Patent Document

TECHNICAL FIELD OF THE INVENTION 
     The present invention relates to CMOS image sensors used in scanners, and more particularly, to a readout circuit in the CMOS image sensor that draws no DC current during readout. 
     BACKGROUND OF THE INVENTION 
     Scanners are commonly used in connection with a personal computer (PC) to digitize a document. The document may be a textual document or other type of document, such as a photograph. One of the important components of a scanner is the imaging device. In many modem scanners, the imaging device is a CCD image sensor. Recently, CMOS image sensors have made significant inroads into applications previously dominated by CCD image sensors. This is due in part to the lower cost and lower power consumption of CMOS image sensors. These advantages are particularly important in PC camera applications, security applications, cell phone applications, and the like. 
     Depending upon the particular application, CMOS image sensors come in a variety of array sizes. High-resolution image sensors with over one million pixels are used in digital still cameras, while lower resolution CIF, VGA, or SVGA formats are used for security camera or PC camera applications. In many applications, the pixel array size is on the order of 352-1280 pixels per row with 288-1024 pixels per column. 
     For scanner applications, the pixel array has significantly different dimensions. Typically, approximately 10,000 pixels are in each row. Specifically, most scanners are manufactured to scan documents 8.5 inches wide. At a resolution of 1200 dots per inch (dpi), this requires a little over 10,000 pixels. Further, a black and white scanner will only require a single row of pixels. However, for a color scanner, three rows of 10,000 pixels are required, one row for the color red, one row for the color green, and one row for the color blue. 
     During readout of the signals from each pixel in the array, there is typically a current associated with the readout process. If a large number of pixels must be read out simultaneously, then a large current is required. The large current required will also cause a voltage drop in the power supply line and also affect the ground line of the image sensor. This in turn will cause non-uniformity and decrease in the signal range of the image sensor. 
     While this is an issue for many image sensors, the problem is complicated by the need to read out over 30,000 pixels simultaneously for a color image sensor used in a scanner. Moreover, because of the large number of pixels in a row, the actual dimension of the pixel array is on the order of 2 centimeters. Because of this, the metal lines used as power and ground are unusually long compared to image sensors used in other applications. For this additional reason, the voltage drop in the power and ground lines is problematical. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The foregoing aspects and many of the attendant advantages of the invention will become more readily appreciated as the same become better understood by reference to the following detailed description, when taken in conjunction with the accompanying drawings, wherein: 
     FIG. 1 is a schematic diagram of a readout circuit formed in accordance with the present invention. 
     FIG. 2 is a schematic diagram of a readout circuit formed in accordance with an alternative embodiment of the present invention. 
     FIG. 3 is a schematic diagram of a readout circuit formed in accordance with another alternative embodiment of the present invention. 
     FIG. 4 is a schematic diagram of a readout circuit formed in accordance with yet another alternative embodiment of the present invention. 
     FIG. 5 is a schematic diagram of a readout circuit formed in accordance with yet another alternative embodiment of the present invention. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     In the following description, numerous specific details are provided, such as the identification of various system components, to provide a thorough understanding of embodiments of the invention. One skilled in the art will recognize, however, that the invention can be practiced without one or more of the specific details, or with other methods, components, materials, etc. In still other instances, well-known structures, materials, or operations are not shown or described in detail to avoid obscuring aspects of various embodiments of the invention. 
     Reference throughout this specification to “one embodiment” or “an embodiment” means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the present invention. Thus, the appearance of the phrases “in one embodiment” or “in an embodiment” in various places throughout this specification are not necessarily all referring to the same embodiment. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more embodiments. 
     As noted above, a CMOS image sensor includes an array of pixels formed into columns and rows. For a color scanner application, the array consists of three rows of pixels, one for each primary color. Each of these pixels must be read out in some manner. Typically, each column of pixels has associated therewith a readout circuit, which is the subject of the present invention. In the description below, a single pixel is described in connection with a readout circuit. It can be appreciated that multiple readout circuits would be required for the full image sensor. 
     Turning to FIG. 1, an active pixel  101  is shown connected to a readout circuit  103 . The active pixel  101  includes a photodiode  105 , a reset transistor  107 , pixel output transistor  109 , and row select transistor  111 . The readout circuit  103  includes a precharge transistor  113 , a hold transistor  115 , a capacitor  117 , and an amplifying output transistor  119 . Because the row select transistor  111 , in some interpretations, may not be explicitly considered part of the pixel  101 , the row select transistor  111 , alternatively, may be considered part of the readout circuit  103 . Similarly, the pixel output transistor  109  may also be considered as a part of the readout circuit  103 . 
     The photodiode is connected between ground and the source of reset transistor  107  at a node A. The drain of reset transistor  107  is connected to a voltage rail set at a value (V R     —     reset ). V R     —     reset  is a reference voltage, which could be in one embodiment V DD , or a value lower than V DD . The gate of the reset transistor  107  is controlled by a reset signal line. The reset transistor  107  operates as a switch that is controlled by the reset signal line. 
     Further, the source of the reset transistor  107  (corresponding to the “output” of the photodiode  105 ) is connected to the gate of the pixel output transistor  109 . In this manner, the pixel output transistor  109  is designed such that the voltage output by the photodiode  105  will cause the pixel output transistor  109  to operate in the linear region. As will be seen below, this will modulate the magnitude of a signal to be output. In one embodiment, the pixel output transistor  109  is a PMOS, however, as will be seen below in other embodiments, an NMOS may also be used. 
     The pixel output transistor  109  is connected between ground and the source or drain of row select transistor  111 . The gate of the row select transistor  111  is connected to a row select (RS) signal line. The row select transistor  111  operates as a switch that is controlled by the row select signal line. 
     The source or drain of the row select transistor  111  is connected to the source or drain of the hold transistor  115 . The gate of the hold transistor  115  is connected to a hold signal line. The hold transistor  115  operates as a switch that is controlled by the hold signal line. 
     Also connected to the source or drain of the row select transistor  111  is the source of the precharge transistor  113 . The gate of the precharge transistor  113  is connected to a precharge signal line. The precharge transistor  113  operates as a switch that is controlled by the precharge signal line. 
     The drain of the hold transistor  115  is connected to one terminal of the capacitor  117 . The other terminal of the capacitor  117  is connected to ground. Further, the drain of the hold transistor  115  is connected to the gate of the output transistor  119 . In this conventional amplification configuration, the amplifying output transistor  119  serves as an amplification element. 
     In this embodiment, the readout circuit  103  operates in two stages, a precharge stage and a readout stage. In the precharge stage, the row select signal is low, causing the row select transistor  111  to be off. The precharge signal and hold signal is high, causing the precharge transistor  113  and hold transistor  115  to be on. This causes the voltage V DD  to be placed on capacitor  117 , thereby charging the capacitor  117 . After the capacitor  117  has been charged, the precharge signal and hold signal is then put to low, causing the precharge transistor  113  and hold transistor  115  to be off. 
     During the readout stage, the row select signal and the hold signal is high, turning on the both of these transistors  111  and  115 . This will cause the capacitor  117  to discharge via a current flowing through the pixel output transistor  109 . The discharge current decreases rapidly with time. After a predetermined and consistent amount of time, the row select signal and the hold signal is then put to low, turning off the both of these transistors  111  and  115 , and ending the discharge process. 
     The rate at which the capacitor  117  is discharged is controlled by the signal on the gate of pixel output transistor  109 . If a high signal is output by the photodiode  105 , then in the case of the PMOS transistor  109 , the pixel output transistor  109  allows minimal current discharge, thereby preserving a high signal to be stored on the capacitor  117 . If a low signal is output by the photodiode  105 , then in the case of the PMOS transistor  109 , the pixel output transistor  109  allows maximal current discharge, thereby preserving a low signal to be stored on the capacitor  117 . In such a manner, the output of the photodiode  105  modulates the amount of charge that remains stored on the capacitor  117 . The voltage that is stored on the capacitor  117  is then used to control the amplifying output transistor  119 . Note that the readout result is insensitive to the precharge voltage value of the capacitor C, as long as it is consistently applied and as long as the time during the readout stage is consistent. 
     After the signal has been read out, the photodiode  105  is reset using the reset transistor  107 . The resetting of the pixel  101  through reset transistor  107  may be done at or about the same time as the precharge operation. Note that the operation of the reset transistor  107  is commonly used to reset the photodiode  105  after the signal is read out. This process is well known in the prior active pixel art. During the reset operation, the voltage at node A is set to voltage (V R     —     reset ). As the photodiode  105  proceeds through the integration time, where the photodiode  105  is gathering light, the voltage at node A decreases in proportion to the amount of gathered light. 
     Several advantages of the present invention are noticed. First, because no DC current is drawn during readout, this requires less power. Indeed, calculations indicate that only approximately 10% of the power of prior readout circuits is required. 
     Second, there is a high uniformity and large signal range. During readout, the discharge current flows inside the readout circuit. Because there is no current on the outside power and ground lines, there is no voltage drop along the power and ground lines. 
     In general terms, the present invention uses a capacitor to store a predetermined charge during a precharge stage. Next, during a readout stage, the signal from a photodiode is then used to modulate the amount of charge that is discharged from the capacitor. The remaining charge on the capacitor after the discharge during the readout stage is then amplified as a signal and output. 
     FIG. 1 illustrates one possible configuration of a readout circuit that can implement this technique. However, it can be appreciated that other configurations for the readout circuit is possible. For example, FIG. 2 shows such an alternative embodiment. 
     In this embodiment, the capacitor  117  is charged by having the row select transistor  111  off and the precharge transistor  113  and a ground transistor S 1  on. This charges the capacitor  117  to a voltage V DD . After the capacitor  117  has been charged, the precharge transistor  113  and the ground transistor S 1  is turned off. This allows the capacitor  117  to carry an initial voltage V DD , but still allowing the capacitor  117  to discharge during a readout stage. 
     Specifically, during the readout stage, the row select transistor  111 , the precharge transistor  113 , and the transistor S 0  is turned on. This allows the capacitor  117  to discharge through the pixel output transistor  109 , as modulated by the signal at node A from the photodiode  105 . While the term “discharge” is used, charge is actually being placed (through pixel output transistors  109 , row select transistors  111 , and transistor S 0 ) onto one plate of the capacitor  117  to equalize (or “discharge”) the voltage on the capacitor  117 . 
     In some situations, it is not possible to form a discharge current path inside the readout circuit. FIG. 3 shows an embodiment that remedies this situation. Specifically, FIG. 3 is substantially similar to FIG. 2, except that node B is not connected to node C. In this situation, during readout, there is a discharge current in the outside power and ground lines. Although the discharge current rapidly decreases rapidly with time, there is still a small voltage drop along the power and ground lines at the end of the readout stage. Thus, this embodiment is less desirable than the circuits of FIGS. 1 and 2, but still more desirable than the prior art. 
     In all of these embodiments, the capacitors in the readout circuits can be charged simultaneously or individually. For simultaneous charging, this will cause a relatively large current and associated drop in the power line. Therefore, it would be undesirable to read out data at this time. 
     FIG. 4 shows yet another alternative embodiment. In this embodiment, the capacitor is discharged first, and then a readout step is performed. While much of the individual components are similar to that of FIGS. 1-3, the arrangement and operation is different. Specifically, the photodiode  105 , the reset transistor  107 , the pixel output transistor  109 , and the row select transistor  111  are substantially configured the same as previous embodiments. However, in a first discharge stage, the row select transistor  111  is turned off and a discharge transistor  121  and hold transistor  115  is turned on. This will discharge the capacitor  117 , resulting in no voltage differential between the anode and cathode (both at the same potential V DD ). After the discharge cycle is complete, the discharge transistor  121  and hold transistor  115  are turned off. 
     During the readout stage, the row select transistor  111  and hold transistor  115  is turned on. This results in the capacitor being charged by having current flow through the hold transistor  115 , the row select transistor  111 , and the pixel output transistor  109  to ground. In other words, the voltage at the capacitor plate connected to the gate of the amplifying output transistor  119  steadily decreases from V DD  towards ground as current flows. This “charges” the capacitor  117 . 
     The amount of current flow is modulated by the signal at node A as applied to the gate of pixel output transistor  109 . Thus, the amount of voltage differential between the anode and cathode of the capacitor  117  is dependent upon the pixel output transistor  109 , as modulated by the signal output from photodiode  105  at node A. This signal is thus stored in the capacitor  117 , and then output through the amplifying output transistor  119 . 
     The circuit of FIG. 5 works in substantially similar manner. Specifically, in a first discharge stage, the row select transistor  111  is turned off and a discharge transistor  121  and hold transistor  115  is turned on. This will discharge the capacitor  117 , resulting in no voltage differential between the anode and cathode (both at the same ground potential). After the discharge cycle is complete, the discharge transistor  121  and hold transistor  115  are turned off. 
     During the readout stage, the row select transistor  111  and hold transistor  115  is turned on. This results in the capacitor being charged by having current flow from V DD  through the hold transistor  115 , the row select transistor  111 , and the pixel output transistor  109 . In other words, the voltage at the capacitor plate connected to the gate of the amplifying output transistor  119  steadily increases from ground to V DD  as current flows. This “charges” the capacitor  117 . 
     The amount of current flow is modulated by the signal at node A as applied to the gate of pixel output transistor  109 . Thus, the amount of voltage differential between the anode and cathode of the capacitor  117  is dependent upon the pixel output transistor  109 , as modulated by the signal output from photodiode  105  at node A. This signal is thus stored in the capacitor  117 , and then output through the amplifying output transistor  119 . 
     The embodiments of FIGS. 4 and 5 both generate a small current and voltage drop in the power and ground lines at the end of the readout stage. However, the embodiments of FIGS. 4 and 5 can realize the discharge path inside the readout circuit easily during layout. Further, the discharge time of these embodiments is relatively short. 
     While the preferred embodiment of the invention has been illustrated and described, it will be appreciated that various changed can be made therein without departing from the spirit and scope of the invention. For example, while the present invention has been described in terms of using a photodiode, other types of light sensing elements may also be used, such as a photogate and the like. Further, the above examples are described using a p-type substrate and photodiode. For an n-type substrate or a photogate sensor, the present invention is equally applicable to one of ordinary skill. 
     Thus, one of ordinary skill after reading the foregoing specification will be able to affect various changes, alterations, and substitutions of equivalents without departing from the broad concepts disclosed. It is therefore intended that the scope of the letters patent granted hereon be limited only by the definitions contained in appended claims and equivalents thereof, and not by limitations of the embodiments described herein.

Technology Category: 5