A reflectometer for allowing a test of a device, the reflectometer comprising: a source of pulsed radiation; a first photoconductive element configured to output a pulse in response to irradiation from said pulsed source; a second photoconductive element configured to receive a pulse; a transmission
A reflectometer for allowing a test of a device, the reflectometer comprising: a source of pulsed radiation; a first photoconductive element configured to output a pulse in response to irradiation from said pulsed source; a second photoconductive element configured to receive a pulse; a transmission line arrangement configured to direct the pulse from the first photoconductive element to the device under test and to direct the pulse reflected from the device under test to the second photoconductive element; and a termination resistance provided for said transmission line configured to match the impedance of the transmission line.
대표청구항▼
1. A time domain reflectometer for allowing a test of a device, the time domain reflectometer comprising: a source of pulsed radiation;a first photoconductive element configured as an emitter to output a pulse in response to irradiation from said pulsed source;a second photoconductive element config
1. A time domain reflectometer for allowing a test of a device, the time domain reflectometer comprising: a source of pulsed radiation;a first photoconductive element configured as an emitter to output a pulse in response to irradiation from said pulsed source;a second photoconductive element configured as a receiver to receive a pulse;a transmission line arrangement comprising a waveguide configured to direct the pulse from the first photoconductive element to the device and to direct the pulse reflected from the device to the second photoconductive element; anda termination resistance provided for said transmission line configured to match the impedance of the transmission linewherein the path length of the waveguide from the first photoconductive element directly to the second photoconductive element is shorter than the path length from the first photoconductive element to the device, and then from the device to the second photoconductive element, such that there is no overlap of the pulses in the time domain and any secondary reflections between the first photoconductive element and second photoconductive element do not interfere with the pulse reflected from the device to the second photoconductive element. 2. A reflectometer according to claim 1, wherein the transmission line arrangement is provided on a substrate with a maximum dielectric constant of 10. 3. A reflectometer according to claim 1, wherein the terminating resistor is separated from the photoconducting element via a further transmission line. 4. A reflectometer according to claim 1, wherein at least some parts of the system which carry no signals or low frequency signals are covered by an RF absorbing material, the low frequency signal being signals in the system other than the said pulse produced by the first photoconductive element and received by the second photoconductive element. 5. A reflectometer according to claim 1, further comprising at least one transient voltage diode configured to protect at least one of said photoconductive elements. 6. A reflectometer according to claim 1, wherein the first photoconductive element is an generator which receives a pump beam of radiation and the second photoconductive element is a receiver which receives a probe beam of radiation, the pump beam and probe beam being emitted from the same source, the reflectometer further comprising a delay line configured to vary the path length of the pump beam is varied relative to that of the probe beam or vice versa. 7. A reflectometer according to claim 6, wherein the delay line comprises a fast scanning delay section and a slow scanning delay section, wherein said fast scanning delay section is provided by an oscillating rhomboid and said slow scanning delay section comprises a linear delay line. 8. A reflectometer according to claim 1, wherein the first photoconductive element is configured as a generator and the second photoconductive element is configured as a receiver, the reflectometer further comprising an AC bias unit to provide an AC bias to said generator and a phase sensitive detection unit configured to perform phase-sensitive detection on the signal measured directly from the receiver device. 9. A reflectometer according to claim 1, wherein said second photoconductive element is configured as a receiver, the reflectometer further comprising an amplifier to amplify the output of the receiver and unit configured to provide a input AC impedance of at least 100,000 ohm at the AC bias frequency to said amplifier. 10. A reflectometer according to claim 1, wherein photoconductive elements are coupled to the transmission line arrangement by wire bonds or ribbon bonds. 11. A reflectometer according to claim 1, wherein the photoconductive elements comprise GaAs, InP, GalnAs or another III—V alloys. 12. A time domain reflectometer for allowing a test of a device, the time domain reflectometer comprising: a source of pulsed radiation;a first photoconductive element configured as an emitter to output a pulse in response to irradiation from said pulsed source;a second photoconductive element configured as a receiver to receive a pulse;a transmission line arrangement comprising a waveguide configured to direct the pulse from the first photoconductive element to the device and to direct the pulse reflected from the device to the second photoconductive element, said transmission line having a three terminal arrangement with the first and second elements provided at separate terminals and an input to the device provided at the third terminal;wherein the path length of the waveguide from the first photoconductive element directly to the second photoconductive element is shorter than the path length from the first photoconductive element to the device, and then from the device to the second photoconductive element, such that there is no overlap of the pulses in the time domain and any secondary reflections between the first photoconductive element and second photoconductive element do not interfere with the pulse reflected from the device to the second photoconductive element. 13. A reflectometer according to claim 12, wherein the three point transmission line arrangement is in the form of a Y or a V. 14. A reflectometer according to claim 12, wherein the three point transmission line comprises a Wye or Delta splitter. 15. A reflectometer for allowing a test of a device, the reflectometer comprising: a source of pulsed radiation;a first photoconductive element configured as an emitter to output a pulse in response to irradiation from said pulsed source;a second photoconductive element configured as a receiver to receive a pulse;a transmission line arrangement comprising a waveguide configured to direct the pulse from the first photoconductive element to the device and to direct the pulse reflected from the device to the second photoconductive element,wherein at least one photoconductive element comprises a pair of electrodes provided on the first surface of a first substrate and said transmission line arrangement is provided on a second surface of a second substrate,the first and second surfaces being provided facing one another and bonded to one another such that there is communication of a pulse between the said element and the transmission line arrangement;wherein the path length of the waveguide from the first photoconductive element directly to the second photoconductive element is shorter than the path length from the first photoconductive element to the device, and then from the device to the second photoconductive element, such that there is no overlap of the pulses in the time domain and any secondary reflections between the first photoconductive element and second photoconductive element do not interfere with the pulse reflected from the device to the second photoconductive element. 16. A reflectometer according to claim 15, wherein the portion of the transmission lines which extend under the first substrate are thinner than the portions which do not extend under the first substrate. 17. A reflectometer according to claim 15, wherein there is hole in the second substrate to allow illumination of the photoconductive element on the first substrate. 18. A reflectometer according to claim 15, wherein the electrodes of the photoconductive elements are coupled to the transmission line by a flip-chip bonding methods chosen from, solder ball bumps, conductive epoxy, indium ball bumps or wire ball bumps. 19. A reflectometer system comprising a plurality of reflectometers according to claim 3, wherein a single common first substrate is provided for the plurality of reflectometers such that the photoconductive elements for a plurality of reflectometers are flip chip bonded at the same time. 20. A reflectometer system according to claim 19, wherein the plurality of reflectometers are arranged in parallel to one another. 21. A time domain method of performing a reflectometry test on a device, the method comprising: providing a source of pulsed radiation;providing a first photoconductive element configured as an emitter to output a pulse in response to irradiation from said pulsed source;providing a second photoconductive element configured as a receiver to receive a pulse;directing the pulse from the first photoconductive element to the device and directing the pulse reflected from the device to the second photoconductive element using a transmission line comprising a waveguide; andproviding a termination resistance provided for said transmission line configured to match the impedance of the transmission line;wherein the path length of the waveguide from the first photoconductive element directly to the second photoconductive element is shorter than the path length from the first photoconductive element to the device, and then from the device to the second photoconductive element, such that there is no overlap of the pulses in the time domain and any secondary reflections between the first photoconductive element and second photoconductive element do not interfere with the pulse reflected from the device to the second photoconductive element. 22. A method of performing a time domain reflectometry test on a device, the method comprising: providing a source of pulsed radiation;providing a first photoconductive element configured as an emitter to output a pulse in response to irradiation from said pulsed source;providing a second photoconductive element configured as a receiver to receive a pulse;directing a pulse from the first photoconductive element to the device and directing a pulse reflected from the device to the second photoconductive element using a transmission line, said transmission line comprising a waveguide having a three terminal arrangement with the first and second elements provided at separate terminals and an input to the device provided at the third terminal;wherein the path length of the waveguide from the first photoconductive element directly to the second photoconductive element is shorter than the path length from the first photoconductive element to the device, and then from the device to the second photoconductive element, such that there is no overlap of the pulses in the time domain and any secondary reflections between the first photoconductive element and second photoconductive element do not interfere with the pulse reflected from the device to the second photoconductive element. 23. A method of performing a reflectometry test on a device, the method comprising providing a source of pulsed radiation;providing a first photoconductive element configured as an emitter to output a pulse in response to irradiation from said pulsed source;providing a second photoconductive element configured as a receiver to receive a pulse;directing the pulse from the first photoconductive element to the device and directing the pulse reflected from the device to the second photoconductive element using a transmission line comprising a waveguide,wherein at least one photoconductive element comprises a pair of electrodes provided on the first surface of a first substrate and said transmission line arrangement is provided on a second surface of a second substrate,the first and second surfaces being provided facing one another and bonded together such that there is communication of a pulse between the said element and the transmission line arrangement;wherein the path length of the waveguide from the first photoconductive element directly to the second photoconductive element is shorter than the path length from the first photoconductive element to the device, and then from the device to the second photoconductive element, such that there is no overlap of the pulses in the time domain and any secondary reflections between the first photoconductive element and second photoconductive element do not interfere with the pulse reflected from the device to the second photoconductive element.
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이 특허에 인용된 특허 (13)
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