a reference voltage and the output linked to the first and second transistors,
    - a reset transistor linked to the node and activated by the output of the operational amplifier, and
    - wherein said output of the operational amplifier is a pulse train whose frequency is proportional to the light intensity incident on the photodiode.
    Also the second circuit for each photodiode comprises: a second XOR gate, an inverter, a third transistor and a fourth transistor, so that:
    - the two inputs of the second XOR gate are linked to the selection signals generated in the vertical cell and the horizontal cell corresponding to this pixel, and its output is linked to the inverter's input and the third transistor gate,
    - the output of the inverter is linked to the door of the fourth transistor,
    - the output of the operational amplifier is linked to the gate of the first and second transistor, the drain of the third transistor is linked to the positive line of the column bus and its source with the drain of the first transistor which in turn has its source connected grounded, and
    5 - the drain of the fourth transistor is linked to the negative line of the bus
    column and its source with the drain of the second transistor which in turn has its source grounded, and
    - when the pulse train is generated, the second XOR gate combines the selection signals by column and by row at pixel level, to account for the
    10 contribution of this pixel as positive, activating the third transistor, or as
    negative by activating the fourth transistor, and transmitting them through the column bus to form the pulse frequency coding of the pixel value
    On the other hand that the fourth circuit comprises:
    - a battery of meters for each column linked to its corresponding column bus to accumulate the contributions that the column bus carries during an integration period, that is, the exposure period of the pixel matrix to the light determined by the lighting conditions of the scene, and
    - a cascade of adders linked to the counter batteries to add the contributions of each column and compress the image captured by the sensor.
    25 In this way an image sensor is obtained that compresses an entire image without breaking down the image into blocks and maintaining the dynamic range of the image. Additionally, this image sensor allows to implement a compression strategy for the complete image without needing to retransmit or store said strategy.
    30
    DESCRIPTION OF THE DRAWINGS
    To complement the description being made and in order to help a better understanding of the features of the invention, according to an example
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    a practical set of drawings is accompanied as an integral part of said description, a set of drawings in which, for illustrative and non-limiting purposes, the following has been represented:
    5 Figure 1.- Shows a diagram of the sensor architecture.
    Figure 2.- Shows a view of the architecture of the cellular automaton in which the connection of each cell of the cellular automaton is shown.
    10 Figure 3.- Shows a graphic representation of the application of rule 30 on the cells of the cellular automaton.
    Figure 4.- Shows a schematic diagram of a preferred implementation of each of the cells of the cellular automaton.
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    Figure 5.- Shows a schematic diagram of one of the pixels of the pixel matrix.
    PREFERRED EMBODIMENT OF THE INVENTION
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    A preferred embodiment of the invention, as shown in Figure 1, is an image sensor (100) with compressive sampling generated "on-chip", where compression is performed on the entire image and an adaptation is made of the dynamic range for precise coding of compressed samples.
    25
    More specifically, the image sensor (100) comprises an array of pixels (5) with rows and columns, a cellular automaton (1) linked to said pixel array (5), a column bus (10) for each column of the array of pixels (5), a battery of counters (21) linked to each column bus (10) and a cascade of 30 adders (22) linked to the counter batteries (21).
    This cellular automaton (1) follows rule 30 so it has a class III behavior and comprises a plurality of cells (3). Specifically, a vertical cell (3v) for each column and a horizontal cell (3h) for each row of the pixel matrix
    (5), so that each vertical cell (3v) is linked to each pixel in its column and each horizontal cell (3h) is linked to each pixel in the row to generate selection signals (4). These cells have a ring structure that implements aperiodic behavior to generate a pseudo-random sequence of 5 binary numbers with as many digits as the sum of the rows and columns of the pixel matrix (5). Thus, from the pseudo-random sequence, the selection signals (4) select the pixels of the rows and columns to compress their information.
    10 That is, each vertical and horizontal cell (3v, 3h) generates a selection signal (4) comprising a selection bit to select, or not, the pixel and thus compress the entire image.
    Additionally, the output of each of the pixels of one of the columns is connected to one of the column buses (10). Each column bus (10) comprises two pulse transmission lines, one for positive pulses and one for negative pulses. The pulses of each column bus (10) are accumulated, during an integration period, by the meter battery (21) to which it is linked. At the end of the integration period, the cascade of adders (22), will add the accounts 20 made in each column to form the compressed sample.
    Note that the integration period is the time window during which the cascade of adders (22) counts the pulses. That is, at that time all the pulses are counted, that is, the positive or negative contributions of the pixels, and the result is the sum of all the pulses that have been received in the cascade of adders (22) forming the compressed sample .
    More specifically, the ring connections of each cell (3) of the cellular automaton (1) are shown in Figure 2. Each cell (3) is implemented by a digital element 30 comprising three inputs: L, C, R and a current status output S, wherein said current status output S is fed back through input C and transmitted to the two neighboring cells anterior (3a) and posterior (3p) through its inputs R and L respectively. These inputs L, C R are used to generate the next state of the current state output S following a truth table (8) as it is
    shown in figure 3.
    More specifically, Figure 3 shows the graphic representation of the application of rule 30 on the cells (3) of the cellular automaton (1) and the current state 5 of each cell (3) and its neighboring cells (3) immediately before and after. Where, for each cell (3) input C represents its current state of input L represents the current value of its previous cell (3) and input R represents the current value of its subsequent cell (3). These inputs L, C and R respectively, are represented by the first squares (7), and from 10 them and following the truth table (8), taking into account that a black box is equivalent to a logical "1" and a blank box at a "0", the next states, NS, of each cell (3), represented by the second squares (6) are obtained.
    On the other hand, in figure 2 you can see a graphic representation of a possible initial seed (2) that would start the cellular automaton (1) to generate a pseudo-random that if it starts with the bit values of said initial seed (2 ).
    Preferably, as shown in Figure 4, each of the cells (3) of the cellular automaton (1) comprises an OR gate (23), a first XOR gate (24) and 20 a type D flip-flop ( 25). In this way the truth table (8) can be made by said OR gate (23) linked to the XOR gate (24) with which the entries corresponding to the anterior and posterior neighbors, L and R, and the feedback itself are combined from state S through C. In order to separate the next state, NS, from the current state S, flip-flop type D (25) is used so that the next 25 state NS will not become the current one until the next flank of the CLK clock.
    On the other hand each, Figure 5 shows the schematic diagram of one of the pixels of the matrix (5). Thus, each pixel comprises a photodiode (19) whose photogenerated current is discharged into a node (18).
    30
    Additionally, as shown in Figure 5, the image sensor (100) comprises an operational amplifier (13) and a reset transistor (20), for each pixel, wherein the operational amplifier (13) comprises a positive input and a negative input, the negative input being linked with said node (18) and with the
    positive input linked to a reference voltage (Vref). Thus, when the voltage at this node (18) becomes below the reference voltage (Vref), the operational amplifier (13) that acts as a comparator will set its output high. This will cause the reset transistor (20) to run, resetting the voltage at the node (18) to the reset value. As a result, the operational amplifier (13) will again offer a low voltage value at the output. This cycle will be repeated as long as the photodiode (19) is illuminated, thus generating a pulse train whose frequency will be proportional to the light intensity incident on the photodiode (19).
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    Additionally, image sensor (100) comprises a second XOR gate (9), an inverter (16), a first transistor (11), a second transistor (12), a third transistor (14) and a fourth transistor (15) , so that:
    15 - the two inputs of the second XOR gate (9) are linked to the signals of
    selection (4) generated by the vertical cell (3) and by the horizontal cell (3) corresponding to this pixel, and its output is linked to the input of the inverter (16) and the door of the third transistor (14),
    - the output of the inverter (16) is linked to the door of the fourth transistor (15),
    20 - the output of the operational amplifier (13) is linked to the door of the first and
    of the second transistor (11, 12), the drain of the third transistor (14) is linked to the positive line of the column bus (10) and its source with the drain of the first transistor (11) which in turn has its source connected grounded, and
    - the drain of the fourth transistor (15) is linked to the negative line of the bus of
    25 column (10) and its source with the drain of the second transistor (12) which in turn
    Your source is grounded.
    Thus, while the pulse train is generated, the second XOR gate (9) combines the selection signals (4) per column and per row at pixel level, so that it decides if the pixel contribution is to be counted as positive, activating the third transistor (14) or negative, activating the fourth transistor (15), so that the pulses generated by the operational amplifier (13) are reproduced by the first and second transistors (11, 12) and transmitted as positive or negative contributions through their respective positive or negative column bus lines (10). The
    Highly generated active pulses are transmitted as low active pulses by the structure of the lines, which have pull-up resistors (17) so that the voltage is high if none of the pixels in the column are emitting a pulse .
    5
    权利要求:
    Claims (8)
    [1]
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    1. - Image sensor (100) with compressive sampling comprising a matrix of pixels (5) with rows and columns, where each pixel in turn comprises a photosensitive element to convert the incident light into an electrical signal, characterized in that The image sensor (100) comprises:
    - a column bus (10) for each column of the pixel matrix (5), where each column bus (10) is linked to all the pixels of its corresponding column, and where each column bus (10) in turn it comprises two lines of pulse transmission, one for positive pulses and one for negative pulses,
    - a first circuit, to generate a pseudo-random sequence of binary numbers, comprising respectively a vertical element and a horizontal element for each row and column of the array of pixels (5) connected to each other in a ring; wherein each vertical element is linked to each of the pixels of its corresponding row, and each horizontal element is linked to each of the pixels of its corresponding column; so that each vertical and horizontal element generates a pixel selection signal (4) that selects the pixels that contribute to compression,
    - a second circuit that receives the pixel selection signal (4) to establish by which pulse transmission line, positive or negative, the contribution of each pixel is transmitted,
    - a third circuit to generate in each pixel a pulse frequency coding of the pixel value and transmit it to the transmission line selected by the second circuit of its corresponding column bus, and
    - a fourth circuit linked to at least the third circuit, through a column bus (10), for each column of the pixel matrix (5) to receive the pulse frequency coding of the pixel value of each compressed pixel , to obtain a compressed digital signal of the entire image.
    [2]
    2. - Image sensor (100) according to claim 1, characterized in that the first circuit is a digital circuit that implements a class III cellular automaton (1) to generate, from an initial seed (2), the sequence pseudo-random binary numbers.
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    [3]
    3. - Image sensor (100) according to claim 2, characterized in that each
    First circuit element is a digital element, as a cell (3) of the cellular automaton (1), comprising three inputs: L, C, R and a current status output S, wherein said current status output S is feedback through input C and is transmitted to the two neighboring cells anterior (3a) and posterior (3p) through their
    R and L inputs respectively for the class III cellular automaton (1) to follow
    rule 30
    [4]
    4. - Image sensor (100) according to claim 3, characterized in that each digital element comprises:
    - an OR gate (23) that receives inputs C and L,
    - a first XOR gate (24) that receives the output of the OR gate (23) and the
    R input, and whose output is equal to the next NS state of the cell (3) and
    - a type D flip-flop (25) that receives the output of the XOR gate (24) and a CLK clock input; and whose output, which is the pixel selection signal (4), will not be equal to the next NS state until the next flank of the CLK clock.
    [5]
    5. - Image sensor (100) according to claim 1, characterized in that each photosensitive element is a photodiode (19).
    [6]
    6. - Image sensor (100) according to claim 5, characterized in that the third circuit for each photodiode (19) comprises:
    - a first transistor (11),
    - a second transistor (12),
    - a node (18) linked to the photodiode (19) to receive the photogenerated current in the photodiode (19),
    - an operational amplifier (13) comprising a positive input and a negative input, the negative input being linked to said node (18), the positive input linked to a reference voltage (Vref) and the output linked to the first and the second transistor (11, 12), and
    - a reset transistor (20) linked to the node (18) and activated by the output of the operational amplifier (13),
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    - wherein said output of the operational amplifier (13) is a pulse train whose frequency is proportional to the light intensity incident on the photodiode (19).
    [7]
    7. - Image sensor (100) according to claim 6, characterized in that the second circuit for each photodiode (19) comprises: a second XOR gate (9), an inverter (16), a third transistor (14) and a fourth transistor (15), so that:
    - the two second-door XOR inputs (9) are linked to the selection signals (4) generated in the vertical cell (3v) and by the horizontal cell (3h) corresponding to this pixel, and its output is linked to the input of the inverter (16) and with the door of the third transistor (14),
    - the output of the inverter (16) is linked to the door of the fourth transistor (15),
    - the output of the operational amplifier (13) is linked to the door of the first and second transistor (11, 12), the drain of the third transistor (14) is linked to the positive line of the column bus (10) and its source with the drain of the first transistor (11) which in turn has its source grounded, and
    - the drain of the fourth transistor (15) is linked to the negative line of the column bus (10) and its source with the drain of the second transistor (12) which in turn has its source grounded, and
    - when the pulse train is generated, the second XOR gate (9) combines the selection signals (4) per column and per row at the pixel level, to account for the contribution of this pixel as positive, activating the third transistor (14 ), or as negative by activating the fourth transistor (15), and transmitting them through the column bus (10) to form the pulse frequency coding of the pixel value.
    [8]
    8. - Image sensor (100) according to claim 7, characterized in that the fourth circuit comprises:
    - a battery of counters (21) for each column linked to its corresponding column bus (10) to accumulate the contributions that the column bus (10) carries during an integration period or exposure period determined by the lighting conditions of the scene, and
    - a cascade of adders (22) linked to the counter batteries to sum the contributions of each column and compress the image captured by the sensor.
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    同族专利:
    公开号 | 公开日
    WO2018158482A1|2018-09-07|
    ES2684521B1|2019-07-12|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    FR3010602B1|2013-09-10|2015-10-02|Commissariat Energie Atomique|DEVICE AND METHOD FOR COMPRESSIVE ACQUISITION OF IMAGES|
    FR3010603A1|2013-09-10|2015-03-13|Commissariat Energie Atomique|COMPRESSIVE ACQUISITION DEVICE OF AN IMAGE|
    法律状态:
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    优先权:
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    ES201730285A|ES2684521B1|2017-03-02|2017-03-02|PICTURE SENSOR|ES201730285A| ES2684521B1|2017-03-02|2017-03-02|PICTURE SENSOR|
    PCT/ES2018/070149| WO2018158482A1|2017-03-02|2018-02-28|Image sensor|
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