Patent Publication Number: US-2023137218-A1

Title: Pixel circuit, control method, and image sensor

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
     The present application is based on and claims the priority of Chinese patent application No. 202111301604.6, filed on Nov. 4, 2021. The entire disclosure of the above-identified application is incorporated herein by reference. 
     TECHNICAL FIELD 
     The present application relates to the technical field of semiconductor devices, and particularly to a pixel circuit, a control method and an image sensor. 
     BACKGROUND 
     With the development of the technology of the image sensor, the application field of the image sensor is more and more extensive, for example, the image sensor can be applied to the fields of medical radiation imaging, industrial flaw detection, security inspection and the like. 
     Current image sensors are not adjustable in the density of phase focus, and therefore, the density of phase focus cannot be switched according to a specific scene. 
     For the above problems, a person skilled in the art has been seeking solutions. 
     The foregoing description is to provide general background information and does not necessarily constitute prior art. 
     SUMMARY 
     The technical problem to be solved by the present application is to provide a pixel circuit, a control method and an image sensor for the defects in the prior art, so as to ensure optical performance while achieving switching of the density of phase focus. 
     This application is realized as follows: 
     The present application provides a pixel circuit, including: at least two pixel units, the at least two pixel units are arranged in an array. 
     Each pixel unit includes at least two pixels. Wherein each of the pixels comprises a photoelectric conversion element and a transmission transistor, and the photoelectric conversion element is used for generating an electric charge in response to incident light; the transmission transistor is coupled between the photoelectric conversion element and a floating diffusion node, and is configured to transfer the electric charge accumulated by the photoelectric conversion element in an exposure process to the floating diffusion node according to a transmission control signal. Wherein, the transmission transistors of two pixels of at least one of the pixel units are connected to a corresponding first group of transmission control lines, and the first group of transmission control lines includes at least one transmission control line, and one of the pixels corresponds to one of the transmission control lines; and the transmission transistor of other pixel unit are connected to a corresponding second group of transmission control lines. 
     Optionally, at least two of the pixels in a same pixel unit share a micro lens, and two of the pixels sharing the same micro lens are connected to the corresponding first group of transmission control lines. 
     Optionally, all of the pixels in the same pixel unit share one of the micro lenses. 
     Optionally, among the pixels of the pixel units connected to the corresponding first group of transmission control lines, the remaining pixels except for the pixels connected to the first group of transmission control lines are connected to the second group of transmission control lines. 
     Optionally, the number of transmission control lines of the first group of transmission control lines is less than or equal to the number of pixels of corresponding ones of the pixel units. 
     Optionally, each row of the pixel units is provided with the corresponding first group of transmission control lines and the corresponding second group of transmission control lines. 
     Optionally, when a density of phase focus is 100%, a timing of a transmission control signal received by the first group of transmission control lines is the same as a timing of the transmission control signal received by the second group of transmission control lines; and when the density of phase focus is not 100%, the timing of the transmission control signal received by the first group of transmission control lines is different from the timing of the transmission control signal received by the second group of transmission control lines. 
     Optionally, each pixel unit includes four pixels, and the first group of transmission control lines corresponding to each row of pixel units includes two transmission control lines; wherein, the transmission transistors of the two pixels in the pixel unit connected to the first group of transmission control lines are respectively connected to the corresponding two transmission control lines in the first group of transmission control lines. 
     Optionally, when the phase focus density is not 100%, a time when the first sub-transmission control line of the first group of transmission control lines receives an effective-level transmission control signal and the time when the second sub transmission control line of the first group of transmission control lines receives the effective-level transmission control signal are offset from each other to obtain left-right phase information and/or up-down phase information, and four transmission control lines of the second group of transmission control lines receive the effective-level transmission control signal to obtain an image information; wherein, the first sub-transmission control line includes a transmission control line correspondingly connected to a first pixel of the four pixels, and the second sub-transmission control line includes a transmission control line correspondingly connected to a pixel adjacent up and down or left and right to the first pixel of the four pixels. 
     Optionally, in the same row of pixel units, two of the pixel units connected to the first group of transmission control lines are separated by at least one pixel unit. 
     Optionally, the pixel units of a nth row of the pixel circuit are arranged in cycles corresponding to a first green color filter and a blue color filter, and the pixel units of a (n+1)th row are arranged in cycles corresponding to a red filter and a second green color filter; or, each pixel unit group comprises four pixel units arranged in an array, and the four pixel units of each pixel unit group respectively correspond to the first green color filter, the blue color filter, the second green color filter and the red color filter in a clockwise direction; wherein, the pixel unit connected to the first group of transmission control lines is correspondingly arranged at a position corresponding to the first green color filter or the second green color filter. 
     Optionally, in the same row of pixel units, two pixel units connected to the first group of transmission control lines are separated by at least one pixel unit; and/or, in the same column of pixel units, two pixel units connected to the first group of transmission control lines are separated by at least one pixel unit. 
     Optionally, the pixel circuit further includes: 
     a reset transistor, which is coupled between a first voltage source and the floating diffusion node; and/or, 
     an amplification output unit, which is coupled to the floating diffusion node and is configured to output a voltage signal of the floating diffusion node; and/or, 
     a dual-conversion gain control unit, which is coupled between the reset transistor and the floating diffusion node and is configured to implement gain control; and/or, 
     a row selection transistor, which is coupled between an output terminal of the amplification output unit and a column output line, and a gate of the row select transistor receives a row selection control signal for outputting the voltage signal of the floating diffusion node. 
     Optionally, each pixel unit includes four pixels, and the four pixels in the same pixel unit share a micro lens, and the first group of transmission control lines includes four two transmission control lines; 
     wherein, among the pixel units connected to the first group of transmission control lines, two of the pixels are connected to two said transmission control lines of the first group of transmission control lines. 
     The present application also provides an image sensor including the pixel circuit described above. 
     The present application also provides a control method of the above-mentioned pixel circuit, and the control method includes: acquiring an image information based on the first group of transmission control lines and the second group of transmission control lines; or acquiring a phase focus information based on the first group of transmission control lines and the second group of transmission control lines; or acquiring the phase focus information based on the first group of transmission control lines, and acquiring the image information based on the second group of transmission control lines. 
     Optionally, the control method comprises a single-row reading mode or a parallel reading mode, wherein: acquiring the phase focus information based on different pixels of a same pixel unit connected to the first group of transmission control lines in a reading process, so as to realize phase focus; or acquiring the phase focus information based on the pixel units of different pixel unit rows connected to the first group of transmission control lines in the reading process, so as to realize phase focus. 
     Optionally, the manner of acquiring the phase focus information based on different pixel unit rows includes: a pixel array has a first focus pixel row comprises at least one first pixel unit connected to the first group of transmission control lines, and a second focus pixel row comprises at least one second pixel unit connected to the first group of transmission control lines, wherein acquiring a first focus information based on the first focus pixel row, and acquiring a second focus information based on the second focusing pixel row, so as to obtain the phase focus information. 
     Optionally, acquiring phase information based on the pixels connected to the second group of transmission control lines in the corresponding pixel unit when the pixel unit connected to the first group of transmission control lines is also connected to the second group of transmission control lines and the first group of transmission control lines receives an invalid level signal. 
     The present application provides a pixel circuit, a control method, and an image sensor, wherein transmission transistors of two pixels of at least one pixel unit are connected to a corresponding first group of transmission control lines, and transmission transistors of other pixel are connected to a corresponding second group of transmission control lines. Therefore, the pixel circuit, the control method and the image sensor provided in the present application can control the density of phase focus of the image sensor by controlling the timing of the first group of transmission control lines and the second group of transmission control lines without changing the structure of the pixel, the structure is simple, and the optical performance is good. 
     To make the above and other objects, features, and advantages of the present disclosure more comprehensible, the following detailed description is set forth in detail below with reference to the accompanying drawings. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG.  1    is a structural diagram of a pixel circuit provided by an embodiment of this application; 
         FIG.  2    is a structural diagram of a pixel unit in a pixel circuit provided by an embodiment of this application; 
         FIG.  3    is a circuit diagram of a pixel unit in a pixel circuit provided by an embodiment of this application; 
         FIG.  4   a    is an effect diagram of the phase focus mode when an image sensor according to an embodiment of this application realizes that a density of left-right phase information is 100%; 
         FIG.  4   b    is a timing diagram when an image sensor according to a first embodiment of this application realizes that a density of left-right phase information is 100%; 
         FIG.  5   a    is an effect diagram of the phase focus mode when an image sensor according to an embodiment of this application realizes that a density of up-down phase information is 100%; 
         FIG.  5   b    is a timing diagram when an image sensor according to a first embodiment of this application realizes that a density of up-down phase information is 6%; 
         FIG.  6    is an effect diagram of the phase focus mode when an image sensor according to an embodiment of this application realizes that a density of up-down and left-right phase information is 100% 
         FIG.  7   a    is a corresponding pixel layout design when an image sensor according to an embodiment of this application realizes that a density of left-right phase information is 3%; 
         FIG.  7   b    is a timing diagram when an image sensor according to a first embodiment of this application realizes that a density of left-right phase information is 3%; 
         FIG.  8   a    and  FIG.  8   b    are two timing diagrams when an image sensor according to a first embodiment of this application realizes that a density of left-right phase information is 6%; 
         FIG.  9   a    is a timing diagram when an image sensor according to a second embodiment of this application realizes that a density of left-right phase information is 3%; 
         FIG.  9   b    is a corresponding pixel layout design when an image sensor according to a second embodiment of this application realizes that a density of left-right phase information is 3%; 
         FIG.  10    is an image sensor according to an embodiment of this application. 
     
    
    
     DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
     Exemplary embodiments of the present application are described in detail with reference to the accompanying drawings, but the present application is not limited to the following embodiments. 
     The terms “first”, “second”, “third”, “fourth”, etc. in the description and claims of the present application are all used for distinguishing similar objects rather than describing a particular sequence or order. 
     The present application provides a pixel circuit, the pixel circuit includes at least two pixel units arranged in an array, and each pixel unit includes: 
     at least two pixels, each of the pixels includes a photoelectric conversion element and a transmission transistor, and the photoelectric conversion element is used for generating an electric charge in response to incident light, and the photoelectric conversion element includes but is not limited to a photodiode PD; the transmission transistor is coupled between the photoelectric conversion element and a floating diffusion node, and is configured to transfer the electric charge accumulated by the photoelectric conversion element in an exposure process to the floating diffusion node according to a transmission control signal; 
     a reset transistor, coupled between a first voltage source and the floating diffusion node, and configured to reset a voltage of the floating diffusion node according to a reset control signal; 
     an amplification output unit, coupled to the floating diffusion node, and configured to output a voltage signal of the floating diffusion node; 
     wherein, the transmission transistors of two pixels of at least one of the pixel units are connected to a corresponding first group of transmission control lines, and the transmission transistors of other pixels are connected to a corresponding second group of transmission control lines, and the first group of transmission control lines is different from the second group of transmission control lines. 
     According to an embodiment of the present application, the amplification output unit includes a source follower transistor, a gate of the source follower transistor is coupled to the floating diffusion node, a drain thereof is coupled to a second voltage source, and a source thereof is coupled to the row selection transistor as an output terminal. 
     Wherein, the first voltage source and the second voltage source may be the same voltage source, so that the reset transistor and the source follower transistor are simultaneously connected to the same voltage source, of course, the first voltage source and the second voltage source may also be a different voltage sources, and the reset transistor and the source follower transistor are respectively connected. 
     In an embodiment, the pixel circuit further includes a dual-conversion gain control unit, which is coupled between the reset transistor and the floating diffusion node, and is configured to implement gain control. 
     As a specific embodiment, the dual-conversion gain control unit comprises a dual-conversion gain control transistor and a dual-conversion gain capacitor, the dual-conversion gain control transistor is coupled between the reset transistor and the floating diffusion node, the first terminal of the dual-conversion gain capacitor is coupled between the double-conversion gain transistor and the reset transistor, and the second terminal of the dual-conversion gain capacitor is connected to the specified level or the ground. 
     In an embodiment, the pixel circuit further includes a row selection transistor coupled between an output terminal of the amplifying output unit and a column output line, and a gate of the row selection transistor receives a row selection control signal for outputting the voltage signal of the floating diffusion node. 
     In an embodiment, at least two pixels in the same pixel unit share a micro lens. Further, two said pixels sharing the same micro lens are correspondingly connected to the first group of control lines. In an embodiment, in the same row of pixel units, two pixel units connected to the first group of transmission control lines are separated by at least one pixel unit; and/or, in the same column of pixel units, two pixel units connected to the first group of transmission control lines are separated by at least one pixel unit. 
     In an embodiment, when a density of phase focus is 100%, a timing of a transmission control signal received by the first group of transmission control lines is the same as a timing of the transmission control signal received by the second group of transmission control lines; and when the density of phase focus is not 100%, the timing of the transmission control signal received by the first group of transmission control lines is different from the timing of the transmission control signal received by the second group of transmission control lines. 
     In an embodiment, each pixel unit includes four pixels, and the four pixels in the same pixel unit share one micro lens, and the first group of transmission control lines corresponding to each row of pixel units includes two transmission control lines; wherein the transmission transistors of two pixels in the at least one pixel unit are respectively connected to two transmission control lines in the corresponding first group of transmission control lines. 
     The pixel circuit provided by the present application includes at least two pixel units, and all pixels in each pixel unit share a reset transistor, an amplification output unit, and a row selection transistor, thereby saving chip area and facilitating device miniaturization. And the transmission transistors of two pixels of at least one pixel unit are connected to a corresponding first group of transmission control lines, and the transmission transistors of other pixel are connected to a corresponding second group of transmission control lines, so that the density of phase focus of the image sensor can be controlled by controlling the timing of the first group of transmission control lines and the second group of transmission control lines without changing the structure of the pixel, the structure is simple, and the optical performance is good. In addition, at least two pixels in the same pixel unit share one micro lens, so that mutual influence between pixels can be avoided, in one embodiment, one pixel unit corresponds to one micro lens, and the number of transmission control lines in the first group of transmission control lines corresponding to each row of pixel units can be set equal to the number of pixels in each pixel unit, so that the left-right phase information and/or the up-down phase information can be obtained while different densities of phase focus can be switched, and the flexibility can be further improved. 
     The solution of the present application is described in detail below with reference to several specific embodiments. 
     The First Embodiment 
     Referring to  FIG.  1   ,  FIG.  2    and  FIG.  3   , as shown in  FIG.  1   , a pixel circuit according to an embodiment of this application includes N pixel units ( FIG.  1    shows 16×16 pixel units, each pixel unit includes four pixels, and each pixel unit shares a micro lens, but the present application is not limited thereto, wherein, only the micro lenses of the pixel units corresponding to the first group of transmission control lines are shown in the figure, and the micro lenses of other pixel units are not shown), N pixel units are arranged in an array, where N is a positive integer, and N 2. 
     As shown in  FIG.  2   , in an embodiment, each pixel unit includes 4 pixels {circle around ( 1 )}, {circle around ( 2 )}, {circle around ( 3 )}, and {circle around ( 4 )}, but the present application is not limited thereto. In one embodiment, the four pixels ({circle around ( 1 )}, {circle around ( 2 )}, {circle around ( 3 )}, and {circle around ( 4 )}) correspond to one micro lens, And in other embodiments, two pixels may also share one micro lens or the like. 
     Wherein, the transmission transistors of two pixels of at least one of the pixel units is connected to a corresponding first group of transmission control lines, and the transmission transistors of other pixels are connected to a corresponding second group of transmission control lines; wherein, the first group of transmission control lines includes two transmission control lines, and one said pixel corresponds to one said transmission control line. It can be that one pixel is connected to only one transmission control line, and one transmission control line can be connected correspondingly to pixels in different pixel units. 
     In this embodiment, each pixel unit includes four pixels, and each row of pixel units corresponds to six transmission control lines. Taking a 0th row of pixel units as an example, the corresponding transmission control lines are arranged in the order: txap &lt;0&gt;, txa &lt;0&gt;, txb &lt;0&gt;, txc &lt;0&gt;, txd &lt;0&gt;, and txcp &lt;0&gt;; And taking a 4th row of pixel units as an example, the corresponding transmission control lines are arranged in the order: txbp &lt;0&gt;, txa &lt;4&gt;, txb &lt;4&gt;, txc &lt;4&gt;, txd &lt;4&gt;, and txdp &lt;0 &gt;. 
     In this embodiment, the first pixel {circle around ( 1 )} of all pixel units in the nth row (N is an odd number and N&gt;=1) is connected to the first transmission control line txa&lt;n&gt; in the second group of transmission control lines, and the second pixel {circle around ( 2 )} is connected to the second transmission control line txb&lt;n&gt; in the second group of transmission control lines, the third pixel {circle around ( 3 )} is connected to the third transmission control line txc&lt;n&gt; in the second group of transmission lines, and the fourth pixel {circle around ( 4 )} is connected to the fourth transmission control line txd&lt;n&gt; in the second group of transmission lines. 
     As shown in  FIG.  1   , in this embodiment, the transfer transistors of the first pixel {circle around ( 1 )} and the third pixel {circle around ( 3 )} of the pixel units of the 5th column and the 13th column in the 0th row and the 2nd row are respectively connected to the first group of transmission control lines txap and txcp. And the transfer transistors of the first pixel {circle around ( 1 )} and the third pixel {circle around ( 3 )} of the pixel units of the first column and the 9th column in the 12th row and the 14th row are also respectively connected to the first group of transmission control lines txap and txcp, and the transmission transistors of the remaining pixel units of the corresponding rows are all connected to the second group of transmission control lines txa, txb, txc and txd. And the transfer transistors of the first pixel {circle around ( 2 )} and the third pixel {circle around ( 4 )} of the pixel units of the first column and the 9th column in the 4th row and the 6th row are respectively connected to the first group of transmission control lines txbp and txdp. And the transfer transistors of the first pixel {circle around ( 2 )} and the third pixel {circle around ( 4 )} of the pixel units of the 5th column and the 13th column in the 8th row and the 10th row are also respectively connected to the first group of transmission control lines txbp and txdp, and the transmission transistors of the remaining pixel units of the corresponding rows are all connected to the second group of transmission control lines txa, txb, txc and txd. 
     In other embodiments, the number and the positions of the pixel units connected to the first group of transmission control lines may be adjusted according to needs, and the present application is not limited thereto. 
     In this embodiment, the first pixel {circle around ( 1 )} and the third pixel {circle around ( 3 )} of the pixel units of the (a) th column of the (n−1) th row (N is an odd number and n&gt;=1) are connected to the corresponding first group of transmission control lines, and the first pixel {circle around ( 2 )} and the third pixel {circle around ( 4 )} of the pixel units of the (a−3) th column of the (n+1) th row (N is an odd number and n&gt;=1) are connected to the corresponding first group of transmission control lines. And in other embodiments, the number and positions of the pixel units connected to the first group of transmission control lines can be adjusted as needed, and the application is not limited to this. wherein, n is less than or equal to N, a is greater than or equal to 3. 
     Each pixel includes a photoelectric conversion element and a transmission transistor, as shown in  FIG.  3   , four pixels in each pixel unit include photodiodes PD  1 , PD  2 , PD  3 , PD  4 , transmission transistors TXA, TXB, TXC, TXD. Wherein, the photodiodes PD 1 , PD 2 , PD 3 , and PD 4  are used for generating an electric charge in response to incident light. And the transmission transistors TXA, TXB, TXC and TXD are coupled between the corresponding photodiodes PD  1 , PD  2 , PD  3 , PD  4  and floating diffusion node FD for transferring the electric charge accumulated in an exposure process to the floating diffusion node FD according to the transmission control signals TXA, TXB, TXC, TCD respectively. Wherein, four pixels in a pixel unit may share a floating diffusion node FD, or two adjacent pixels may share a floating diffusion node, and the formed nodes FD 1  and FD 2  are electrically connected to the gate of the source follower transistor SF at the same time, and based on the output circuit, the signals corresponding to the two nodes FD 1  and FD 2  are simultaneously output. Specifically, the anode terminals of the photodiodes PD 1 , PD 2 , PD 3 , and PD 4  are connected to the ground terminal, and the cathode terminals thereof are coupled to the floating diffusion node FD through corresponding transfer transistors TXA, TXB, TXC, and TXD. 
     The reset transistor RST is coupled between the first voltage source Vrab and the floating diffusion node FD, and is configured to reset the voltage of the floating diffusion node FD according to the reset control signal rst. 
     The amplification output unit is coupled to the floating diffusion node FD, and is configured to amplify the voltage signal of the floating diffusion node FD. Specifically, in this embodiment, the amplification output unit includes a first source follower transistor SF, a gate of the first source follower transistor SF is coupled to the floating diffusion node FD, a drain thereof is coupled to the second voltage source VRSF, and a source thereof is coupled to the row select transistor as an output terminal. Of course, the present embodiment only schematically shows one implementation of the amplification output unit, and it should be appreciated by those skilled in the art that the amplification output unit may also use other different gain amplifiers to replace the source follower transistor SF, for example, two stages or multiple stages of amplifiers may be used to replace the source follower transistor SF in the present embodiment, and these variations are also within the protection scope of the present application. 
     In an embodiment, the pixel circuit further includes a dual-conversion gain control unit, which is coupled between the reset transistor RST and the floating diffusion node FD, and is used to implement gain control. As a specific embodiment, the dual-conversion gain control unit includes a dual-conversion gain control transistor DCG and a dual-conversion gain capacitor Cdcg, and the dual-conversion gain control transistor DCG is coupled between the reset transistor RST and the floating diffusion node FD. A first terminal of the dual conversion gain capacitor CDCG is coupled to the node between the dual conversion gain transistor DCG and the reset transistor RST, and A second terminal of the dual conversion gain capacitor Cdcg is connected to the specified level. 
     Wherein, as a preferred embodiment, the pixel circuit provided in this embodiment further includes a row select transistor RS coupled between the output terminal of the amplification output unit (e.g., the source of the first source follower transistor SF) and the column output line, and a gate of the row select transistor RS being configured to receive a control signal rs for outputting a voltage signal of the floating diffusion node FD. Of course, it should be noted that the row select transistor RS is present as a preferred embodiment, and the implementation of the present application does not necessarily need to set the row select transistor RS. 
     Taking the reset transistor RST, the transmission transistor TX, the source follower transistor SF, the row select transistor RS, and the dual conversion gain control transistor DCG are all NMOS, N=16×16, the transfer transistors of the pixels {circle around ( 1 )} and {circle around ( 3 )} of the pixel unit of the 5th and 13th columns in the 0th row and the second row are respectively connected to the first transmission control line txap and the second transmission control line txcp of the first group of transmission control lines, and the transfer transistors of the remaining pixel units in the 0th row and the second row are all connected to the first transmission control line txa, the second transmission control line txb, the third transmission control line txc, and the fourth transmission control line txd of the second group of transmission control lines. the control timing thereof is as shown in  FIG.  4   b    as an example to illustrate the working principle of the image sensor of the present embodiment, and a specific working process thereof is as follows: 
     1. At time t0, the row selection signal rs is set to a high level, and the quantization circuit is ready to quantize the data of the corresponding row; 
     2. At time t1, the reset signal rst and the dual-conversion gain selection signal dcg are set to a low level to obtain the corresponding image reset signal; of course, in other embodiments, the dual-conversion gain selection signal dcg can also be set to the high level; 
     3. At time t2, the first transmission control lines txap and txa in the first group of transmission control lines and the second group of transmission control lines, and the third transmission control lines txcp and txc in the first group of transmission control lines and the second group of transmission control lines, are both set to the high level, and all the pixel units in the row 0, row 2, row 12, and row 14 start to transmit the right phase information; 
     4. At time t3, the first transmission control lines txap and txa in the first group of transmission control lines and the second group of transmission control lines, and the third transmission control lines txcp and txc in the first group of transmission control lines and the second group of transmission control lines, are both set to the low level. And all the pixel units in the row 0, row 2, row 12, and row 14 finish transmitting the right phase information, and the quantized right phase information VRPD can be obtained through quantization by the quantization circuit; 
     5. At time t4, the second transmission control lines txbp and txb in the first group of transmission control lines and the second group of transmission control lines, and the fourth transmission control lines txdp and txd in the first group of transmission control lines and the second group of transmission control lines, are both set to the high level, and all the pixel units in the row 4, row 6, row 8, and row 10 start to transmit the left phase information; 
     6. At time t5, the second transmission control lines txbp and txb in the first group of transmission control lines and the second group of transmission control lines, and the fourth transmission control lines txdp and txd in the first group of transmission control lines and the second group of transmission control lines, are both set to the low level. And all the pixel units in the row 4, row 6, row 8, and row 10 finish transmitting the left phase information, and if the two kinds of phase information are summed at the floating diffusion node fd, the image information Vsum is obtained by quantization through the quantization circuit; 
     7. At time t6, the reset signal rst or the dual-conversion gain selection signal dcg are set to the high level to reset the floating diffusion node fd; 
     8. At time t7, the row selection signal rs is set to the low level to end the quantization of the current row. 
     After digital calculation, the left phase information VLPD (VLPD=Vsum−VRPD) can be obtained, so, the image sensor of this embodiment can achieve phase focus with the density of 100% of the left and right phase information of the full array. 
     In other embodiments, the reset operation of setting the reset signal rst and the dual-conversion gain selection signal dcg to the high level and then the low level can also be added between the time t3 and the time t4, so that the object quantized again by the quantization circuit is the individual left phase information instead of the summed Vsum. In addition, it should be noted that, based on the above-mentioned control principle, other focus data for phase focus can also be obtained based on the txap, and the txcp; and the corresponding relationship between the txap, the txcp, and the txa, the txb, the txc, and the tcd in timing can be designed according to actual requirements. 
       FIG.  4   a    is an effect diagram of the phase focus mode when an image sensor according to an embodiment of this application realizes that a density of left-right phase information is 100%. If each pixel unit of the pixel array performs quantization to obtain the right phase information  10   a  and the left phase information  10   b  under the control of the timing shown in  FIG.  4   b   , the phase focus mode in which the density of the left and right phase information is 100% can be realized, and  FIG.  4   a    only shows a 4×2 array, but the application is not limited to this. Wherein, the left phase information  10   b  and the right phase information  10   a  are used for phase focus. 
       FIG.  5   b    is a timing diagram when an image sensor according to a first embodiment of this application realizes that a density of up-down phase information is 6%. Referring to  FIG.  5   b   ,  FIG.  2    and  FIG.  3   , the first transmission control line txap, txa of the first group of transmission control lines and the second group of transmission control lines corresponding to a certain pixel unit and the second transmission control line txbp and txb of the first group of transmission control lines and the second group of transmission control lines in the second group of transmission control lines are all set to the high level, so that the transmission transistors TXA and TXB in the first pixel {circle around ( 1 )} and the third pixel {circle around ( 2 )} of the pixel unit are turned on, so that the pixel unit starts to transmit the up phase information. And after a period of time, the first transmission control line txap, txa of the first group of transmission control lines and the second group of transmission control lines corresponding to the pixel unit and the second transmission control line txbp and txb of the first group of transmission control lines and the second group of transmission control lines corresponding to the pixel unit are both set to the low level, so that the transmission transistors TXA and TXB in the first pixel {circle around ( 1 )} and the second pixel {circle around ( 2 )} of this pixel unit are turned off, and the pixel unit ends transmitting the up phase information, and the quantized up phase information may be obtained by quantizing the circuit quantization. And the principle of obtaining the quantized down phase information is similar to the principle of obtaining the up phase information, and will not be repeated here. 
       FIG.  5   a    is an effect diagram of the phase focus mode when an image sensor according to an embodiment of this application realizes that a density of up-down phase information is 100%. If each of the pixel units in the pixel array performs quantization to obtain the up phase information  20   a  and the down phase information  20   b  under the control of the timing sequence shown in  FIG.  5   b   , the phase focus mode with the density of 100% of the up-down phase information can be realized.  FIG.  5   a    only shows a 4×2 array, but the application is not limited to this. wherein, the up phase information  20   a  and the down phase information  20   b  are used for phase focus. 
       FIG.  6    is an effect diagram of the phase focus mode when an image sensor according to an embodiment of this application realizes that a density of up-down and left-right phase information is 100%. For example, the 4×4 image sensor array, the pixel array  500  can be extended to any suitable size for each application. The 4×2 pixel array in the pixel array  500  performs quantization to obtain the corresponding image information  130 , the right phase information  130   a  and the left phase information  130   b  under the control of the timing shown in  FIG.  4   b   . And the other 4×2 pixel array in the pixel array  500  performs quantization to obtain the corresponding image information  131 , the right phase information  131   a  and the left phase information  131   b  under the control of the timing shown in  FIG.  5   b   , wherein the image information is used for imaging, the left and right phase information, and the up and down phase information are used for phase focus. In fact, the proportions and positions of the pixel units respectively used to obtain the left and right phase information and the upper and lower phase information in the entire pixel array can be configured according to phase focus requirements. 
       FIG.  7   b    is a timing diagram when an image sensor according to a first embodiment of this application realizes that a density of left-right phase information is 3%. In addition,  FIG.  7   a    shows a corresponding pixel layout design, and referring to  FIG.  1    and  FIG.  7   a    and  FIG.  7   b   , as shown in  FIG.  1   , in the 16×16 pixel array, for example, the transfer transistors of the pixels of the pixel units of the 5th column and the 13th column in the second row are respectively connected to the first group of transmission control lines txap and txcp. And the transfer transistors of the pixels of the pixel units of the first column and the 9th column in the 14th row are also respectively connected to the first group of transmission control lines txap and txcp. And the transfer transistors of the remaining pixel units of the second row and the 14th row are all connected to the corresponding second group of transmission control lines txa, txb, txc, and txd; and the transfer transistors of the pixels of the pixel units of the first column and the 9th column in the 6th row are respectively connected to the first group of transmission control lines txbp and txdp. And the transfer transistors of the pixels of the pixel units of the 5th column and the 13th column in the 10th row are also respectively connected to the first group of transmission control lines txbp and txdp, and the transfer transistors of the remaining pixel units of the 6th row and the 10th row are all connected to the corresponding second group of transmission control lines txa, txb, txc, and txd. 
     Therefore, under the control of the timing signal as shown in  FIG.  7   b   , for a row without a phase focus pixel, txa/txb/txc/txd/txap/txbp/txcp/txdp are turned on at the same time to obtain normal image information. For a row with the phase focus pixel, txa/txb/txc/txd are turned on at the same time, txap/txbp/txcp/txdp are set to low level, wherein, the pixel that is not phase focus pixel get normal image information. And the phase focus pixels connected with txap/txcp obtain the left phase information (based on the pixels connected to the second group of transmission control lines), and the phase focus pixels connected with txbp/txdp obtains the right phase information (based on the pixels connected to the second group of transmission control lines). Therefore, under the control of the timing signal as shown in  FIG.  7   b   , the present application can realize a phase focus mode with a density of 3%. Of course, it is also possible to realize other density of focusing through the design and readout of the pixels connected to the first group of transmission control lines. 
       FIG.  8   a    and  FIG.  8   b    are two timing diagrams when an image sensor according to a first embodiment of this application realizes that a density of left-right phase information is 6%. Referring to  FIG.  1   ,  FIG.  8   a    and  FIG.  8   b   , as shown in  FIG.  1   , in the 16×16 pixel array, the transfer transistors of the pixels of the pixel units of the 5th column and the 13th column in the 0th row and the second row are respectively connected to the first group of transmission control lines txap and txcp. And the transfer transistors of the pixels of the pixel units of the first column and the 9th column in the 12th row and the 14th row are also respectively connected to the first group of transmission control lines txap and txcp. And the transfer transistors of the remaining pixel units of the 0th row, the second row, the 12th row and the 14th row are all connected to the corresponding second group of transmission control lines txa, txb, txc, and txd; and the transfer transistors of the pixels of the pixel units of the first column and the 9th column in the 4th row and the 6th row are respectively connected to the first group of transmission control lines txbp and txdp. And the transfer transistors of the pixels of the pixel units of the 5th column and the 13th column in the 8th row and the 10th row are also respectively connected to the first group of transmission control lines txbp and txdp, and the transfer transistors of the remaining pixel units of the 4th row, the 6th row, the 8th row and the 10th row are all connected to the corresponding second group of transmission control lines txa, txb, txc, and txd. 
     Therefore, under the control of the timing signal as shown in  FIG.  8   a   , the transfer transistors of the pixels of the pixel units of the 5th column and the 13th column in the 0th row and the second row, and the transfer transistors of the pixels of the pixel units of the first column and the 9th column in the 12th row and the 14th row are used to obtain the right phase information. And the transfer transistors of the remaining pixel units of the 0th row, the second row, the 12th row and the 14th row are used to obtain the normal image information. The transfer transistors of the pixels of the pixel units of the first column and the 9th column in the 4th row and the 6th row, and the transfer transistors of the pixels of the pixel units of the 5th column and the 13th column in the 8th row and the 10th row are used to obtain the left phase information. And the transfer transistors of the remaining pixel units of the 4th row, the 6th row, the 8th row and the 10th row are used to obtain the normal image information. For its specific implementation principle, please refer to the above description, which will not be repeated here. Therefore, under the control of the timing signal as shown in  FIG.  8   a   , the present application can realize the phase focus mode in which the density is 6%. 
       FIG.  8   b    is a timing diagram when an image sensor according to a second embodiment of this application realizes that a density of left-right phase information is 6%. The timing signals shown in  FIG.  8   b    and  FIG.  8   a    are basically the same, the only difference is that the time when the first group of transmission control lines txap, txcp and the second group of transmission control lines txa, txb, txc, and txd are at a high level is coincident. Under the control of the timing signal shown in  FIG.  8   b   , the present application can also achieve the phase focus mode in which the density is 6%, and the specific principles thereof refer to the description corresponding to  FIG.  8   a   , and details are not described herein again. 
       FIG.  9   a    is a timing diagram when an image sensor according to a first embodiment of this application realizes that a density of left-right phase information is 3%. In addition,  FIG.  9   b    shows a corresponding pixel layout design, referring to  FIG.  1   ,  FIG.  9   a    and  FIG.  9   b   , in  FIG.  9   a   , the left side of the vertical dividing line represents reading the data of rows 0 to 7 in the pixel array, and the pixel units connected to the first group of transmission control lines in the 8 rows of data obtain half of the phase information; wherein, in the first 8 rows of pixel units, the phase focus pixels in the 4th row and the 6th row can obtain the left phase information. And at the same time, the right side of the vertical dividing line represents reading the data of rows 8 to 15 in the pixel array, and the pixel units connected to the first group of transmission control lines in the 8 rows of data obtain the other half of the phase information; wherein, in the last 8 rows of pixel units, the 12th and 14th rows can obtain the right phase information. therefore, the completed phase information can be obtained based on the pixel units connected to the first group of transmission control lines in rows 0 to 15. However, for the focus pixel units connected to the first group of transmission control lines in  FIG.  1   , it is equivalent to half of the unread phase information, which is actually equivalent to the phase focus mode in which the density is 3%. Therefore, under the control of the timing signal as shown in  FIG.  9   a   , the present application can realize a phase focus mode in which the density of the left and right phase information is 3%. It can also be other density transformations designed by those skilled in the art according to actual requirements. 
     The Second Embodiment 
     Referring to  FIG.  10   , as shown in  FIG.  10   , the present embodiment provides an image sensor  100 , including a pixel array  110 . The pixel array  110  is arranged in rows and columns, and the structure of each pixel in the pixel array  110  may be the pixel structure as shown in  FIG.  2    and  FIG.  3   . Please refer to the above description for the specific situation of the pixel structure, which will not be repeated here. 
     In addition, as an illustrative embodiment, the image sensor further includes a logic control unit  120 , a driving unit, a column A/D conversion unit  150 , and an image processing unit  160 ; among them: 
     the logic control unit  120  is configured to control the working timing logic of the entire system; 
     one end of the driving unit is connected to the logic control unit  120 , and the other end is coupled to the pixel array  110  for driving and controlling each control signal line in the pixel array  110 . Specifically, the driving unit includes a row driving unit  130  and a column driving unit  140 . One end of the row driving unit  130  is connected to the logic control unit  120 , and the other end is coupled to the pixel array  110  for providing the pixel array  110  with corresponding row control signals. One end of the column driving unit  140  is connected to the logic control unit  120 , and the other end is coupled to the pixel array  110  for providing corresponding column control signals to the pixel array  110 . 
     the column A/D conversion unit  150  corresponds to each column of pixels in the pixel array  110 , and is configured to implement analog/digital conversion of column signals under the control of the logic control unit  120 ; 
     The image processing unit  160  is configured to perform image processing on the image digital signal output by the column A/D conversion unit  150  under the control of the logic control unit  120 . 
     The Third Embodiment 
     The present embodiment provides a control method for the above pixel circuit, and the control method includes: acquiring an image information based on the first group of transmission control lines and the second group of transmission control lines; or, acquiring the phase focus information based on the first group of transmission control lines and the second group of transmission control lines; or acquiring the phase focus information based on the first group of transmission control lines, and acquiring image information based on the second group of transmission control lines. 
     Wherein acquiring the phase focus information or the image information based on the first group of transmission control lines, and acquiring the image information or the phase focus information based on the second group of transmission control lines, please refer to the above description, which will not be repeated here. 
     In this embodiment, the control method includes a single-row reading mode or a parallel reading mode, wherein in a reading process, by controlling the timing of the first group of transmission control lines and the second group of transmission control lines, the phase focus information may be obtained based on different pixels of the same pixel unit connected to the first transmission control line, or the phase focus information may be acquired based on the pixel units connected to the first transmission control line in different pixel unit rows. 
     In this embodiment, the method of acquiring phase focusing information based on different pixel unit rows includes: the pixel array includes a first focus pixel row having a first pixel unit connected to the first transmission control line, and a second focus pixel row having a second pixel unit connected to the first transmission control line, wherein, acquiring a first focus information based on the first focus pixel row, and acquiring a second focus information based on the second focusing pixel row, so as to obtain the phase focus information. 
     Specifically, for example, the first focus information acquired by the first focus pixel row may be left and right phase information, and the second focus information acquired by the second focus pixel row may be up and down phase information. 
     Obviously, those skilled in the art can make various changes and modifications to the invention without departing from the spirit and scope of the application. In this way, if these modifications and variations of this application fall within the scope of the claims of this application and their equivalent technologies, this application also intends to include these modifications and variations. The technical features of the above-mentioned embodiments can be combined arbitrarily. In order to make the description concise, all possible combinations of the various technical features in the above-mentioned embodiments are not described, however, as long as there is no contradiction in the combination of these technical features, all should be considered as the scope of this specification. 
     It should be noted that in this article, the terms “including”, “including” or any other variants thereof are intended to cover non-exclusive inclusion, so that a process, method, article or device including a series of elements not only includes those elements, it also includes other elements that are not explicitly listed, or elements inherent to the process, method, article, or device. Without more restrictions, the element defined by the sentence “including a . . . ” does not exclude the existence of other identical elements in the process, method, article, or device that includes the element. In addition, different implementations of this application, the parts, features, and elements with the same name in the examples may have the same meaning or different meanings, and their specific meanings need to be determined by their interpretation in the specific embodiment or further combined with the context in the specific embodiment. 
     It should be understood that although the terms first, second, third, etc. may be used herein to describe various elements, these elements should not be limited to these terms. These terms are only used to distinguish the same type of information from each other. For example, without departing from the scope of this document, the first element may also be referred to as the second element, and similarly, the second element may also be referred to as the first element. Depending on the context, as used in this article, the singular forms “a”, “an” and “the” are intended to also include the plural form, unless the context dictates to the contrary. It should be further understood that the terms “comprising” and “including” indicate the presence of the described features, steps, operations, elements, components, items, types, and/or groups, but do not exclude one or more other features, steps, operations, The existence, appearance or addition of elements, components, items, categories, and/or groups. The terms “or” and “and/or” used herein are interpreted as inclusive or mean any one or any combination. Therefore, “A, B or C” or “A, B and/or C” means “any of the following: A; B; C; A and B; A and C; B and C; A, B and C”. An exception to this definition will only occur when the combination of elements, functions, steps, or operations is inherently mutually exclusive in some way. 
     The above are embodiments of the present application only, and should not be deemed as limitations to the scope of the present application. It should be noted that similar variations will become apparent to those skilled in the art to which the present application pertains. Therefore, the scope of the present application is defined by the appended claims.