Abstract:
A CMOS photodiode device for use in a dual-sensitivity imaging pixel contains at least two areas of differential doping. Transistors are provided in electrical contact with these areas to govern operation of signals emanating from the photodiode on two channels, each associated with a different sensitivity to light. A plurality of such photodiodes may be incorporate into a shared arrangement forming a single pixel, in order to enhance the signals.

Description:
BACKGROUND 
       [0001]    Solid state image sensors include those incorporating complementary metal oxide semiconductor (CMOS) design. A photodiode-based pixel array collects opto-electrons for imaging purposes. The pixels are arranged in a row-column format that may, for example, be a 1280×800 array. Row processing circuitry and column processing circuitry operate by known methods to pre-process analog signals and convert the analog signals to digital signals. Low voltage differential signaling (LVDS) provides the final digital output stage. See for example U.S. Pat. Nos. 7,483,058 issued to Frank et al. and 7,265,784 issued to Frank. 
         [0002]    Designs for competitive imaging technologies include those for charge-coupled device (CCD) and CMOS imaging sensors. These concepts originated in the 1960 and 1970&#39;s. While CCD technology achieved an early lead, CMOS is now emerging as the dominant technology. The rise of CMOS-based imaging technology is, in part, attributable to new processing technologies that reduce the size of solid state transistors (MOSFET). Smaller transistor sizes provide higher density, faster speed, lower power dissipation, and more functionality that can be integrated on a single chip. This densification is shown by way of example where in 1995 Jet Propulsion Laboratory produces the first successful active 128×128 pixel CMOS image sensor. The distance from pixel to pixel is known as the pixel pitch. The JPL device of 1995 had a pixel pitch of about 20 μm. This compares to current technologies that are capable of shrinking the pixel pitch down to about 1.2 μm in fully functional imaging devices; however, transistor size is no longer the limiting factor in achieving further scale reductions beyond about 1.2 μm. 
         [0003]    Smaller pixel sizes problematically provide less photosensing area on the pixel itself. Each pixel is less sensitive to light where also the signal to noise ratio is disadvantageously reduced. These problems diminish the dynamic range that is achievable from each pixel. Various solutions have been proposed to address this problem, but each solution has its own problems. Logarithmic response pixels have been proposed to extend the dynamic range nonlinearly, as reported in Kavidas et al. “a Logarithmic Response CMOS Image Sensor With On-Chip Calibration” IEEE Journal of Solid State Circuits, Vol. 35, No. 8 pp. 1146-1152 (August 2000). This solution is problematic where the nonlinear response produces difficulty in reconstructing the final image. Another proposed solution is to provide a lateral overflow capacitor as reported in Akahane et al., “A Sensitivity and Linearity Improvement of a 100-dB Dynamic Range CMOS Image Sensor Using A Lateral Overflow Integration Capacitor” IEEE Journal of Solid State Circuits, Vol. 41 No. 7, pp. 1577-1587 (July 2008). This second solution problematically introduces a large variation in the threshold voltage of the transfer gates, and this may introduce additional ‘dark’ current leading to higher dark current imaging shot noise. Some have proposed adopting multiple exposure times to expand the dynamic range as reported in Mase et al. “A Wide Dynamic Range CMOS Image Sensor With Multiple Exposure-Time Signal Outputs and 12-bit Column-Parallel Cyclic A/D Converters” IEEE Journal of Solid-State Circuits, Vol. 40 No. 12 pp. 2787-2795 (December 2005). This third solution produces discontinuity in the signal-to-noise ratio, where also differing integration times may distort images due to motion. 
         [0004]    As reported in U.S. Pat. No. 5,625,210 issued to Lee et al., pinned photodiodes may be incorporated into CMOS image sensors to improve the blue response, reduce image lag and minimize the dark current characteristics of active pixel sensors. 
       SUMMARY 
       [0005]    The present disclosure mitigates the problems outlined above and advances the art by providing a photodiode device having multiple sensitivity to light conditions. The photodiode device is differentially doped to provide a plurality of channels each emanating a signal allocated to a particular light condition, such as bright light and low light conditions. The photodiode device may be incorporated within circuitry forming a pixel to enhance the dynamic range of the pixel, also with improvement of signal to noise ratio. 
         [0006]    In one embodiment, a single photodiode device has multiple sensitivity to light conditions. A photoactive area is provided to convert light into photocurrent. A first channel includes a first dopant material affecting potential on the first channel. A first transistor is positioned to govern transfer of charge from the photoactive area into the first channel. A second channel includes a second dopant material affecting potential on the second channel to a different degree than the first dopant material affects potential on the first channel. A second transistor is positioned to govern transfer of charge from the photoactive area into the second channel. By these expedients, due to differences in the first dopant material and the second dopant material, the first channel as compared to the second channel is better suited for imaging conditions under one of a low light condition and a bright light condition. 
         [0007]    In one aspect, the first dopant material and the second dopant material may reside in different regions of the photoactive area such that a first region of the photoactive area has an inherent material property of V pin1  associated with the first dopant material on the first channel. The second region of the photoactive area then has an inherent material property of V pin2  associated with the second dopant material on the second channel, such that V pin1  has a greater magnitude than does V pin2 . 
         [0008]    In one aspect, the photodiode device may be provided with circuitry incorporating the photodiode device in a pixel that uses the first channel to sense a bright light condition and the second channel to sense a low light condition. 
         [0009]    In one aspect, the first transistor may have an internal threshold voltage V ti1  and the second transistor may have an internal threshold voltage V ti2 , such that V ti1  is approximately equal to V t2 . 
         [0010]    In one aspect, the pixel circuitry includes a transistor that is selectively actuable to isolate the first channel from the second channel, thus separating a signal on the second channel from a signal on the first channel. 
         [0011]    In one aspect, the photodiode device may be incorporated in a pixel that shares a plurality of such photodiode devices. 
         [0012]    According to one embodiment, the photodiode device contains the first dopant material residing in the first transistor and the second dopant material residing in the second transistor. Thus, the first channel has an increased internal threshold voltage V ti  as compared to the second channel. 
         [0013]    In one aspect, the pixel circuitry may include the first channel as a loop connected to the second channel downstream of the second transistor relative to the second area. 
         [0014]    In one aspect, pixel circuitry is improved by use of the photodiode device with differential doping to provide a first channel producing a signal allocated to a first level of sensitivity to light and a second channel producing a signal allocated to a second level of sensitivity to light. 
         [0015]    In one aspect, pixel circuitry is improved by use of a photoactive area feeding a plurality of channels, where a plurality of transistors each govern flow of accumulated charge from the photoactive area into a corresponding channel. Each transistor may be differentially doped with respect to the other transistors to produce a different voltage potential on each channel attributable to different internal threshold voltages of the respective transistors. 
         [0016]    It will be appreciated that the foregoing device may be operated by: (1) resetting the photodiode device to a predetermined voltage; (2) turning off the first transistor and the second transistor by application of a gate voltage V TX1  to the first transistor and a second gate voltage V TX2  to the second transistor, where V TX1  equals V TX2 ; (3) impinging light upon the photodiode device to produce an accumulated charge; and (4) switching on at least one of the first transistor and the second transistor to allow charge to flow from the photodiode device. 
       Definitions 
       [0017]    As used herein, the term “internal threshold voltage”or V ti  is an inherent property of a solid state transistor constituting a voltage that is required for current to flow across the transistor. 
         [0018]    Pin voltage or V pin  means an inherent property of a photodiode that exists as a voltage upon full depletion of what the art alternatively refers to as the depletion region, photoconversion region, photo collection region or photo sensitive region of a photodiode. This depletion region exists at a boundary between n-doped and p-doped regions and is where photons excite immobile electrons into a mobile state where the electrons can move to one side to reduce the voltage induced on the photodiode during its reset sequence. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0019]      FIG. 1  is a schematic circuit diagram of a CMOS based dual-sensitivity pixel incorporating a photodiode device that is differentially doped to provide multiple channels of different sensitivity to light; 
           [0020]      FIG. 2  shows a photodiode device according to one embodiment that includes differentially doped areas to differentiate PIN voltage or V pin  properties of the photodiode material respectively allocated to the different channels; 
           [0021]      FIG. 3  shows a photodiode device according to one embodiment that includes differentially doped areas to differentiate V pin  properties of the photodiode material respectively allocated to the different channels; 
           [0022]      FIG. 4  is a voltage diagram that describes operation of the V pin -based voltage embodiments; 
           [0023]      FIG. 5  shows a photodiode device according to one embodiment that includes differentially doped areas to differentiate internal threshold voltage or V ti  properties of transistors that are respectively provided for control of signals emanating on the different channels; 
           [0024]      FIG. 6  is a voltage diagram that describes operation of the V ti -based voltage embodiments; 
           [0025]      FIG. 7  shows operation of a pixel incorporating the photodiode device on a first channel FD 1  allocated to bright light signal and a second channel FD 2  allocated to low light signal; and 
           [0026]      FIG. 8  shows a two-share arrangement incorporating a plurality of photodiode devices in a single pixel. 
       
    
    
     DETAILED DESCRIPTION 
       [0027]      FIG. 1  is a schematic circuit diagram showing an improvement constituting a dual sensitivity pixel  100  demonstrating wide dynamic range performance. A photodiode device PD 1  is used to generate a charge or photocurrent Q. Transistors M Tx1  and M Tx2  control dissipation of the charge Q for image sense operations such that a closed state of M Tx1  acting as a switch feeds a first channel designated as node FD 1 , and a closed state of M Tx2  acting as a switch feeds a second channel designated as node FD 2 . Transistor M DFD  may be opened or closed by varying the applied voltage V DFD  for selective isolation of node FD 1  from node FD 2 . Transistor M SF  is a readout transistor acting as a source-follower buffer that accumulates pixel voltage V p arising from the charge Q and permits readout or observation of this voltage V p  without necessarily removing the accumulated charge. A reset transistor M RST  may be closed for reset of the dual sensitivity pixel  100  by clearing all integrated charge when transistors M Tx1  and M Tx2  are also closed. Transistors M RST  and M SF  are connected to power supply voltage V DD . Transistor M SEL  permits readout of a single ROW of the pixel array during sense operations. Node FD 1  forms a loop that discharges into node FD 2  at a position downstream of transistor M Tx2  relative to the photodiode PD 1 . 
         [0028]    It will be appreciated from the context of  FIG. 1  that voltages V Tx1  and V Tx2  may be provided at different levels to achieve different levels of sensitivity from the single photodiode device PD 1 , respectively, in nodes FD 1  and FD 2 . However, according to the various embodiments discussed below, different levels of sensitivity may also exist due to differential doping of the photoactive area of the photodiode device PD 1 . This permits the voltages V Tx1  and V Tx2  to be the same, which is preferred according to one such embodiment. V Tx1  and V Tx2  may be set to a common value while voltage properties inherent to the photodiode PD 1  and/or transistors M Tx1  and M Tx2  create different channels within the photodiode device PD 1 . These concepts as applied to  FIG. 1  are expanded in the discussion below. 
         [0029]      FIG. 2  shows how to apply two voltages to govern current flow from the same photodiode device  200 , which constitutes the photodiode device PD 1  of  FIG. 1  according to one embodiment.  FIG. 2  retains like numbering of identical parts with respect to  FIG. 1 . The photodiode device  200  may include a substrate  202  and a first doped region  204  with n and p doping that provides carrier mobility for the transport of electrons and holes resulting in photocurrent during the presence of incident light. The gate voltage V Tx1  is applied for control of current through transistor M Tx1  as shown in  FIG. 1 . Scaled doping of solid state photodiodes to produce the same or different charge generation performance is known to the art. In region  206 , the n and p doping differs from that of region  204  to produce a different photocurrent response under incident light. Gate voltage V Tx2  is applied to control the flow of current through transistor M Tx2 . In this embodiment of  FIG. 2 , the gate voltages V Tx1  and V TX2  are preferably the same, although these voltages may also differ from one another. The differential doping of regions  204 ,  206  produce different photocurrent responses in the photodiode PD 1 . These responses may, for example, be respectively allocated for imaging under a bright light condition versus a low light condition, as will be explained more completely below. In this embodiment, the surface area footprint of region  204  feeding node FD 1  is advantageously much larger, such as more than five times or even ten times larger, than the footprint of region  206 . This provides a greater surface area for collection of low light condition optoelectronic charges from light impinging upon region  204 , while also presenting less surface area for collection of bright light feeding node FD 2 . 
         [0030]      FIG. 3  depicts another embodiment concerning how to achieve different current levels from different portions of the same photodiode device  300 , which for example may constitute the photodiode device PD 1  of  FIG. 1  according to one embodiment.  FIG. 3  retains like numbering of identical parts with respect to  FIG. 1 . The photodiode device  300  contains a substrate  302  that is provided with regions  304 ,  306  that differ from one another in the amount of n and p doping to produce different photocurrent responses under conditions of ambient light. Region  304 , is for example a lightly p-type doped substrate. V TX1  as applied to M Tx1  controls delivery of photocurrent through node FD 1 , and V Tx2  controls delivery of photocurrent through transistor M TX2 . 
         [0031]    The differential doping of regions  304 ,  306  produce different photocurrent responses in the photodiode PD 1 . These responses may, for example, be respectively allocated for imaging under a bright light condition versus a low light condition, as will be explained more completely below. In this embodiment, the surface area footprint of region  304  feeding node FD 1  is advantageously much larger, such as more than five times or even ten times larger, than the footprint of region  306 . This provides a greater surface area for collection of low light condition optoelectronic charges from light impinging upon region  304 , while also presenting less surface area for collection of bright light feeding node FD 1 . 
         [0032]      FIG. 4  shows, by way of example, operation of the dual sensitivity pixel  100  in various portions of  FIG. 1  where the voltages V pin1  and V pin2  are achievable by either the embodiment of photodiode device  200  or photodiode device  300 . The voltage V pin1  constitutes an inherent property of the photodiode PD 1  in region  204  or  306  as the case may be (see  FIGS. 2 and 3 ). The voltage V pin2  constitutes an inherent property of the photodiode PD 1  in region  206  or  304  as the case may be (see  FIGS. 2 and 3 ). The photodiode devices  200 ,  300  are operated in reverse bias mode. The gate voltages V TX1  and V TX2  as applied to place the transistors M TX1  and M TX2  in respective states of “off” preventing the flow of photocurrent current or “on” permitting the flow of photocurrent. Photocurrent generated from regions  204  or  306  will flow through transistor M TX1  where V TX1  exceeds V pin1 . Photocurrent generated from regions  206  or  304  will flow through transistor M TX2  where V TX2  exceeds V pin2 . The channel potential through FD 1  is increased by having a greater V pin1 , such that channel FD 2  is the preferred channel for low light imaging conditions. 
         [0033]    The photodiode PD 1  may be reset to voltages that are limited by the internal properties of V pin1  and V pin2  to other values corresponding to V TX1  and V TX2  Photocharges are generated by photons entering the space and collect until transistors M TX1  and M TX2  turn “on.” FD 1  and FD 2  may also be reset to a voltage that is the same or greater than V TX1  and V TX2 . When the transistors M TX1  and M TX2  turn “on,” the charges flow to FD 1  and/or FD 2 , which by design have a deeper potential well than does PD 1 . FD 1  and FD 2  may be designed such that their charge holding capacities matches their partner regions  204 ,  206 ,  304 ,  306  of PD 1 . 
         [0034]    The node FD 2  may be exposed to the voltage on node FD 1  by turning “on” the transistor M DFD  (see  FIG. 1 ), in which case the voltage on node FD 1  equals the voltage on node FD 2  as shown in  FIG. 4 . Different voltages between nodes FD 1  and FD 2  may exist when transistor M DFD  is “off.” 
         [0035]      FIG. 5  shows yet another embodiment of photodiode device PD 1  as photodiode device  500 . This embodiment does not require use of different V pin  properties on nodes FD 1  and FD 2 , but uses instead different internal threshold voltages (Vti) in the transistors M Txt1 , M Txt2 . On substrate  502 , region  504  is lightly doped with p-type material that produces an internal threshold voltage property V ti2  inherent to transistor M TX2 . Region  506  is doped with a material that increases V ti1  in in transistor M TX1 . V pin  is the same for all of region  504  and does not differ in the photodiode device  500 . The channel potential of FD 1  is increased by the implantation in region  506  that raises V ti1  above V ti2 . Thus, channel FD 2  is preferred for low light imaging conditions where V TX1  and  V   TX2  may be equal and the quantity ΔV ti , which is the increase in internal threshold voltage due to the high V ti  implantation of region  506 , increases the potential on channel FD 1 . 
         [0036]      FIG. 6  shows, by way of example, operation of the dual sensitivity pixel  100  where the potential of channels FD 1 , FD 2  vary by higher V ti  implantation in region  506  when using the embodiment of photodiode device  500  as PD 1  (see  FIG. 1 ). Gate voltages V TX1  and V TX2  may be equal tone another and selectively applied to turn “on” or “off” the corresponding gate transistors M TX1 , M TX2 . It will be appreciated that V pin1  presents an additional hurdle to carrier mobility since the quantity V TX1 +ΔV ti &lt;V TX2 , and so the channel FD 2  is preferred for imaging in low light conditions. 
         [0037]      FIG. 7  shows operation of the dual sensitivity pixel  100 , generally speaking, according to the various embodiments described above. The signal in node FD 2  may represent information from the low light or dark signal alone until such point  700  as the bright light signal on node FD 1  becomes active. 
         [0038]      FIG. 8  shows a pixel  800  including a two-shared arrangement including photodiodes PD 1  and PD 2 .  FIG. 8  retains like numbering of identical circuit elements with respect to  FIG. 1 . Here the photodiode device PD 2  may be one according to any of the photodiode devices  200 ,  300 ,  500 . The photodiode device PD 1  may be the same as or different from photodiode device PD 2 . Where PD 1  and PD 2  are the same, there is amplification of the output signal on the bright light or dark signal channels due to dual input. Where PD 1  and PD 2  are different, there are then four channels each having different sensitivities. Transistors M Tx1a  and M Tx2a  correspond to transistors M Tx1  and M Tx2  as described above with respect to photodiode devices  200 ,  300 ,  500 , where the “a” subscript indicates use with PD 1 . Similarly, transistors M Tx1b  and M Tx2b  correspond to transistors M Tx1  and M Tx2  as described with respect to photodiode devices  200 ,  300 ,  500 , where the “b” subscript indicates use with PD 2 . 
         [0039]    The foregoing specification teaches by way of example and not by limitation. Accordingly, the claims should not be read as being unduly narrowed by the disclosure of the specification. Those skilled in the art will appreciate that what is shown and described may be subjected to insubstantial changes without departing from the scope and spirit of what is claimed. For this reason, the inventors hereby state their intention to rely upon the Doctrine of Equivalents to protect their full rights in the invention.