IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
US-0908347
(2001-07-18)
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발명자
/ 주소 |
- Chappo, Marc A.
- Luhta, Randall P.
- Mattson, Rodney A.
- Roos, Pieter G.
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출원인 / 주소 |
- Koninklijke Philips Electronics, N.V.
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대리인 / 주소 |
Fay, Sharpe, Fagan, Minnich & McKee, LLP
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인용정보 |
피인용 횟수 :
187 인용 특허 :
5 |
초록
▼
A CT scanner (10) includes a reconstruction processor (32) and a mosaic X-Radiation detector (20). The mosaic detector includes plural detector elements (22, 22, 23, 24, 25, 26) arranged in abutting relationship and configured for the desired imaging application. The detector elements include scinti
A CT scanner (10) includes a reconstruction processor (32) and a mosaic X-Radiation detector (20). The mosaic detector includes plural detector elements (22, 22, 23, 24, 25, 26) arranged in abutting relationship and configured for the desired imaging application. The detector elements include scintillating crystals (50) in optical communication with a back-illuminated photodiode array (52) or modified top-surface photodiode array (152, 252) for converting emitted light into electrical charge. The photodiode array is mounted on a carrier substrate (58) via bump (56) bonding. The carrier substrate provides a conductive path routing the photodiode array output through to contacts on the back side for connection to readout electronics (60). The carrier substrate and readout electronics are contained within the footprint defined by the photodiode array, allowing the detector elements to be abutted on any and all sides, thus permitting the mosaic detector to be tailored to any desired size and shape.
대표청구항
▼
A CT scanner (10) includes a reconstruction processor (32) and a mosaic X-Radiation detector (20). The mosaic detector includes plural detector elements (22, 22, 23, 24, 25, 26) arranged in abutting relationship and configured for the desired imaging application. The detector elements include scinti
A CT scanner (10) includes a reconstruction processor (32) and a mosaic X-Radiation detector (20). The mosaic detector includes plural detector elements (22, 22, 23, 24, 25, 26) arranged in abutting relationship and configured for the desired imaging application. The detector elements include scintillating crystals (50) in optical communication with a back-illuminated photodiode array (52) or modified top-surface photodiode array (152, 252) for converting emitted light into electrical charge. The photodiode array is mounted on a carrier substrate (58) via bump (56) bonding. The carrier substrate provides a conductive path routing the photodiode array output through to contacts on the back side for connection to readout electronics (60). The carrier substrate and readout electronics are contained within the footprint defined by the photodiode array, allowing the detector elements to be abutted on any and all sides, thus permitting the mosaic detector to be tailored to any desired size and shape. es of phase shifted clock signals forming the output clock signal at the second frequency. 2. The frequency synthesizer as set forth in claim 1, wherein: each address value corresponds to an ideal phase shifted clock signal to be output by the selection circuit, each ideal phase shifted clock signal having an ideal phase shift with respect to the reference clock signal; and the LUT includes a mapping of each address value to a corresponding tap address which causes the selection circuit to output the phase shifted clock signal having a phase shift corresponding to the ideal phase shift of the desired phase shifted clock signal corresponding to the address value. 3. The frequency synthesizer as set forth in claim 2, wherein the selection circuit is a multiplexer. 4. The frequency synthesizer as set forth in claim 1, wherein: the delay line has a plurality of delay elements connected in series; each delay element has an output tap connected to an input of the selection circuit; and each delay element delays the propagation of the reference clock signal therethrough and outputs on its output tap a corresponding phase shifted clock signal. 5. The frequency synthesizer as set forth in claim 1, wherein two or more address values have the same tap address associated therewith. 6. The frequency synthesizer as set forth in claim 2, further including a calibration circuit for generating the mapping between each address value and one of the tap addresses, and for storing the mapping in the LUT. 7. The frequency synthesizer as set forth in claim 6, wherein the calibration circuit includes: a calibration processor for supplying each tap address to the selection circuit independent of the LUT; a calibration phase detector configured to receive each phase shifted clock signal output by the selection circuit and for generating for each phase shifted clock signal received thereby a phase difference signal related to a phase difference between the reference clock signal and the phase shifted clock signal; a low pass filter for low pass filtering the phase difference signal; and an analog-to-digital converter for converting the low pass filtered phase difference signal into a phase difference value for processing by the calibration processor. 8. The frequency synthesizer as set forth in claim 7, wherein the calibration processor: stores for each address value an ideal phase difference value corresponding to a phase difference between the reference clock signal and the ideal phase shifted clock signal corresponding to the address value; stores for each tap address the corresponding phase difference value; maps each address value to one of the tap addresses as a function of a difference between the respective ideal phase difference value and phase difference value; and causes each tap address to be stored in the LUT so that in response to receiving one of the address values, the LUT outputs to the selection circuit the tap address which causes the selection circuit to output one of the phase shifted clock signals having the phase shift equal to or closest to the ideal phase shift of the one address value. 9. A method of synthesizing from an input clock signal oscillating at a first frequency an output clock signal oscillating at a second frequency, the method comprising the steps of: (a) converting the input clock signal into a plurality of phase shifted clock signals, with each phase shifted clock signal oscillating at the first frequency and having a phase shift with respect to the input clock signal and with respect to the other phase shifted clock signals; (b) mapping each phase shifted clock signal to a tap address; (c) converting the input clock signal into a series of address values, with each address value related to an ideal phase shift of the input clock signal; (d) mapping the series of address values to a series of the tap addresses, with each address value mapped to its corresponding tap address as a function of a difference between the respective ideal phase shift and phase shift with respect to the input clock signal; (e) outputting a series of phase shifted clock signals corresponding to the series of tap addresses; (f) sampling at least a portion of each phase shifted clock signal in the order it is output in step (e); and (g) outputting the sampled portions of the series of phase shifted clock signals to form the output clock signal oscillating at the second frequency. 10. The method as set forth in claim 9, wherein step (d) includes the steps of: storing for each address value the ideal phase shift value related thereto; determining for each tap address the phase shift related thereto; and mapping each address value to one of the tap addresses that minimizes the difference between the ideal phase shift and the phase shift, respectively. 11. An apparatus for synthesizing an oscillator signal having a desired frequency, the apparatus comprising: a clock which produces a clock signal oscillating at a fixed frequency; a delay line which receives the clock signal and which produces therefrom a plurality of phase shifted clock signals oscillating at the fixed frequency, with each phase shifted clock signal being shifted in phase with respect to the clock signal and with respect to the other phase shifted clock signals; a look-up table (LUT) configured to receive an address value related to an ideal phase shifted clock signal oscillating at the fixed frequency and to output a tap address corresponding to the address value; a selection circuit which receives the plurality of phase shifted clock signals and the tap address and which outputs, in response to receiving the tap address, one of the phase shifted clock signals; and a sampling circuit configured to sample at least a portion of the one phase shifted clock signal output by the selection circuit and to output the sampled portion of the one phase shifted clock signal to form at least part of the oscillator signal having the desired frequency. 12. The apparatus as set forth in claim 11, wherein: in response to receiving a series of address values, the LUT outputs a corresponding series of tap addresses; in response to receiving the series of tap addresses, the selection circuit outputs a corresponding series of phase shifted clock signals; and in response to receiving the series of phase shifted clock signals, the sampling circuit samples a portion of each of the phase shifted clock signals and outputs the sampled portions of the phase shifted clock signals to form the oscillator signal having the desired frequency. 13. The apparatus as set forth in claim 12, further including a calibration circuit for generating a mapping between each of a plurality of address values and one of a plurality of tap addresses, and for storing the mapping in the LUT. 14. The apparatus as set forth in claim 13, wherein the calibration circuit includes: a calibration processor for supplying to the selection circuit the plurality of tap addresses; a calibration phase detector configured to receive the clock signal and each phase shifted clock signal output by the selection circuit and to generate for each phase shifted clock signal received thereby a phase difference signal related to a phase difference between the clock signal and the phase shifted clock signal; a low pass filter for low pass filtering the phase difference signal; and an analog-to-digital converter for converting the low pass filtered phase difference signal into a phase difference value for processing by the calibration processor. 15. The frequency synthesizer as set forth in claim 14, wherein the calibration processor: stores for each address value an ideal phase difference value corresponding to a phase difference between the clock signal and the ideal phase shifted clock signal corresponding to the address value; stores for each tap address the corresponding phase difference value ; maps each address value to one of the tap addresses as a function of a difference between the respective ideal phase difference value and phase difference value; and causes each tap address to be stored in the LUT so that in response to receiving one of the address values, the LUT outputs to the selection circuit the tap address which causes the selection circuit to output one of the phase shifted clock signals having a phase shift closest to an ideal phase shift of the ideal phase shifted clock signal corresponding to the one address value. 16. The frequency synthesizer as set forth in claim 15, wherein: the calibration processor stores only the fractional part of each ideal phase difference value and the fractional part of each phase difference value; and the calibration processor maps each address value to one of the tap addresses as a function of a difference between the respective fractional part of the ideal phase difference value and fractional part of the phase difference value. 17. The frequency synthesizer as set forth in claim 16, wherein the phase shift between the ideal phase shifted clock signal and the phase shifted clock related together by the mapping of one of the address values to one of the tap addresses, respectively, is greater than one cycle of the clock signal. 18. The frequency synthesizer as set forth in claim 15, wherein: the delay line includes a plurality of delay elements connected in series; each delay element has an output tap connected to the selection circuit; and each delay element delays the propagation of the reference clock signal therethrough and outputs on its corresponding output tap a corresponding phase shifted clock signal. 19. The frequency synthesizer as set forth in claim 18, wherein: each tap address corresponds to one of the output taps of the delay line; and in response to receiving each tap address, the selection circuit connects to an output thereof the output tap of the delay element corresponding to the tap address. 20. The frequency synthesizer as set forth in claim 12, further including: another delay line which receives the series of phase shifted clock signals from the selection circuit and which produces from one of the phase shifted clock signals another plurality of phase shifted clock signals; another LUT receives another address value related to another ideal phase shifted clock signal and to output another tap address related to the other address value; and another selection circuit which receives the other plurality of phase shifted clock signals and the other tap address and which outputs to the sampling circuit in response to receiving the other tap address one of the other plurality of phase shifted clock signals.
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