The present invention relates to a method of driving an image sensor (for example, a linear contact image sensor) for reading images in a facsimile, image scanner, digital copying machine, X-ray imaging apparatus, or the like and, more particularly, to removal of fixed pattern noise (FPN) arising from inter-chip differences or deviations in a contact image sensor in which a plurality of semiconductor photosensor chips are mounted on a mounting substrate.
In recent years, in the field of linear photo-electric conversion devices, an equal-magnification (magnification=1) contact image sensor in which a plurality of semiconductor photosensors are mounted has been extensively developed in addition to CCDs using reducing optics.
The output from one sensor module is externally output via an analog switch 37.
As shown in
In the image sensor, since fixed pattern noise (FPN) resulting from variations of the amplifier elements used for a plurality of pixels is produced, FPN produced in the chip is removed by calculating the difference between a light signal (S signal) and noise signal (N signal) in a dark state (to be referred to as an “S-N method” hereinafter for the sake of simplicity) in the prior art shown in
FPN removal using the S-N method in the image sensor shown in
In
Upon irradiation of light onto the sensor 9 of the photo-electric conversion element, a light signal (i.e., a charge) corresponding to its light amount hν (h is a Planck constant, and ν is the frequency of the light) is accumulated on the PN junction of the emitter-follower transistor 9. Upon completion of accumulation, the transistor 9 is set in a floating state (by turning off φERS), and φTS is turned on to transfer the charge accumulated on the PN junction to the light signal holding capacitance CTS1. Subsequently, a reset pulse φERS is turned on to reset the sensor (transistor 9). At this time, the charge transferred to the capacitance CTS1 contains noise components. After that, φTN is turned on to transfer a noise (N) signal of the sensor to the noise signal holding capacitance CTN2. Again, a reset pulse φBRS is turned on to enable a MOS transistor 29, and the reset pulse φERS is turned on to enable a MOS transistor 30. Since the MOS transistors 29 and 30 are ON, the sensor transistor 9 is reset and then starts the next accumulation.
Some components of the charges accumulated on the CTS1 and CTN2 are respectively shifted to the output line capacitances CHS and CHN during the next accumulation. This operation is called “capacitive division” for the sake of simplicity since the original charges accumulated on CTS1 and CTN2 are divided as a result of movement of the charges between the two capacitances. The “capacitive division” is activated by the MOS transistors 25 and 26 when a control timing signal φN is ON. The “capacitive division” will be explained below.
In order to reset holding capacitances CHS 7 and CHN 8, MOS transistors 5 and 6 are turned on by a signal φHC. After these capacitances are reset, the MOS transistors 25 and 26 are turned on by the timing signal φN output from a shift register (not shown). When the MOS transistors 25 and 26 are ON, data in the light signal holding capacitance CTS1 and noise signal holding capacitance CTN2 (some components of charges) are respectively transferred to the capacitances CHS7 and CHN 8, connected to the common output lines 3 and 4. Consequently, the potential that appears on the output line 3 (4) is determined by the ratio between the capacitances CHS 7 and CTS 1 (the ratio between CHN 8 and CTN 2). The potential on the output line 3 (4) is amplified by the differential amplifier 33 via an amplifier 13a (13b).
Although not shown in
By repeating such shift operation, the charges accumulated on the sensors (transistors 9) of the respective bits are read out to the capacitances CHS 7 and CHN 8. Voltages induced on the capacitances CHS 7 and CHN 8 are input to the differential amplifier 33 via the voltage-follower amplifiers 13a and 13b.
Fixed pattern noise FPN in the sensor IC mainly arises from variations of hFE or the like of the bipolar transistors 9 of the respective pixels (bits). Such variations are reflected in the charges accumulated on the holding capacitances CTS and CTN. FPN removal using the S-N method removes noise resulting from hFE variations of the bipolar transistors 9 in units of pixels by detecting any level differences between the signal lines by the differential amplifier 33 upon reading out the charges accumulated on the holding capacitances CTS and CTN onto the common signal lines 3 and 4.
The S-N method using the differential amplifier 33 is effective for removing FPN produced in the sensor chip.
However, in case of the equal-magnification contact image sensor in which a plurality of photosensors are mounted, since a plurality of linear line sensor chips are cascade-connected, as shown in
The above-mentioned S-N method is not effective for inter-chip FPN.
In the image sensor shown in
However, the present inventors found that it is difficult to remove inter-chip FPN arising from the offsets of the output buffer amplifier 36 even by the prior art technique shown in
Especially, when the initial stage of the output buffer amplifier 36 adopts a MOS top arrangement (in which the MOS transistor is located on the input side), since threshold value unbalance of that MOS influences the offsets, offset variations of, e.g., around 10 mV are produced among the output buffer amplifiers 36 of different chips. Even after a plurality of sensor chips are mounted, as shown in
Hence, when a high-gradation image is to be obtained using the conventional image sensor, dark correction is required in units of chips to assure its dynamic range, and the cost required for system design and manufacture increases.
In the prior art, each sensor chip includes a large-scale analog circuit such as a sensor, holding capacitances, and the like, and 10 to 20 chips are mounted. For this reason, the chip area for the analog circuit portion increases, and it is hard to reduce cost.
Furthermore, each sensor chip includes both a digital circuit such as MOS transistors for light signal read and reset, and the aforementioned analog circuit, and the sensor output is readily influenced by noise produced by the digital circuit.
It is an object of the present invention to provide a high-performance image sensor which can remove FPN arising from inter-chip variations and does not require any dark correction.
It is another object of the present invention to provide an inexpensive image sensor which can obviate the need for any dark correction means, and can avoid an increase in cost resulting from an increase in chip area, which is inevitable in the prior art.
It is still another object of the present invention to provide a drive method that can remove inter-chip FPN in an image sensor.
It is still another object of the present invention to provide an image sensor and its drive method, which can simultaneously remove intra-chip FPN and inter-chip FPN.
It is still another object of the present invention to provide an image sensor in which a plurality of sensor chips are mounted on a single mounting substrate, and a circuit for removing inter-chip FPN is mounted on a semiconductor substrate different from that of the plurality of sensor chips.
It is still another object of the present invention to provide an image sensor in which a power supply for a plurality of sensor chips is isolated from that for a circuit on the semiconductor substrate.
It is still another object of the present invention to provide an image sensor in which ground for a plurality of sensor chips is isolated from that for a circuit on the semiconductor substrate.
It is still another object of the present invention to provide an image sensor in which differential amplifiers are removed from individual sensor chips.
It is still another object of the present invention to provide an image sensor which can adjust gain and can remove individual differences of image sensor assemblies, and its drive method.
The arrangement, operation, and drive method of an image sensor according to the preferred embodiments of the present invention will be explained hereinafter with reference to the accompanying drawings.
Note that parts such as capacitances, resistors, and the like (not shown) are also mounted on the assembly 300 shown in
In
In
Note that the photo-electric converter 10, 10′, 10″, . . . preferably use bipolar elements such as, e.g., BASIS, or amplifiers each consisting of a photo-diode and MOS transistor.
The signal holder preferably comprises a capacitor, as shown in
Each of the photo-electric converters 10, 10′, 10″, . . . is connected to a pair of MOS transistors 27 and 28. An array of MOS transistors 27 commonly receive a control signal φTS. An array of MOS transistors 28 commonly receive a control signal φTN. When a transfer pulse φTS is turned on, S signals are stored in the S signal holders (capacitances) CTS 1, 1′, 1″, . . . ; when a transfer pulse φTN is turned on, N signals are stored in the N signal holders (capacitances) CTN 2, 2′, 2″, . . . . That is, when the transfer pulses φTS and φTN are turned on, the S and N signals detected by the photo-electric converters 10, 10′, 10″, . . . are respectively stored in the holders CTS 1, 1′, 1″, . . . , and the holders CTN 2, 2′, 2″, . . . .
In order to supply the outputs from the photo-electric converters 10, 10′, 10″, . . . onto the common output lines 3 and 4, the common output lines 3 and 4 must be reset before that. The MOS transistors 5 and 6 are turned on to reset the S and N signal output lines 3 and 4. Upon being reset in this way, the lines 3 and 4 are ready to transfer data to the capacitances CHS 7 and CHN 8. The MOS transistors 25 and 26 are then enabled using a shift pulse φ1 of a shift register SR to output data (charges) in the capacitances CTS and CTN in turn onto the common output lines 3 and 4 by capacitance division. Some components of the charges accumulated on CTS and CTN are respectively transferred to the capacitances CHS 7 and CHN 8. As a result, the charge accumulated on CTS is divided into CTS 1 and CHS 7, and the charge accumulated on CTN is divided into CTN 2 and CHN 8. When the charge is divided into two capacitances, the potential between these two capacitances will be referred to as the capacitively divided output in this specification.
The capacitively divided outputs are impedance-converted by amplifiers 11 and 12, and are then output onto the S and N signal lines 101 and 102 on the mounting substrate via analog switches 14 and 15. In
Data detected by the sensor element 10 is output onto the S and N signal lines 101 and 102 in response to a shift pulse φ1, as described above. Next, data detected by the sensor element 10′ is similarly output onto the S and N signal lines 101 and 102 in response to a shift pulse φ2. Furthermore, data detected by the sensor elements 10″ is output onto the S and N signal lines 101 and 102 in response to a shift pulse φ3.
The sensor module (100, 100′, 100″, . . . ) as a semiconductor photosensor is connected to the S and N signal lines 101 and 102 and one amplifier chip 200 mounted on a single mounting substrate via terminals 99 mounted on the same mounting substrate by wire bonding. That is, S and N signals from the sensor modules (100, 100′, 100″, . . . ) are input to the amplifier chip 200.
The amplifier chip 200 shared by the plurality of sensor modules (100, 100′, 100″, . . . ) has a buffer amplifier 201 for receiving an N signal, a buffer amplifier 202 for receiving an S signal, a differential amplifier 203 for calculating the difference between the outputs from the amplifiers 201 and 202, a voltage clamping circuit 204 connected to the output side of the differential amplifier 203, and an output buffer amplifier 205, as shown in
Note that the voltage clamping circuit 204 comprises a clamping capacitance 206, and a MOS switch 207, and has a function of clamping the input signal toward a clamping reset voltage VCD.
The characteristic features of the first embodiment shown in
I: The clamping circuit 204 for removing inter-chip FPN is mounted outside the plurality of sensor chips 100, . . . but inside the amplifier chip 200 as a circuit common to these sensor chips. For this reason, clamping circuits (204 in
II: In order to effectively remove inter-chip-FPN, the generation timing of a signal φCHR for controlling the reset timing of the output lines 3 and 4 and the generation timing of a signal φCD for controlling the clamping circuit 204 are appropriately set. Two examples of the generation timings of φCHR and φCD will be explained later.
III: Since the differential amplifier 203 for differentially amplifying the outputs from the pair of common output lines 3 and 4 is mounted inside the amplifier chip 200, the number of differential amplifiers which are required in units of chips in the prior art (
IV: As a combined effect of the features I to III, the timings set in II can remove not only “inter-chip FPN” but also “intra-chip FPN” at the same time.
According to the arrangement shown in
The drive control method for the image sensor of the first embodiment, especially, the drive control-method for removing inter-chip FPN will be explained below with reference to
V: to output the clamping pulse φCD before each shift pulse φN (one of φ1, φ2, φ3 . . . ); and
VI: to reset the MOS transistors 5 and 6 before the clamping pulse φCD is output.
In the control timing example shown in
The operation of the circuit shown in
After signals φTN and φTS are input, S signals have already been read out to the capacitances CTS 1, 1′, 1″, . . . , and N signals to the holding capacitances CTN 2, 2′, 2″, . . . . Read-out signals (shift pulses) φ1, φ2, φ3, . . . are output in turn from the shift register SR, and sensor detection signals are read out onto the signal lines 3 and 4 by capacitance division between the capacitances CTS and CHS, and between CTN and CHN, as described above.
In
Modification of Control Timings
The control timings of the clamping circuit 204 of the first embodiment are not limited to those shown in
According to the first embodiment, since the need for a differential amplifier in each sensor chip can be obviated as compared to the image sensor shown in
Modification of First Embodiment
In the image sensor assembly 300 of the first embodiment, when the power supply for the sensor chips 100, 100′, 100″, . . . and that for the amplifier chip 200 are independently set, a broad dynamic range of the output can be maintained even when the sensor power supply voltage is decreased.
In the first embodiment, a contact image sensor using a plurality of line sensor chips has been exemplified. However, the present invention is not limited to such specific sensor, but may be effective for a two-dimensional area sensor including a large number of sensor chips. Especially, when area chips in small regions have different photo-electric conversion sensitivities, FPN variations become more conspicuous than a 1-line contact sensor and, hence, it is very effective to apply the present invention.
As another modification, when an amplification function is added to the amplifier chip 200, the amplification function may be added to, e.g., the differential amplifier 203 or a gain amplifier may be inserted on the output side of the differential amplifier 203.
In the arrangement shown in
As other building elements of the second embodiment, each sensor chip has N signal holders 2, 2′, 2″, . . . , S signal holders 1, 1′, 1″, . . . , an N signal output line 4, an S signal output line 3, and reset switches 5 and 6, as in the first embodiment (
The characteristic feature of the second embodiment lies in that the level of a final output VOUT of a sensor assembly 300 can be adjusted by adding a gain amplifier 208 to an amplifier chip 200′. However, when the gain amplifier 208 is added, the output VOUT of the assembly 300 suffers an individual difference due to individual offset variations in the gain amplifier 208. Such individual difference will be referred to as an “inter-assembly FPN” hereinafter for the sake of simplicity.
In the image sensor of the second embodiment, a clamping circuit 209 is added to remove this “inter-assembly FPN”.
The arrangement of the image sensor of the second embodiment will be described in more detail below.
The capacitively divided outputs that appear on the N and S signal output lines 4 and 3 are impedance-converted by source-follower amplifiers 11 and 12 each including two transistors, and are then output onto S and N signal lines 101 and 102 via analog switches 14 and 15. S and N signals on the S and N signal lines 101 and 102 are input to the amplifier chip 200′ mounted on the same chip as the sensor chips.
The amplifier chip 200′ of the second embodiment comprises an N signal input buffer amplifier 201, S signal input buffer amplifier 202, differential amplifier 203, voltage clamping circuit 204, gain amplifier 208 (gain=A), voltage clamping circuit 209, and output buffer amplifier 205. A clamping control signal to the voltage clamping circuit 204 is φCD as in the first embodiment, and a clamping signal for controlling the voltage clamping circuit 209 is φCL.
The clamping signal φCD to the clamping circuit 204 must be generated at the charge transfer timing (φ1, φ2, and φ3 in
In the second embodiment, the voltage clamping circuit 209 reduces offset variations (“inter-assembly FPN”) for each module including the sensor chips 100, 100′, 100″, . . . , and the amplifier chip 200′, and a nearly uniform reference level of the module (i.e., the assembly) can be maintained. Since variations of the module (i.e., the assembly) can be reduced, variations in units of products can be reduced, and the manufacture of high-quality products can be achieved.
In the second embodiment, the power supplies and GND terminals for the sensor chips 100, 100′, 100″, . . . , and amplifier chip 200′ are isolated from each other on the mounting substrate, and the power supply voltages for the sensor chip and amplifier chip are respectively 3.3 V and 5.0 V.
The operation of the second embodiment will be described below with reference to the timing chart in
After signals are read out to the S signal holding capacitances (holders) CTS 1, 1′, 1″, . . . , and N signal holding capacitances (holders) CTN 2, 2′, 2″, . . . , read-out signals φ1, φ2, φ3 . . . are output in turn from the shift register SR, and signals detected by the photosensors are read out by capacitance division between CTS and CHS, and between CTN and CHN. Immediately before these signals are read out, capacitances CHS 7 and CHN 8 are reset to desired voltages by turning on the MOS transistors (switches) 5 and 6 in response to the reset pulse φCHR. After CHS 7 and CHN 8 are reset, the clamping circuits 204 and 209 enabled by the clamping signals φCD and φCL generate reference signals. Hence, the outputs after capacitance division contain variations caused by a threshold voltage Vth of the source-follower amplifiers 11 and 12 in units of chips. However, since the outputs are obtained after Vth variations are corrected by the above-mentioned operations of the reset pulses and the like, inter-chip FPN that has posed a problem in the prior art can be removed. That is, in the second embodiment as well, the problem of “inter-chip FPN” can be solved.
In this way, the second embodiment can remove all of “intra-chip FPN”, “inter-chip FPN”, and “inter-assembly FPN”.
More specifically, the inter-chip difference is around 10 mV in the conventional module, but is 3 mV or less in the second embodiment.
Note that φCD for controlling the clamping timing of the clamping circuit 204 is generated at the first bit in the second embodiment, but may be generated in synchronism with the generation timings of other bits.
In the third embodiment, the arrangement of each of the sensor chips 100, 100′, 100″, . . . is substantially the same as that in the second embodiment, i.e., comprises photo-diodes 20, 20′, 20″, . . . , reset switches 21, 21′, 21″, . . . , NMOS source-follower transistors 22, 22′, 22″, . . . , transfer switches 23, 23′, 23″, . . . , N signal holders 2, 2′, 2″, . . . , and S signal holders 1, 1′, 1″, . . . , except that N and S signals are time-serially (time-divisionally) read out onto a single common output line 55. That is, the single common output line 55 is sequentially reset by a reset MOS transistor 56. Since time-division driving is done, the number of source-follower amplifiers 11 including two transistors for amplifying N and S signals can be reduced to one as compared to the second embodiment.
An amplifier chip 200′ of the third embodiment comprises an input buffer amplifier 201, voltage clamping circuit 204, gain amplifier 208, voltage clamping circuit 209, and output buffer amplifier 205 as in the second embodiment. That is, the reason why the voltage clamping circuit 209 is added in the third embodiment is to remove “inter-assembly FPN” as in the second embodiment.
After signals are read out to the S signal holding capacitances (holders) CTS 1, 1′, 1″, . . . , and N signal holding capacitances (holders) CTN 2, 2′, 2″, . . . , the common output line is reset by φCHR, and an N signal for the first bit is read out by capacitance division onto the common output line 55 in response to φ1N The read-out state of the N signal is clamped in response to φCD, and is used as a reference signal for the first bit. Subsequently, the common output line 55 is reset by φCHR, and an S signal for the first bit is read out by capacitance division onto the common output line 55 in response to φ1S. The difference between the S signal for the first bit and a voltage clamped to the N signal is input to the gain amplifier 208 via the signal input buffer amplifier 201, and variations in units of pixels can be removed by this clamping function. In addition, variations of the sensor chips 100, 100′, 100″, . . . can be removed. Likewise, signals for the second and third bits are read out, and after all the bit pixel signals of the sensor chip are read out, a switch 14 of that sensor chip output is turned off and a signal for the first bit of the next sensor chip is read out.
In the arrangement of the third embodiment, inter-chip FPN is 2.9 mV or less; the FPN removal effect can be improved.
Note that φCD for controlling the clamping timing of the clamping circuit 204 is generated at the first bit in the third embodiment, but may be generated in synchronism with the generation timings of other bits.
According to the present invention, a method of driving a high-performance contact image sensor which can remove inter-chip FPN without requiring any dark correction can be provided. More specifically, since the output is clamped using as a reference signal the level obtained upon resetting the common output lines after signals are output from each sensor module to the amplifier chip, a reference potential can be obtained in the final state of photo-electric conversion, thus reliably removing FPN. Of course, since the dynamic range can be maximized, the need for dark level correction means can be obviated. Also, since the state immediately after the common output lines are reset is used as a reference potential for the clamping circuit, the clamping circuit can clamp at a reliable level in correspondence with a stable reset level, thus removing FPN for each chip.
Furthermore, since variations in units of output lines in the capacitively divided outputs from each photo-electric conversion chip can be corrected in units of chips, FPN can be removed as a whole.
According to the present invention, a method of driving a high-performance contact image sensor which can remove inter-chip FPN without requiring any dark correction can be provided. More specifically, since the level obtained upon resetting the common output lines after signals are output from each sensor module to the amplifier chip is clamped as a reference signal, a reference potential can be obtained in the final state of photo-electric conversion, thus reliably removing FPN. Of course, since the dynamic range can be maximized, the need for dark level correction can be obviated. Also, since the state immediately after the common output lines are reset is used as a reference potential for the clamping circuit, the clamping circuit can clamp at a reliable level in correspondence with a stable reset level, thus removing FPN for each chip.
As described above, the image sensor assembly 300 according to each of the first to third embodiments can be constructed by discrete circuit parts. However, the present invention is more effective when the module chips 100 and amplifier chips 200 are integrated into a single module. In other words, the image sensor of each of the first to third embodiments strongly has an aspect of a semiconductor device. In general, when the outputs from a plurality of semiconductor chips which form a module and have an identical function are combined, inter-chip FPN is produced as in the image sensor of the present invention. Hence, the FPN removal method of the present invention can be applied to such semiconductor device.
As many apparently widely different embodiments of the present invention can be made without departing from the spirit and scope thereof, it is to be understood that the invention is not limited to the specific embodiments thereof except as defined in the appended claims.
Number | Date | Country | Kind |
---|---|---|---|
9-272574 | Oct 1997 | JP | national |
9-272575 | Oct 1997 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
4584607 | Miyazawa | Apr 1986 | A |
4672453 | Sakamoto | Jun 1987 | A |
4780765 | Hamasaki et al. | Oct 1988 | A |
4835404 | Sugawa et al. | May 1989 | A |
4942474 | Akimoto et al. | Jul 1990 | A |
4965570 | Hatanaka et al. | Oct 1990 | A |
5021888 | Kondou et al. | Jun 1991 | A |
5109440 | Kawahara et al. | Apr 1992 | A |
5229848 | Sugasawa | Jul 1993 | A |
5262870 | Nakamura et al. | Nov 1993 | A |
5311320 | Hashimoto | May 1994 | A |
5321528 | Nakamura | Jun 1994 | A |
5329312 | Boisvert et al. | Jul 1994 | A |
5591960 | Furukawa et al. | Jan 1997 | A |
5592222 | Nakamura et al. | Jan 1997 | A |
5640207 | Rahmouni et al. | Jun 1997 | A |
5771070 | Ohzu et al. | Jun 1998 | A |
5907359 | Watanabe | May 1999 | A |
5933188 | Shinohara et al. | Aug 1999 | A |
6002287 | Ueno et al. | Dec 1999 | A |
6118115 | Kozuka et al. | Sep 2000 | A |
6130712 | Miyazaki et al. | Oct 2000 | A |
6184516 | Sawada et al. | Feb 2001 | B1 |
6215521 | Surisawa et al. | Apr 2001 | B1 |
6288742 | Ansari et al. | Sep 2001 | B1 |
6421085 | Xu | Jul 2002 | B1 |
20040027471 | Koseki et al. | Feb 2004 | A1 |
Number | Date | Country |
---|---|---|
0488674 | Jun 1992 | EP |
0741493 | Nov 1996 | EP |
61-214657 | Sep 1986 | JP |
62-115865 | May 1987 | JP |
3-280663 | Dec 1991 | JP |