Abstract:
The invention is an imaging device having a high fill factor. The high fill factor is achieved by constructing the light sensors in a vertical fashion in the imaging device. The control circuitry of the light sensor is then contained inside the integrated circuit chip, rather than taking up area that could otherwise be used for light collection. The majority of the area on the surface of the IC chip is made up of light sensing elements, since the control circuitry is embedded in the IC chip. The control circuitry is connected to the light sensing devices through vias in the IC chip. The control circuitry of the chip is mainly contained within the die, rather than on it.

Description:
PATENT APPLICATION 
     1. Technical Field 
     The present invention is directed to imaging sensors and the associated imaging devices. In particular, the invention is directed towards a more compact imaging sensor providing for more efficient operation of an imaging device and providing for denser pixel structure on the imaging device. 
     2. Related Art 
     Conventional image technology usually places most acquisition and control elements near the surface of a wafer. A pixel structure occupies an area on the wafer or integrated circuit (IC) chip. This area is divided between area used for elements actually acquiring the image and elements controlling the functionality of the image sensing element. 
     Typically, a light sensing element, such as a photodiode, takes up an area on a surface of the IC chip housing the imaging device. The area of the diode on the surface of the IC chip generates a signal indicative of the light striking the area. 
     However, the total pixel structure requires control circuitry for controlling the actions of the overall photodetector and the transmission of the signal from the photo-sensing element to the remainder of the imaging device. These control functions include select circuitry, amplifier circuitry, and reset circuitry. This control circuitry is typically made up of transistors and metal interconnect lines that take up space on the surface of the IC chip. 
     Thus, the total area for a single image detector cannot be used for light detection. The ratio of the light sensing surface to the total area required for the light detector structure including the detection circuitry and the control circuitry is known as the fill factor. Conventional imaging sensors generally have a low fill factor ratio. For a typical conventional sensor, the fill factor may range from 20% or so to 40% in higher end sensors. 
     With lower fill factors, the number of pixels per imaging device is lower. As such, fewer sensors may be placed in a given area, and the density of the light sensors on the IC chip is decreased. 
     With higher densities of imaging sensors on an IC chip, the total size of an imaging device may be reduced with the same number of pixels. Or, higher granularity or sensitivity may be obtained by putting more imaging sensors in a constant area. 
     Additionally, greater color clarity and color discrimination may be achieved with higher pixel or imaging sensor density. In some conventional color imaging devices, a coating may be used on an individual imaging element to selectively activate that imaging element for a particular wavelength of light. 
     In a red-green-blue (RGB) color scheme, for example, a single pixel or light sensor may be manufactured to be responsive to blue light. Other adjoining or nearby pixels or light sensors are manufactured to be responsive to red and green light, respectively. As for the pixel that is activated solely by blue light, the red and green components for the blue pixel may be estimated by using values of nearby pixels activated by red and green light, respectively. 
     Thus, for example, assume a fill factor of 25% for an older imaging sensor. If the fill factor can be improved to one of 75%, an imaging sensor could directly measure the red, green, and blue components of a target image in the area of an older single pixel, which also needs estimations from other adjoining pixels for missing color components. Thus, the color clarity of a target image may be improved with denser image sensors without sacrificing granularity. Correspondingly, an image of a finer granularity can be derived from a higher fill factor. 
     Thus, when the fill factor can be raised, more efficient imaging devices may be constructed. A higher fill factor means that the pixel structures or the individual imaging sensors may be placed closer together. Thus, a higher fill factor leads to having higher density of imaging devices per wafer. This leads to sharper images due to more imaging sensors, or to smaller IC chips for the same sensitivity of imager. 
     Many other problems and disadvantages of the prior art will become apparent when schooled in the art after comparing such prior art with the present invention described herein. 
     SUMMARY OF THE INVENTION 
     Various aspects of the invention may be found in a light imager. The light imager is contained on an integrated circuit (IC) chip or die. The light imager has one or more light sensors. Each of the light sensors has a light sensing element and control circuitry. 
     In the individual light sensors, the control circuitry is communicatively coupled to the light sensing element and controls the functions of the light sensing element. The control circuitry is substantially disposed within the IC chip, freeing the additional top area of the die for the light sensing elements. 
     In an alternative embodiment, the light imager has a processing circuitry. The processing circuitry is communicatively coupled to the one or more light sensors. The processing circuitry may also have an application program executing on it. 
     The placement of the control circuitry within the IC chip allows for a higher fill factor associated with each light sensor. As such, the fill factors of the light sensors can be greater than 50%. 
     The control circuitry of the invention may be such things as a reset transistor or an amplifier transistor. These components may be manufactured within the IC chip. 
     In another embodiment of the invention, a light imager is contained on an integrated circuit die. The light imager has one or more light sensors, the light sensors having a fill factor, or a ratio of the area used for collection of light to the total area of the light sensor. 
     The light sensors have a light sensing element and a control circuitry. The control circuitry is communicatively coupled to the light sensing element, and controls the operation of the light sensing element. Additionally, at least some of the control circuitry is disposed within the integrated circuit die. 
     In another exemplary embodiment of the invention, the light imager is contained on an integrated circuit chip. The light imager has one or more light sensors. The light sensors have control circuitry coupled to the light sensing elements. 
     Each of the light sensors is disposed on a corresponding sensor area on the integrated chip. The sensor area has a light sensing area, where the light is collected by a light sensing element. The light sensing area makes up at least 50% of the sensor area. 
     The light sensor may also have a processing circuitry communicatively coupled to the one or more light sensors. Additionally, the light sensor may also have an application program executing on the processing circuitry. 
     Aspects of the invention may also be found in a light sensor. The light sensor is disposed on and within an integrated circuit chip. The light sensor has a fill factor, meaning the ration of the area used for light collection to the total area of the sensor. The light sensor has a light sensing element and control circuitry. The control circuitry is communicatively coupled to the light sensing element and controls the output of the light sensing element. The control circuitry is disposed substantially within the integrated circuit chip. As such, the fill factor of the light sensor is at least 50%. Portions of the control circuitry that may be disposed within the IC chip are a reset transistor and an amplifier transistor, among others. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a block diagram of an imaging device according to the invention comprising a plurality of vertically oriented light sensor elements disposed about the imaging device. 
     FIG. 2 is a cutaway vertical schematic view of an exemplary light sensor of FIG. 1 detailing the minimization of usage of surface area on the die occupied by the control circuitry. 
     FIGS. 3 a  and  3   b  are schematic diagrams illustrating a particular embodiment of the light sensor of FIG.  2 . 
     FIG. 4 is a cutaway vertical schematic diagram of an alternative imaging sensor of FIG.  1 . 
     FIGS. 5 a  and  5   b  are schematic diagrams illustrating an exemplary embodiment of the light sensor of FIG.  4 . 
     FIGS. 6 a  and  6   b  are schematic diagrams illustrating another exemplary embodiment of the light sensor of FIG.  4 . 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     FIG. 1 is a block diagram of an imaging device according to the invention comprising a plurality of vertically oriented light sensor elements disposed about the imaging device. A light imaging device  100  is disposed on an integrated circuit (IC) chip or die  120 . The light imaging device is made up of one or more light sensors  110   a-n  coupled to a processing circuitry  190 . The light sensors  110   a-n  are coupled to the processing circuitry  190  via signal lines, not labeled on the drawing. 
     The light sensors  110   a-n  are responsive to light striking them. The light sensors  110   a-n  generate a signal indicative of the light that strikes them. The signals are communicated to the processing circuitry  190 , which then creates an electronic record of the image striking the light sensors  110   a-n . The processing circuitry  190  may store the signals from the light sensors  110   a-n , and may also perform further manipulation on them. 
     The processing circuitry  190  may contain a programmable processing circuitry  180  or a memory  170 . The programmable processing circuitry may be operated through the use of an application program  160  contained in the memory  170 . Thus, the processing circuitry may adaptively process the signals from the light sensors  110   a-n.    
     The processing circuitry may be wholly or partially contained on the IC chip  120 . Or, the processing circuitry  110  may be separate from the IC chip  120 . 
     Each of the light sensors  110   a-n  are contained in an area of the die  120 . The area utilized by each of the light sensors  110   a-n  can be broken into two different components. The light sensing areas  112   a-n  act to capture the light striking those areas and produce a signal indicative of that light. Typically, the light sensing area  112   a-n  each are occupied by a light sensing element, such as a photodiode. The remainder of the area occupied by the light sensors  110   a-n , noted as the areas  114   a-n , typically contain circuitry controlling the actions and responses of the light sensing elements. 
     In a conventional light sensor, the fill factor, or the ratio of the light sensing area to the total area occupied by a single light sensor can be as low as 15%. Other light sensors approach a fill factor of 40%. 
     In the present invention, the ratio of the light sensing area to the total area occupied by a single light sensor is 50% or above, due to the removal of much of the control circuitry away from the surface of the IC chip. The majority of the elements that do not collect the light are moved interior to the die  120 . As such, most of the area on the surface of the die  120  in which the imaging sensor is placed can be used by the actual light sensor. 
     Thus, when portions of the control circuitry are removed to the interior of the die  120 , the light sensors  110   a-n  may be placed on the die in a higher density. This allows for either a smaller die for the same efficiency, or for a more granulated image for IC chips with the same amount of area. 
     FIG. 2 is a cutaway vertical schematic view of an exemplary light sensor of FIG. 1 detailing the minimization of usage of surface area on the die occupied by the control circuitry. A light sensor  210  is contained on and within an IC chip  220 . The light sensor  210  comprises a light sensing element  230  coupled to a control circuitry  240 . 
     The light sensing element  230  is a device that responds to light striking it. In response to the light striking the light sensing element  230 , it generates a signal indicative of the intensity of that light striking. The control circuitry  240  controls the transfer of the signals generated by the light sensing element  230  to the processing circuitry, not shown in this figure. 
     The control circuitry  240  may control several aspects of the functionality of the light sensing elements  230 . For example, control circuitry  240  may contain circuitry for enabling or gating the passage of the signal generated by the light sensing element  230  to the processing circuitry. Or, the control circuitry  240  may amplify the signal generated by the light sensing element  230  as light is striking it. Or, the control circuitry  240  can reset the amplifier mentioned above. 
     The control circuitry  240  is formed beneath the surface of the integrated circuit chip  210 , as,indicated in FIG.  2 . Placing the control circuitry  240  within the integrated circuit chip  210  rather than on the surface of the integrated circuit chip enhances the functionality of the image device. More surface area is available for light acquisition, rather than sacrificing precious surface for control functionality. As such, the densities of imaging sensors can be greatly increased, leading to the benefits of greater granularity and/or greater color discrimination in the imaging device, or smaller chip sizes. 
     FIGS. 3 a  and  3   b  are schematic diagrams illustrating a particular embodiment of the light sensor of FIG.  2 . FIG. 3 a  is a top plan view of a layer of an IC chip  300  containing a light sensor  310 . The light sensor  310  is disposed on multiple layers in the substrate of the IC chip  300 . The topmost layer of the light sensor  310  is a light sensing element, in this case a photodiode  320 . 
     FIG. 3 b  is a planar view of an interior layer of the IC chip of FIG. 3 a , showing the control circuitry of the light sensor  310  disposed within the IC chip  300 . The control circuitry of the light sensor  310  can be such elements as a reset transistor  330 , an amplification transistor  340 , a memory select transistor  350 , a selection transistor  360 , and a storage element  370 . 
     The photodiode  320  is connected to the reset transistor  330  through an interconnect  380 . The reset transistor  330  allows a processing circuitry (not shown) to clear the photodiode  310  after the signal indicative of the light striking the photodiode  320  has been read and/or transferred. 
     The photodiode  320  is also connected to an amplification transistor  340 , also through an interconnect  390 . Additional control components for the light sensor  310  comprise a memory select transistor  250 , a selection transistor  360 , and a storage element  370 . 
     The control circuitry of the light sensor  310 , in this case the reset transistor  330 , the amplification transistor  340 , the select transistor  350 , the storage element  370 , and/or the memory select transistor  360  are contained within the substrate of the IC chip  300 . As such, the control circuitry for the light sensor  310  resides within the die  300 , and is disposed below the light sensing element  320 , or offset from it and interior to the chip  300 . 
     Thus, a light sensor with a high fill factor is through placing the control components of the light sensor away from the light detecting surface is shown. 
     However, the entirety of the control circuitry for a light sensor need not exist solely beneath the surface of the die to gain the added benefits of the invention. Small proportions of the control circuitries for a light sensor may co-exist on the surface of the die with the light sensing elements. 
     FIG. 4 is a cutaway vertical schematic diagram of an alternative imaging sensor of FIG. 1. A light sensor  410  is contained on and within an IC chip  420 . The light sensor  410  comprises a light sensing element  430  coupled to a control circuitry  440  and a control circuitry  450 . 
     The light sensing element  430  is a device that responds to light striking it. In response to the light striking the light sensing element  430 , it generates a signal indicative of the intensity of that light striking. The control circuitries  440  and  450  control the transfer of the signals generated by the light sensing element  430  to the processing circuitry, not shown in this figure. 
     The control circuitries  440  and  450  control several aspects of the functionality of the light sensing elements  430 . For example, the control circuitries  440  and  450  may contain circuitry for enabling or gating the passage of the signal generated by the light sensing element  430  to the processing circuitry. Or, the control circuitries  440  and  450  may amplify the signal generated by the light sensing element  430  as light is striking it. Or, the control circuitries  440  and  450  can reset the amplifier mentioned above. 
     The control circuitry  440  is formed beneath the surface of the integrated circuit chip  410 , as indicated in FIG.  4 . Placing the control circuitry  440  within the integrated circuit chip  410  rather than on the surface of the integrated circuit chip enhances the functionality of the image device. More surface area is available for light acquisition, rather than sacrificing precious surface for control functionality. As such, the densities of imaging sensors can be greatly increased, leading to the benefits of greater granularity and/or greater color discrimination in the imaging device. 
     The additional control circuitry  450  is placed on the surface or topmost layer of the IC chip  410  in conjunction with the light sensing element  430 . The additional control circuitry  450  placed on the level of the light sensing element should be minimal, allowing for as high a fill factor as possible. In order to fully take advantage of the present invention, a good proportion of the control circuitry should be placed within the IC chip, preferably allowing a fill factor of 50% or greater. 
     FIGS. 5 a  and  5   b  are schematic diagrams illustrating an exemplary embodiment of the light sensor of FIG.  4 . FIG. 5 a  is a top plan view of a layer of an IC chip  500  containing a light sensor  510 . The light sensor  510  is disposed on multiple layers in the IC chip substrate  510 . The topmost layer of the light sensor  510  is a light sensing element, in this case a photodiode  520 . Also present is a reset transistor  530 , coupled to the light sensing element 
     FIG. 5 b  is a planar view of an interior layer of the IC chip of FIG. 5 a , showing a control circuitry of the light sensor  510  disposed within the IC chip  500 . The control circuitry of the light sensor  510  can be such elements as an amplification transistor  540 , a memory select transistor  550 , a selection transistor  560 , and a storage element  570 . 
     The photodiode  520  is connected to the reset transistor  530  on the surface of the IC chip  500 . The reset transistor  530  allows a processing circuitry (not shown) to clear the photodiode  520  after the signal indicative of the light striking the photodiode  520  has been read and/or transferred. 
     The photodiode  520  is also connected to an amplification transistor  540 , interior to the IC chip  500 . The photodiode  520  is connected to the amplification transistor  540  through an interconnect  580 . Additional control components for the light sensor  510  comprise a memory select transistor  550 , a selection transistor  560 , and a storage element  570 . 
     Most of the control circuitry of the light sensor  510 , in this case, the amplification transistor  540 , the select transistor  550 , the storage element  570 , and/or the memory select transistor  560  are contained within the IC chip  500 . As such, the control circuitry for the light sensor  510  resides within the die  500 , and is disposed below the light sensing element  520 . However, the control circuitry may also be disposed in the die  500  offset from the light sensing element  520 . Thus, a light sensor with a high fill factor is through placing most of the control components of the light sensor away from the light detecting surface is shown. 
     In another exemplary embodiment of the invention, the amplification transistor  540  could be placed on the surface of the IC chip  500  and connected to the remainder of the control circuitry through an interconnect. However, this arrangement would result in one more interconnect for the light sensor  510 . 
     FIGS. 6 a  and  6   b  are schematic diagrams illustrating another exemplary embodiment of the light sensor of FIG.  4 . FIG. 6 a  is a top plan view of a layer of an IC chip  600  having a substrate  610  and containing a light sensor  610 . The light sensor  610  is disposed on multiple layers in the IC chip substrate  610 . The topmost layer of the light sensor  610  is a light sensing element, in this case a photodiode  620 . Also present is a reset transistor  630  and an amplification transistor  640 , each coupled to the light sensing element  620 . 
     FIG. 6 b  is a planar view of an interior layer of the IC chip of FIG. 6 a , showing a control circuitry of the light sensor disposed within the IC chip  600 . The control circuitry of the light sensor  610  can be such elements as a memory select transistor  650 , a selection transistor  660 , and a storage element  670 . 
     The photodiode  620  is connected to the reset transistor  630  within the IC chip  600 . The reset transistor is coupled to the photodiode  620  through an interconnect  580 . The reset transistor  630  allows a processing circuitry (not shown) to clear the photodiode  620  after the signal indicative of the light striking the photodiode  620  has been read and/or transferred. 
     The photodiode  620  is also connected to an amplification transistor  640  present on the same level of the IC chip  600  as the photodiode  620 . Additional control components are coupled in turn to the amplification transistor  640 . These additional control components can comprise a memory select transistor  650 , a selection transistor  660 , and a storage element  670 . 
     However, the additional control components, namely the memory select transistor  650 , the selection transistor  660 , and the storage element  670  are present on a different level apart from the amplification transistor  640  and the photodiode  620 . These components are manufactured within the IC chip  600 . These other control components are coupled to the amplification transistor  640  through an interconnect  690 . 
     Most of the control circuitry of the light sensor  610 , in this case, the select transistor  650 , the storage element  670 , and/or the memory select transistor  660  are contained within the IC chip  600 . As such, the control circuitry for the light sensor resides within the die  600 , and is disposed below the light sensing element  620 .