USRE39780EExpiredUtilityPatentIndex 93
Photoelectric converter, its driving method, and system including the photoelectric converter
Est. expiryDec 27, 2013(expired)· nominal 20-yr term from priority
G01T 1/2928H04N 25/76H04N 25/78H04N 23/30H10D 86/01H10D 86/60H10F 39/803H10F 39/016H10F 39/1898H10F 30/227H10D 86/40
93
PatentIndex Score
16
Cited by
20
References
29
Claims
Abstract
A photoelectric converter of a high signal-to-noise ratio, low cost, high productivity and stable characteristics and a system including the above photoelectric converter. The photoelectric converter includes a photoelectric converting portion in which a first electrode layer, an insulating layer for inhibiting carriers from transferring, a photoelectric converting semiconductor layer of a non-single-crystal type, an injection blocking layer for inhibiting a first type of carriers from being injected into the semiconductor layer and a second electrode layer are laminated in this order on an insulating substrate.
Claims
exact text as granted — not AI-modified1. A system having a photoelectric converter comprising:
a plurality of photoelectric converting elements sections formed on a substrate, each of the photoelectric converting elements sections including a first electrode layer and a second electrode layer, an insulating layer formed between the first and second electrode layers for inhibiting a first type of carriers both of electrons and holes from passing through the layer, a semiconductor layer, and an injection blocking layer for inhibiting said first type of carriers either of electrons or holes from being injected into the semiconductor layer;
a switch section for applying an electric field to each layer of said photoelectric converting elements sections in a direction so that said first type of carriers are one type of carrier, electrons or holes, is introduced from said semiconductor layer to said second electrode layer in a refresh mode or and in a direction so that said first type of carriers the one type of carrier generated by light incident on said semiconductor layer remain in said semiconductor layer and said second type of carriers are the other type of carrier generated by light incident on said semiconductor layer is introduced to said second electrode layer in a photoelectric conversion mode; and
a signal processing means for processing signals output from connected to the photoelectric converting elements.
2. A system according to claim 1 , further comprising a record means for recording signals output from said signal processing means.
3. A system according to claim 1 , further comprising a display means for displaying signals output from said signal processing means.
4. A system according to claim 1 , further comprising a transmission means for transmitting signals output from said signal processing means.
5. A system according to claim 1 , wherein said photoelectric converter has a phosphor.
6. A system according to claim 1 , further comprising a light source for emitting light to generate optical information input to said photoelectric converter.
7. A system according to claim 6 , wherein said light source emits X-rays.
8. A method of driving a photoelectric converting element apparatus having a photoelectron converting section formed on a substrate, the photoelectric converting element and including a first electrode layer; an insulating layer for inhibiting both of two types of carriers, a first type of carriers and a second type of carriers whose positive or negative characteristics are opposite to those of the first type of carriers, from passing through the layer; a semiconductor layer including the first and second types of carriers ; an injection blocking layer for inhibiting the a first type of said carriers from being injected into the semiconductor layer; and a second electrode layer arranged adjacent to said injection blocking layer,
the driving method having a refresh and a photoelectric conversion mode, wherein an electric field is applied so that the first type of said carriers are brought from said semiconductor layer into said second electrode layer in the refresh mode, and
detecting, while an electric field is applied so that the first type of said carriers generated by light incident in said semiconductor layer remain in said semiconductor layer and thea second type of said carriers are introduced into said second electrode in the photoelectric conversion mode, and, under an influence of an electric field having the same direction as in the photoelectric conversion mode, the first and second types of said carriers stored in said semiconductor layer are detected .
9. A method according to claim 8 , wherein the photoelectric converting apparatus further comprising comprises a capacitive storing element wherein integral values depending upon said carriers are stored and read out.
10. A method according to claim 8 , wherein the photoelectric converting apparatus further comprising comprises a plurality of said photoelectric converting sections wherein the plurality of said photoelectric converting sections are electrically connected in each within a respective block and, when one of the blocks is in the photoelectric conversion mode, at least one of the other blocks is turned to the refresh mode.
11. A method according to claim 8 , wherein an electric field is applied to said photoelectric converting elements sections in said refresh mode in accordance with a condition represented by (V rG ·q<V D ·q−V FB ·q), where the product (V rG ·q) of a voltage (V rG ) of said first electrode layer in said photoelectric converting section and an electric charge (q) of said first type of carriers becomes smaller than the product (V D ·q−V FB ·q) of a voltage (V D −V FB ), the voltage subtracting a threshold voltage (V FB ) from a voltage (V D ) of said second electrode layer, and the electric charge (q) of said first type of carriers.
12. A method according to claim 9 , wherein said capacitive storing element has two electrode layers, an insulating layer held between the electrode layers and a semiconductor layer to be operated in the accumulation state.
13. A photoelectric converter having a photoelectric converting section provided on a substrate having a surface which is at least isolative , and first and second integrated circuit element groups provided outside of said photoelectric converting section, wherein:
said photoelectric converting section has plural combinations of a photoelectric converting element and a thin film transistor arranged correspondingly to said photoelectric converting element, one electrode of said photoelectric converting element is connected to a line capable of being set at a predetermined voltage, the other another electrode of said photoelectric converting element is connected to either one of the source and or drain electrodes of said thin film transistor, a gate electrode of said thin film transistor is connected to said first integrated circuit element group arranged outside of said photoelectric converting section through a driving line provided commonly to said plural combinations of a photoelectric converting element and a thin film transistor and said and second first integrated circuit element groups group for supplying to said gate electrode a signal for driving said thin film transistor, and the other of the source and drain electrodes different from the one of the source and the other of the source or drain electrodes of said thin film transistor are is connected to the second integrated circuit element group through an output line common to a group of said plural combinations of a photoelectric converting element and a thin film transistor and arranged in a direction crossing said driving line;
said photoelectric converting element has first and second electrode layers on said substrate, and has an insulating layer, between said first and second electrode layers, an insulating layer for blocking passage of a hole and an electron therethrough, a semiconductor layer, and a carrier blocking layer for blocking passage of one of the hole and the electron; and
said thin film transistor has, on said substrate, a gate electrode, and source and drain electrodes arranged in spaced relation, and has between said gate electrode and said source and drain electrodes, an insulating layer to be a gate insulating film, a semiconductor layer and an ohmic contact layer, said ohmic contact layer is arranged correspondingly to said source and drain electrodes, and said ohmic contact layer and said source and drain electrodes are provided at one side surface of said semiconductor layer.
14. A photoelectric converter according to claim 13 , wherein said first electrode layer of said photoelectric converting element, and said gate electrode of said thin film transistor, said second electrode layer of said photoelectric converting element, and said source and drain electrodes of said thin film transistor, said insulating layer on said photoelectric converting element, and said gate insulating film of said thin film transistor, said semiconductor layer of said photoelectric converting element, and said semiconductor layer of said thin film transistor, said carrier blocking layer of said photoelectric converting element, and said ohmic contact layer of said thin film transistor, are respectively, produced from the same material, and have respectively the same thickness.
15. A photoelectric converter according claim 13 , wherein said first and second integrated circuit element groups are respectively arranged at a periphery of said photoelectric converting section.
16. A photoelectric converter according to claim 13 , wherein said photoelectric converting section is quadrilateral, and said first and second integrated circuit element groups are arranged separately along sides of the quadrilateral.
17. A photoelectric converter having a photoelectric converting section provided on a substrate having a surface which is at least insolative , wherein said photoelectric converting section has in matrix arrangement plural combinations of a photoelectric converting element and a thin film transistor arranged correspondingly to said photoelectric converting element, one electrode of said photoelectric converting element is connected to a line capable of being set at a predetermined voltage, the other another electrode of said photoelectric converting element is connected to one of the source and or drain electrodes of said thin film transistor, the other of the source and or drain electrodes drain electrodes of said thin film transistor are is connected to an output line common to a group of said plural combinations of a photoelectric converting element and a thin film transistor for outputting a signal derived by a photoelectric conversion of said photoelectric conversion elements of the group, and a gate electrode of said thin film transistor is connected to a driving line common to a group of said plural combinations of a photoelectric converting element and a thin film transistor for supplying said gate electrode with a signal for driving said thin film transistors of this group in a direction crossing the output line for outputting the signal , and said photoelectric converter further comprises a passivation film provided on a group of said photoelectric conversion elements and thin film transistors, and a fluorescent body provided on said passivation film.
18. A photoelectric converter according to claim 17 , wherein said photoelectric converting element has first and second electrode layers on said substrate, an insulating layer between said first and second electrode layers for inhibiting a passage of a hole and an electron therethrough, a semiconductor layer, and a blocking layer for blocking a passage therethrough of one of the hole and the electron, in this order.
19. A photoelectric converter according to claim 18 , wherein said thin film transistor has, on said substrate, a gate electrode, separately arranged source and drain electrodes, an insulating layer to be a gate insulating film between said gate electrode and said source and drain electrodes, a semiconductor layer and an ohmic contact layer, wherein said ohmic contact layer is provided correspondingly to the source and drain electrodes, and said ohmic contact layer and said source and drain electrodes are provided at one side surface of said semiconductor layer.
20. A method for driving a photoelectric converting section which comprises a first electrode layer; an insulating layer for preventing carriers of both of two types from passing through said insulating layer, the two types of carriers being a first type of carrier and a second type of carrier whose positive or negative polarity is opposite that of the first type of carrier ; a semiconductor layer; an injection blocking layer for preventing said a first type of carrier from being injected into said semiconductor layer; and a second electrode layer disposed in contact with said injection blocking layer, said method comprising:
a refreshment refresh mode for applying an electric field for guiding said first type of carrier from said semiconductor layer toward said second electrode layer; and
a photoelectric converting mode for applying an electric field for remaining to said first type of carrier generated by incident light in said semiconductor layer and for introducing said a second type of carrier from said semiconductor layer into said second electrode layer;
wherein, according to the electric field in the direction in said photoelectric converting mode, a charge corresponding to a carrier stored in said semiconductor layer in the photoelectric converting mode is detected .
21. A method according to claim 20 , wherein:
the photoelectric converting section further comprisingcomprises a storage capacitor element, and
wherein a process for storing the carrier first type of carriers in said storage capacitor element for reading is provided.
22. A method according to claim 20 , wherein a plurality of photoelectric converting sections are provided, and are connected within a respective block that includes a respective group of the photoelectric converting sections, and, when a selected block is in the photoelectric converting mode, at least one other block is in the refreshment refresh mode.
23. A method according to claim 20 , wherein the electric field applied in the refreshment refresh mode is set to meet a condition that a product (VrG×q) of a voltage (VrG) of the first electrode layer of said photoelectric converting section and a charge (q) of the first type of carrier is not greater than a product ((VD−VFB)×q) of a voltage (VD−VFB) obtained by subtracting a threshold voltage (VFB) from a voltage (VD) of said second electrode layer and the charge (q) of the first type of carrier.
24. A method according to claim 21 , wherein said storage capacitor element comprises two electrode layers and an insulating layer sandwiched between said electrode layers.
25. A method according to claim 21 , wherein the charge corresponding to the stored carrier has a quantity of a charge flowing at the application of the electric field in the same direction as in the refreshment refresh mode.
26. A method according to claim 21 , wherein a charge quantity corresponding to the stored carrier is a charge quantity flowing in the photoelectric converting mode.
27. A method according to claim 21 , further comprising a step of subtracting from the charge corresponding to the stored carrier a charge corresponding to the stored carrier in a case of non-incident light at the photoelectric converting mode.
28. A photoelectric converter according to claim 13 , further comprising a fluorescent substance on said photoelectric converting element.
29. A photoelectric converter according to claim 13 , wherein said photoelectric converting element and said thin film transistor have thereon a passivation film, on which a fluorescent substance is provided.Cited by (0)
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