GB2215556A - Edge-correcting image sensor - Google Patents

Abstract

An image sensor comprises a photoelectric conversion device 100 including a plurality of MOS photoelectric conversion elements arranged in a matrix pattern and a plurality of output terminals for simultaneously reading out signals of a plurality of lines and a control circuit CKD, CKG for simultaneously reading out the signals of the plurality of lines a, b, c of the photoelectric conversion device. An edge signal generating circuit 63, 64, 65, 67 receives the signals of the plurality of lines, and operates on them to generate an edge-corrected signal e. A switch 101 changes the connection between the plurality of output terminals of the photoelectric conversion device and the input of the edge signal generating circuit in correspondence with a change in combination of the lines to be read out. In a further embodiment (Fig 14) defect correction, using a ROM to store defect locations, is carried out. This image sensor has the advantage of simplicity. There is detailed explanation of the construction of the individual conversion elements (Figs 1 to 4). <IMAGE>

Description

TITLE OF THE INVENTION Image Sensing Apparatus BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to an image sensing apparatus using a photoelectric conversion element having a photoelectric charge storage region in which a potential is controlled by a capacitor.

An image sensing apparatus according to the present invention is applicable to image input devices, workstations, digital copying machines, wordprocessors, bar code readers, and automatic focusing photoelectric conversion object detection devices for cameras, video cameras, 8-mm movie cameras, and the like.

Description of the Prior Art Research on photoelectric conversion devices and in particular on solid state sensors is concentrated on CCD and MOS devices.

In a CCD sensor, a potential well is formed below a MOS capacitor electrode. A charge generated upon reception of light is stored in the well. During readout, the potential wells are sequentially operated by pulses applied to the electrodes, and the stored charges are transferred to an output amplifier. The CCD sensor therefore has a relatively simple structure, generates low noise, and allows image sensing at low illuminances.

The operation principle of a MOS sensor is as follows. Upon reception of light, charges are stored in photodiodes of p-n junctions constituting lightreceiving sections During readout, MOS switching transistors connected to the respective diodes are sequentially read out to an output amplifier. Therefore, a MOS sensor has a more complex structure than a CCD sensor. However, a MOS sensor can have a high storage capacity and wide dynamic range.

The two types of conventional sensors described above have the following drawbacks, which have prevented further improvement in resolution.

A CCD sensor has the following drawbacks.

1) Since a MOS amplifier is formed on a chip as an output amplifier, l/f noise is generated from the interface between the Si and the silicon oxide film, thus interfering with normal display. 2) When the number of cells is increased and cells are integrated at a high speed in order to provide high resolution, the maximum charge amount which can be stored in a single potential well is reduced and a wide dynamic range connot be obtained. 3) Since a CCD sensor has a structure wherein stored charges are transferred, if even a single cell fails the transferred charges stop at the failed cell. Thus, manufacturing yield is low.

A MOS sensor has the following drawbacks.

1) Since a wiring capacitance is connected to each photodiode, a large signal voltage drop occurs when a signal is read out. 2) Wiring capacitance is large, and random noise is easily generated. 3) Fixed pattern noise tends to become mixed in due to variations in the parasitic capacitance of a scanning MOS switching transistor. Hence, image sensing at low illuminances cannot be performed. When cells are reduced in size in order to allow high resolution, stored charges are reduced. However, since the wiring capacitance is not decreased very much, the S/N ratio is reduced.

Neither CCD nor MOS sensors, therefore, can provide high resolution. As a result, a semiconductor image sensing apparatus of a new type has been proposed (Japanese Laid-Open Patent Gazettes Nos. 150878/1981, 157073/1981 and 165473/1981). In an apparatus of this type, a charge generated upon light reception is stored in a control electrode (e.g., the base of a bipolar transistor, or the gate of an electrostatic induction transistor SIT or a MOS transistor). The stored charge is read out by charge amplification using the amplifying function of each cell. With this apparatus, high output, wide dynamic range, low noise, non-destructive read out, and high resolution can be provided.

However, this apparatus is based on an X-Y address system. In addition, each cell has a basic structure wherein an amplification element such as a bipolar transistor or an SIT transistor is coupled to a conventional MOS cell. These factors have limited improvements in resolution.

In an image sensing element capable of nondestructive read out, the width of a wiring for X-Y addressing must be minimized in order to guarantee a certain opening rate of the element. For this reason, the wiring capacitance is low, and the gain of the image sensing element is limited.

As shown in Fig. 15A, in a conventional edge compensation circuit an edge emphasized signal as shown in Fig. 15B is obtained using lH delay lines 60 and 61, adders 63, 65, and 66, a coefficient circuit 64, and a level adjustment resistor 67.

However, two expensive delay lines must be used, and the circuit configuration-becomes complex.

In Fig. 15B, charts a to d show waveforms of signals in odd fields; d', an output from the adder 65 in even fields; d", an edge signal of a frame image; and e", an edge emphasized signal of a frame image.

When dust or the like is mixed in the manufacturing line for conventional photoelectric conversion devices, a white or black defect is formed in the corresponding portion, thereby impairing image quality.

In view of this problem, various defect correction methods have been conventionally proposed.

For example, the defective pixel positions of each photoelectric conversion device are detected and stored in a ROM (read-only memory). When the signal is read out, a correction signal is generated to replace the corresponding signal, thereby correcting the defective pixel signal.

With this method, however, a lh delay line is required to perform the above-mentioned correction, and the circuit configuration becomes complex.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an image sensing apparatus which is free from the drawbacks of conventional image sensing apparatuses.

It is another object of the present invention to provide an image sensing apparatus which can form an image of high quality with a simple configuration.

It is still another object of the present invention to provide an image sensing apparatus which can compensate for defective pixels with a simple configuration.

In order to achieve the above objects of the present invention, there is provided according to an embodiment thereof, an image sensing apparatus comprising: a photoelectric conversion device including a plurality of photoelectric conversion elements which are arranged in a matrix pattern; control mens for simultaneously reading out signals of a plurality of lines of the photoelectric conversion device; and switching means for switching the signals of the plurality of lines at predetermined photoelectric conversion elements.

Defective pixel compensation can be performed with a simple configuration. In addition, since defective pixels are replaced with signals of adjacent pixel lines having a high vertical- correlation, image quality is improved.

According to another embodiment of the present invention, there is provided an image sensing apparatus comprising: a photoelectric convert ion device having a plurality of photoelectric conversion elements which are arranged in a matrix pattern; control means for simultaneously reading out signals of a plurality of lines of the photoelectric conversion device; and edge signal generating means for operating the signals of the plurality of lines and for forming an edge-corrected signal.

The edge-corrected signal can be generated with a simple configuration. In addition, since the edge-corrected signal is obtained from signals of adjacent pixel lines having a high vertical correlation, the inclusion in of false signals is rare.

According to still another embodiment of the present invention, there is provided an image sensing apparatus comprising: a photoelectric conversion device including a plurality of photoelectric conversion elements arranged in a matrix pattern and having a plurality of output means for simultaneously reading out signals of a plurality of lines of the photoelectric conversion device; control means for simultaneously reading out signals of a plurality of lines of the photoelectric conversion device; edge signal generating means for receiving the signals of the plurality of lines, operating the signals, and generating an edge-corrected signal; and a switch for switching, a relationship between the plurality of output means of the photoelectric conversion device and an input of the edge signal generating means, in correspondence with a change in a combination of lines to be read out.

The edge-corrected signal is generated by a simple configuration. Since the vertical correlation distance is short, inclusion of false signals is rare.

In addition, since the apparatus has a switch for switching the output lines of the photoelectric conversion device, construction of the edge signal generating means and the photoelectric conversion device is simplified.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1A is a plan view of a photosensor cell according to an embodiment of the present invention; Fig. lB is a sectional view of the cell; Fig. 2 is an equivalent circuit diagram of the cell; Fig. 3A is a graph showing read out voltage and read out time as a function of storage voltage; Fig. 3B is a graph showing the read out time as a function of the bias voltage; Fig. 4A is an equivalent circuit diagram during a refresh operation; Fig. 4B is a graph showing base voltage as a function of refresh time; Fig. 5 is a circuit diagram showing an image sensing photoelectric conversion device; Fig. 6 is a diagram for explaining the drive method of the device shown in Fig. 5; Fig. 7 is a block diagram showing an example of an image sensing apparatus; Fig. 8A is a block diagram showing the configuration of a second embodiment of the present invention;; Fig. 8B shows waveforms of signals at respective points in the circuit shown in Fig. 8A; Fig. 9 is a diagram for explaining the drive method of the second embodiment; Fig. 10 is a block diagram showing the configuration of a switch circuit 101; Fig. 11 is a table for explaining the operation of the switch circuit 101; Fig. 12 is a block diagram showing a third embodiment of the present invention; Fig. 13 is a table showing the drive method of a switch circuit 80; Fig. 14 is a block diagram showing a fourth embodiment of the present invention; Fig. 15A is a block diagram of a conventional edge compensation circuit; and Fig. 15B shows waveforms of signals at respective parts of the circuit shown in Fig. 15A.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The preferred embodiments of the present invention will be described below with reference to the accompanying drawings.

Figs. lA and lB are diagrams for-explaining the basic structure of a photosensor cell and its operation for a photoelectric conversion device according to an embodiment of the present invention.

Fig. lA shows a plan view of a photosensor cell 100 as a photoelectric conversion element, Fig. lB shows a sectional view of the structure in Fig. lA along the line A-A', and Fig. 2 shows an equivalent circuit for the structure. The same reference numerals throughout Figs. lA, lB, and 2 denote the same parts.

In Fig. 1, a plan view of an aligned array system is illustrated. However, in order to improve horizontal resolution, a pixel shifting (staggered) arrangement can be adopted.

The photosensor cell as shown in Figs. lA and lB comprises: a passivation film 2 which is formed of a PSG film or the like on a silicon substrate 1 and in which an impurity such as phosphorus (P), antimony (Sb) or arsenic (As) is doped to obtain a conductivity type of n or + an insulating oxided film 3 consisting of a silicon oxide film (SiO2); an element isolation region 4 comprising insulating films or polysilicon films consisting of SiO2 or Si3N4 for electrically isolating adjacent photosensor cells; an n -type region 5 having a low impurity concentration and formed by epitaxy; a p-type region 6, which serves as the base of a bipolar transistor obtained by the doping of an impurity with an impurity diffusion technique or an ion-implanation technique;; an n -type region 7, which serves as the emitter of a bipolar transistor formed by an impurity diffusion technique or an ion-implanation technique; a wiring 8 consisting of a conductive material such as Al, Al-Si, Al-Cu-Si or the like for the external readout of signals; an electrode 9 for applying a pulse to the floating p-type region 6; a wiring 10 for the electrode 9; an n -type region 11 having a high impurity concentration and formed by an impurity diffusion technique or the like on the rear side of the substrate 1 to obtain an ohmic contact; and an electrode 12 for providing a substrate potential and consisting of a conductive material such as aluminum to provide a collector potential for the bipolar transistor.

A contact 19 shown in Fig. lA connects the n -type region 7 and the wiring 8. The intersection of the wiring 8 and the wiring 10 is a double-wiring structure, and is insulated by an insulating region composed of an insulating material such as SiO2. Thus, a bilayered metal wiring structure is provided.

A capacitor Cox 13 in the equivalent circuit shown in Fig. 2 has a MOS structure consisting of the electrode 9, the insulating film 3, and the p-type region 6. A bipolar transistor 14 consists of the n -type region 7 as an emitter, the p-type region 6 as a base, the n -type region 5 having a low impurity + concentration, and the n or n -type region 1 as a collector. As can be seen from the accompanying drawings, the p-type region 6 is a floating region.

The second equivalent circuit shown in Fig. 2 is expressed by a base-emitter.junction capacitance Cbe 15, a base-emitter p-n junction diode Dbe 16, a base-collector junction capacitance Cbc 17, a basecollector p-n junction diode Dbc 18, and current sources 19 and 20.

The basic operation of the photosensor cell will be described below with reference to Figs. lA, lE and 2.

The basic operation of the photosensor cell involves a charge storage operation upon light reception, a read out operation1 and a refresh operation. In the charge storage operation, the emitter is grounded through the wiring 8, and the collector is biased to a positive potential through the wiring 12. The base is set to a negative potential, i.e., reverse biased with respect to the emitter region 7 by applying a positive pulse voltage through the wiring 10 to the capacitor Cox 13. Biasing to the negative potential of the base 6 by application of a pulse to the capacitor Cox 13 will be described in detail with reference to the refresh operation below.

When light 20 becomes incident on the photosensor cell shown in Fig. lB, electron-hole pairs are generated in the semiconductor. Since the n-type region 1 is biased to a positive potential, electrons flow to the side of the n-type region 1. However, holes are stored in the p-type region 6. When holes are stored in the p-type region 6 in this manner, the potential of the p-type region 6 gradually changes toward a positive potential.

Referring to Figs. lA and 1B, the lower lightreceiving surface of each cell is mostly occupied by a p-type region and is partially occupied by the n -type region 7. Naturally, the concentration of electron-hole pairs which are photo-excited increases toward the surface. Therefore, many electron-hole pairs are excited by light in the p-type region 6.

If electrons photo-excited in the p-type region 6.

If electrons photo-excited in the p-type region flow without recombination and are absorbed by the n-type region, holes excited by the p-type region 6 are stored and change the region 6 to a positive potential If the impurity concentration in the p-type region 6 is uniform, photo-excited electrons flow to the p-n junction between the p-type region 6 and the n--type region 5. Thereafter, the electrons are absorbed in the n-type collector region 1 by a drift due to a strong electric field applied to the n -type region.

Note that electrons in the p-type region 6 can be transferred by diffusion alone. However, if the impurity concentration of the p-type base is controlled to increase from the surface to the inside, an-electric field given by: Ed = (l/WB) . (kT/q) In (NAs/NAi) (where WB is the depth of the p-type region 6 from the light-incident surface, k is the Bolzmann's constant, T is the absolute temperature g is the unit charge, NAs is the surface impurity concentration of the p-type base region, and NAi is the impurity concentration at the interface between the p-type region 6 and the n -type high-resistance region 5) directed toward the surface from the inside of the base is formed in the base due to the impurity concentration difference.

If we assume that NAs/NAi > 3, transfer of electrons in the p-type region 6 is performed by drift in place of diffusion. In order to effectively obtain carriers photo excited in the p-type region 6 as a signal, the impurity concentration of the p-type region 6 preferably reduces from the light-incident surface to the inside. When the p-type region 6 is formed by diffusion, the impurity concentration reduces from the surface to the inside.

A portion of the sensor cell below the light-receiving surface is partially occupied by + + the n -type region 7. Since the depth of the n -type region 7 is normally about 0.2 to 0.3 um or less, the amount of light absorbed by the n -type region 7 is not so large and does not present a problem.

However, for light having short wavelengths, in + particular, for blue light, the presence of the n -type region 7 may lower sensitivity. The impurity concentration of the n±type region 7 is normally 1020 to be about 1 x 1020 -3 designed to be about 1 x 1020 cm or more. The diffusion distance of holes in the n -type region 7 in which an impurity is doped to a high concentration is 0.15 to 0.2 ,um. Therefore, in order to effectively flow holes photo-excited in the n -type region 7 into the p-type region 6, the n -type region 7 also referably has a structure wherein the impurity concentration decreases from the light-incident surface to the inside.When the impurity concentration of the n -type region 7 is as described above, a strong drift electric field directed from the lightincident surface to the inside is generated, and foles photo-excited in the n -type region 7 immediately flow into the p-type region 6. When the impurity concentrations of the n±type region 7 and the p-type region 6 decrease from the light-incident surface to the inside, carriers photo-excited in the n -type region 7 and the p-type region 6 at the light-incident surface side of the sensor cell all serve to generate a photo signal. When the n -type region 7 is formed by impurity diffusion from a sillicon oxide film or a polysilicon film in which As or P is doped to a high concentration, an n -type region having a preferable imprity concentration profile as described above can be obtained.

Upon storage of holes, the base potential changes to the emitter potential and then to ground level where it is clipped. More specifically, the base-emitter path is forward-biased, and clipped at a voltage at which the holes stored in the base begin to flow to the emitter. The saturation potential of the sensor cell is approximately given by the potential difference between the ground potential and the bias potential, which is used to bias the p-type + region 6 first to a negative potential. If the n -type region 7 is not grounded and a charge is stored by a photo input in the floating state, the p-type region 6 can store the charge to a potential which is substantially the same as that at the n-type region 1.

In the MOS sensor, fixed pattern noise due to variations in the parasitic capacitance of a switching MOS transistor for external read out, and random noise due to a high wiring capacitance or an output capacitance are high, and a satisfactory S/N ratio cannot be obtained. In the photosensor cell of the structure shown in Figs. lA, lB and 2, the voltage stored in the p-type region 6 is externally read out. Since the voltage is relatively high, fixed pattern noise or random noise due to output capacitance are reduced relative to the high voltage. Thus, signals with an excellent S/N ratio can be produced.

Another advantage of the photosensor cell of the above configuration is a provision of nondestructive read out of holes stored in the p-type region 6 due to a low recombination rate between electrons and holes in this region 6. When a voltage VR applied to the electrode 9 during read out is returned to zero volts, the potential of the p-type region 6 is reverse-biased as before application of the voltage VR. Thus, the stored voltage VR generated before light irradiation is maintained unless another light irradiation is performed. When the photosensor cell of the above configuration is used to constitute a photoelectric conversion device, a new system function can be provided.

A time for which the stored voltage Vp can be stored in the p-type region 6 is very long, and the maximum storage time is limited by a dark current which is thermally generated in a depletion layer at the junction. This is because the photosensor cell is saturated by a thermally generated d-ark current.

However, in the photosensor cell of the configuration described above, the region of the depletion layer is the n--type region 5 having a low impurity concen -3 -3 14 -3 tration such as about 1012 cm to 10 cm , it has a very good crystallinity and only a small number of electron-hole pairs are thermally generated as compared to a MOS or CCD sensor. Therefore, a dark current is lower than other conventional devices. Thus, the photosensor cell of above-described configuration has low noise.

Refresh operation of the charge stored in the p-type region 6 will be described below.

In the photosensor cell of the configuration described above, as described above, the charge stored in the p-type region 6 is held unless it is read out. Therefore, in order to input new optical information, refresh operation for erasing the previous charge is required. At the same time, the potential of the floating p-type region 6 must be charged to a predetermined negative potential.

In the photosensor cell having the above configuration, as in the case of read out operation, refresh operation is performed by applying a positive voltage to the electrode 9 through the wiring 10.

The emitter is grounded through the wiring 8. The collector is set at the ground potential or at a positive potential through the electrode 12.

The charge storage operation, the read out operation, and refresh operation of the photosensor cell having the above basic configuration are as described above.

Fig. 3A is a graph showing read out voltage and read out time as a function of storage voltage.

Fig. 3B is a graph showing read out time a-s a function of bias voltage.

Fig. 4A is an equivalent circuit diagram of the refresh operation, and Fig. 4B is a graph showing base voltage as a function of refresh time.

As described above, the basic structure of the photosensor cell of the above configuration is simpler that those disclosed in Japanese Laid-Open Patent Gazettes Nos. 150878/1981, 157073/1981 and 165473/1981. The structure allows high-resolution applications which are feasible in near future while it also maintains advantages of conventional structures such as low noise, high output, wide dynamic range1 and non-destructive read out.

An embodiment of a photoelectric conversion device having two arrays of photosensor cells according to the present invention will be described below.

Fig. 5 shows the configuration of a circuit of the photoelectric conversion device having a two-dimensional array (matrix) of basic photosensor cells The device has basic photosensor cells 30 (the collector of the bipolar transistor is connected to the substrate and the substrate electrode) surrounded by dotted lines; horizontal lines 31, 31', 32", ..., for applying read out pulses and refresh pulses; a vertical shift register 32 for generating read out pulses; buffer MOS transistors33, 33', 33", ..., between the vertical shift register 32 and the horizontal lines 31, 31', 31", ...,; a terminal 34 for applying pulses to the gates of the transistors 33, 33', 33", ...,; buffer MOS transistors 35, 35', 35", ..., for applying refresh pulses; a terminal 36 for applying pulses to the gates of the transistors 35, 35', 35", ...,; a vertical shift register 52 for applying refresh pulses; vertical lines 38, 38', 38", ..., and 51, 51', 51", ..., for reading out stored voltages from the basic photosensor cells 30; a horizontal shift register 39 for generating pulses so as to select the respective vertical lines; gate MOS transistors 40, 40', 40", ..., and 49, 9', 49", ....

for enabling or disabling the respective vertical lines; output lines 49 and 51 for reading out the stored voltages to an amplifier section; MOS transistors 42 and 53 for refreshing the charge stored on an output line; terminals 43 and 54 for applying refresh pulses to the MOS transistors 42 and 53, transistors (e.g., bipolar, MOS, FET, J-FET transistors) for amplifying output signals; terminals 46 and 57 for connecting load resistors 45 and 56 and the transistors 44 and 55 to a power source; output terminals 47 and 48 as an output means;MOS transistors 48, 48', 48", ..., and 50, 50', 50", ..., for refreshing the charges stored on the vertical lines 38, 38', 38", ..., and 51, 51', 51", ...,; and a terminal 49 for applying pulses to the gates of the MOS transistors 48, 48', 48", ..., and 50, 50', 50", The image sensing apparatus of the present invention comprises a clock driver CKD for supplying drive pulses to the respective portions 32, 34, 36, 39, 43, 49 and 54 of the photoelectric conversion device, and a clock generator CKG for supplying timing pulses to the clock driver CKD. The clock driver CKD and the clock generator CKG constitute the control means.

Fig. 6 is a diagram showing the drive method of the apparatus by the control means. In odd fields, line data Q1 and Q2 forms nl horizontal scanning line, line data Q3 and Q4 forms n2 horizontal scanning line, and line data Q5 and Q6 form the n3 horizontal scanning line. In even fields, line data Q2 and Q3 form the ml horizontal scanning line, line data Q4 and Q5 fprm the m2 horizontal scanning line, and line data Q6 and Q7 form the m3 horizontal scanning line.

Line data of two horizontal lines is simultaneously read out, and the read out data is produced from the output terminals 47 and 58.

Fig. 7 shows the configuration of the image sensing apparatus according to the present invention The apparatus has a photoelectric conversion device 100 as shown in Fig. 5, a switch circuit 68 for inputting the 2 line signals from the device 100 to different terminals 72 and 73 for each field, a subtracter 69, a level adjustment resistor 70, and an adder 71. This embodiment of the present invention is also applicable to a conventional X-Y address type MOS image sensor.

In an odd field, an edge signal is obtained by subtracting an output at the terminal 47 from an output from the terminal 58. After the level of the edge signal is adjusted by the resistor 70, it is added with the original signal by the adder 71 so as to obtain an edge-corrected video signal. In an even field, the output from the terminal 58 is subtracted from that from the terminal 47 to obtain an edge signal. After the level of the edge signal is adjusted by the resistor 70, it is added to the original signal by the adder 71.

The clock driver CKD switches the switch 68 for each field. According to the first embodiment of the present invention, edge correction can be performed without using a delay circuit, thereby providing a very simple circuit. APC in Fig. 7 is an edge signal generation block as a processing means or an edge signal generating means.

Fig. 8A is a block diagram showing a second embodiment of the present invention. This embodiment uses a photoelectric conversion device which simultaneously reads line information of three horizontal lines.

The same reference numerals as in Fig. 5 denote the same parts in Fig. 8A. In Fig. 8A, a clock driver circuit CKD controls a switch circuit 101.

Fig. 8B shows waveforms of the signals at the respective portions of the circuit shown in Fig. 8A.

Charts a to d show the waveforms in odd fields; d', the output waveform from an adder 65 in even field; and d", an edge signal in a frame image.

Fig. 9 is a diagram showing the wiring of the output line of a photoelectric conversion device 100 and the read out method by the clock driver.

In this embodiment, in an odd field, the clock driver simultaneously reads out lines Q1 to Q3 as the nl horizontal scanning line, lines Q3 to Q5 as the n2 horizontal scanning line, lines Q5 to t7 as the n3 horizontal scanning line, and lines Q7 to Q9 as the n4 horizontal scanning line.

In an even field, the clock driver simultanously reads out lines Q2 to Q4 as the ml horizontal scanning line, lines Q4 to Q6 as the m2 horizontal scanning line, and lines Q6 to Q8 as the m3 horizontal scanning line.

The following effect will be described by the following method. It is known that a false signal is rarely generated at an edge portion and sensitivity is improved, when vertical correlation processing is performed. In addition, edge correction is easy to perform.

Fig. 10 is a diagram showing the switch circuit 101 for establishing correspondence between output terminals O1, O2 and b3 as an output means of the device 100 and outputs a, b and c in Fig. 8A. The switch circuit 101 has an interior as shown in Fig. 10.

The clock driver CKD switches the outputs at timings which are different substantially at each field and each line, as shown in Fig. 11.

In this embodiment, since the switch circuit 101 is arranged, as shown in Fig. 8A, an edge compensation circuit need only be incorporated for one combination of the outputs a, b and c as shown in Fig. 8A. Therefore, the overall construction is simplified.

Fig. 12 is a block diagram showing a third embodiment of the present invention. The apparatus has adders 74, 76, 78 and 83, weighting circuits 75 and 79, a level adjustment resistor 77, a switch circuit 80, an intensity signal processing circuit 81 as a processing means, and a color signal processing circuit 82 as a processing means.

According to this embodiment, as in the second embodiment, edge correction be performed without using delay lines or the like, and the configuration of the switch circuit 80 can be simplified. In addition, only one series of parts 75 to 79 is required, and the wiring in the device 100 can be simplified.

Fig. 13 is a method of controlling the switching operation of the switch circuit 80. As shown in Fig. 13, when three horizontal lines are simultaneously read, the central horizontal'line is handled as an original signal, and the upper and lower line signals are delayed and advanced by 1H, respectively.

As described above, according to the embodiment of the present invention, a plurality of lines of a photoelectric conversion device for image sensing an optical image are simultaneously read, and the signals of a plurality of lines areoperated to generate an edge-corrected signal. Thus, the signal processing system is simplified extremely.

According to the above embodiment, a switch circuit is arranged for changing the combination of a plurality of line signals when they are supplied to an operation circuit. Therefore, only a single operation circuit is required, and the configuration.of the operation circuit is simplified. Connections in the photoelectric conversion device are simplified.

When a photoelectric conversion device capable of non-destructive read out is used, three or more horizontal lines can be simultaneously read out. At the same time, the signals can be read out in a partially overlapped state upon each horizontal scanning, thereby improving vertical correlation. An edge signal of second order or more can be obtained. The switch circuit can be incorporated in the photoelectric conversion device.

As described above, according to the embodiment of the present invention, an edge-corrected signal can b-e obtained with a simple configuration. Since the vertical correlation distance is small, inclusion of a false signal is rare. Since the apparatus has a switch circuit for switching the output lines of the photoelectric conversion device, the construction of the edge signal generating means and the photoelectric conversion device is simplified.

Fig. 14 shows a fourth embodiment of the present invention. In this embodiment, a defective pixel in a photoelectric conversion device can be corrected. The same reference numerals as in Fig. 13 denote the same parts in Fig. 14.

The apparatus shown in Fig. 14 has an adder 84, a weighting circuit 85, a switch 86 as a switching means, a subtracter 87, and a ROM storing the position of a defective pixel. The parts 84 to 87, 66, 67, and the like constitute a processing means.

A switch circuit 101 converts the three horizontal line signals read out from output terminals O1, 02 and O3 of the device 100 to obtain signals a, b and c as in the case of Fig. 11. The signal b is a signal of the control line of the three horizontal lines read out simultaneously from the photoelectric conversion device. The signal b contains a dropout at a pred < ter- mined pixel position.

The position of the defective pixel is prestored in the ROM 88. The ROM 88 is driven by a sync signal from a clock generator CKG. The switch 86 is switched from the x side to the y side at the position of the defective pixel. The signal b is interpolated by an average signal of the signals a and c. The adder 84 and the weighting circuit 85 are for forming.an average signal. The average signal is subjected to subtraction at the subtracter 87 to form an edge signal d. The remaining operation is the same as that described with reference to up to Fig. 13. According to this embodiment, correction of a defective pixel can be performed without using a delay line, the circuit configuration is simplified, and the image quality is improved. The manufacturing yield of the photoelectric conversion device can be improved. The dropout of the signal b can be directly detected, and the switch 86 can be detected.

According to the embodiments of the present invention, a defective pixel can be corrected by a simple circuit, and such a defective pixel is replaced with a signal of an adjacent pixel which has a high correlation.

Claims (14)

CLAIMS:

1. An image sensing apparatus comprising: a photoelectric conversion device consisting of a plurality of photoelectric conversion elements which are arranged in a matrix pattern; control means for simultaneously reading out signals of a plurality of lines of said photoelectric conversion device; and edge signal generating means for operating the signals of the plurality of lines to generate an edgecorrected signal.

2. An apparatus according to Claim 1, wherein said photoelectric conversion device has a plurality of output means for independently reading out the signals of the plurality of lines.

3. An apparatus according to Claim 1, further including means for forming a l-horizontal scanning signal using the signals of the plurality of lines which are simultaneously read out by said control means.

4. An apparatus according to Claim 1, wherein said photoelectric conversion elements include elements which are capable of non-destructive read out.

5. An image sensing apparatus including: a) a plurality of photoelectric conversion elements which are arranged in a matrix pattern; b) a plurality of output means for independently reading out signals of the plurality of lines constituted by said photoelectric conversion elements; c) processing means for processing the signals of the plurality of lines, said processing means having signal input channels numbering the same as said plurality of output means; and d) switching means for switching connections between said plurality of output means and said plurality of signal input channels.

6. An apparatus according to Claim 5, wherein said processing means forms a l-horizontal scanning signal from the signals of the plurality of lines.

7. An apparatus according to Claim 5, wherein said photoelectric conversion elements include elements which are capable of non-destructive read out.

8. An apparatus according to Claim 5, wherein said switching means switches the connections between said plurality of output means and said plurality of signal input channels every time signals of substantially all lines are read out.

9. An apparatus according to Claim 5 or 8, wherein said switching means switches the connections between said plurality of output means and said plurality of signal input channels every time signals of each line are read out.

10. An apparatus according to Claim 5, wherein said processing means performs defect correction processing.

11. An apparatus according to Claim 5, wherein said processing means generates an edge signal.

12. An apparatus according to Claim 5, wherein said processing means operates the signals of the plurality of lines.

13. An image sensing apparatus including: a) a plurality of photoelectric conversion elements which are arranged in a matrix pattern; b) a plurality of output means for independently reading out signals of the plurality of lines constituted by said photoelectric conversion elements; and c) defect correction means for processing the signals of the plurality of lines so as to form a defectcorrected signal.

14. An apparatus according to Claim 13, wherein said photoelectric conversion elements include elements which are capable of non-destructive read out.