Patent
Monolithic multi-function balanced switch and phase shifter
| العنوان: | Monolithic multi-function balanced switch and phase shifter |
|---|---|
| Patent Number: | 5,606,283 |
| تاريخ النشر: | February 25, 1997 |
| Appl. No: | 08/440,555 |
| Application Filed: | May 12, 1995 |
| مستخلص: | A multi-function, balanced phase shifter and switch having a particular application as a balanced switched low-noise amplifier. The switch includes a hybrid input coupler that couples a first input signal at a first input port and a second input signal at a second input port into a first path and a second path of the switch. Each of the first path and the second path include at least one amplifier and a phase shifter. The phase shifters include a hybrid coupler and two switching devices that are simultaneously switched on or off by a single control signal. Output from the two paths are applied to an output hybrid coupler that couples the output from the two paths into first and second output ports of the switch. By controlling the two control signals applied to the phase shifters to selectively switch the switching devices on and off, signals at the input ports can be selectively amplified and switched to the output ports in a balanced, low-noise manner. |
| Inventors: | Allen, Barry R. (Redondo Beach, CA); Lo, Dennis C. (Los Angeles, CA); Wang, Huei (La Palma, CA); Dow, Gee S. (Rancho Palos Verdes, CA) |
| Assignees: | TRW Inc. (Redondo Beach, CA) |
| Claim: | What is claimed is |
| Claim: | 1. A low noise electronic control device comprising |
| Claim: | an input coupler, said input coupler including a first input port and a second input port connected to the input coupler, said input coupler coupling signals at the first and second input ports into a first path and a second path of the device; |
| Claim: | a first low noise amplifier associated with the first path, said first amplifier being responsive to signals applied to the first path from the input coupler to provide an amplified first path signal; |
| Claim: | a first phase shifter associated with the first path, said first phase shifter being responsive to the amplified first path signal from the first low noise amplifier, said first phase shifter including a first path coupler and a first path coupler control circuit, said first path coupler control circuit being responsive to a first control signal that controls the operation of the first path coupler; |
| Claim: | a second low noise amplifier associated with the second path, said second amplifier being responsive to signals applied to the second path from the input coupler to provide an amplified second path signal; and |
| Claim: | a second phase shifter associated with the second path, said second phase shifter being responsive to the amplified second path signal from the second low noise amplifier, said second phase shifter including a second path coupler and a second path coupler control circuit, said second path coupler control circuit being responsive to a second control signal that controls the operation of the second path coupler. |
| Claim: | 2. The device according to claim 1 further comprising an output coupler, said output coupler including a first output port and a second output port, said output coupler coupling an output signal from the first path and an output signal from the second path into the first and second output ports. |
| Claim: | 3. The device according to claim 2 wherein the input coupler is responsive to a first input signal applied to the first input port and a second input signal applied to the second input port, and wherein the input coupler applies the first input signal to the first path at a first phase and the first input signal to the second path at a second phase, and applies the second input signal to the first path at the first phase and the second input signal to the second path at the second phase. |
| Claim: | 4. The device according to claim 3 wherein the first and second phases are 90.degree. apart in phase. |
| Claim: | 5. The control device according to claim 2 wherein the first path coupler control circuit includes first and second switching devices and the second path coupler control circuit includes first and second switching devices, said first and second switching devices of the first path being simultaneously switched on and off by the first control signal and the first and second switching devices of the second path being simultaneously switched on and off by the second control signal. |
| Claim: | 6. The device according to claim 5 wherein the input coupler is responsive to a first input signal applied to the first input port and a second input signal applied to the second input port, and wherein when the first control signal switches the first and second switching devices of the first path on and the second control signal switches the first and second switching devices of the second path on, the second input signal will be applied to the first output port at a first phase angle and the first input signal will be applied to the second output port at the first phase angle, and wherein when the first control signal switches the first and second switching devices of the first path off and the second control signal switches the first and second switching devices of the second path off, the second input signal will be applied to the first output port at the first phase angle plus 180.degree. and the first input signal will be applied to the second output port at the first phase angle plus 180.degree., and wherein when the first control signal switches the first and second switching devices of the first path on and the second control signal switches the first and second switching devices of the second path off, the first input signal will be applied to the first output port at a second phase angle and the second input signal will be applied to the second output port at the second phase angle, and wherein when the first control signal switches the first and second switching devices of the first path off and the second control signal switches the first and second switching devices of the second path on, the first input signal will be applied to the first output port at the second phase angle plus 180.degree. and the second input signal will be applied to the second output port at the second phase angle plus 180.degree.. |
| Claim: | 7. The device according to claim 5 wherein the first input port is responsive to an input signal, the second input port is connected to an input load resistor and the second output port is connected to an output load resistor, and wherein when the first control signal switches the first and second switching devices of the first path on and the second control signal switches the first and second switching devices of the second path on, and when the first control signal switches the first and second switching devices of the first path off and the second control signal switches the first and second switching devices of the second path off, the output signal at the first output port is out of phase and cancelled, and wherein when the first control signal switches the first and second switching devices of the first path on and the second control signal switches the first and second switching devices of the second path off, the input signal will be applied to the first output port at a particular phase angle, and wherein when the first control signal switches the first and second switching devices of the first path off and the second control signal switches the first and second switching devices of the second path on, the input signal is applied to the first output port at the phase angle plus 180.degree.. |
| Claim: | 8. The device according to claim 5 wherein the second input port is connected to an input load resistor, the first output port is connected to an output load resistor and the first input port is responsive to an input signal, and wherein when the first control signal switches the first and second switching devices of the first path on and the second control signal switches the first and second switching devices of the second path off, and when the first control signal switches the first and second switching devices of the first path off and the second control signal switches the first and second switching devices of the second path on, the output signal at the second output port is out of phase and cancelled, and wherein when the first control signal switches the first and second switching devices of the first path on and the second control signal switches the first and second switching devices of the second path on, the input signal will be applied to the second output at a particular phase angle, and wherein when the first control signal switches the first and second switching devices of the first path off and the second control signal switches the first and second switching devices of the second path off, the input signal will be applied to the second output port at the phase angle plus 180.degree.. |
| Claim: | 9. The device according to claim 5 wherein the first input port is responsive to an input signal and the second input port is connected to an input load resistor, and wherein when the first control signal switches the first and second switching devices of the first path on and the second control signal switches the first and second switching devices of the second path on, the input signal is applied to the second output port at a first phase angle, and wherein when the first control signal switches the first and second switching devices of the first path off and the second control signal switches the first and second switching devices of the second path off, the input signal is applied to the second output port at the first phase angle plus 180.degree., and wherein when the first control signal switches the first and second switching devices of the first path on and the second control signal switches the first and second switching devices of the second path off, the input signal is applied to the first output port at a second phase angle, and wherein when the first control signal switches the first and second switching devices of the first path off and the second control signal switches the first and second switching devices of the second path on, the input signal is applied to the first output port at the second phase angle plus 180.degree.. |
| Claim: | 10. The device according to claim 5 wherein the first input port is responsive to a first input signal, the second input port is responsive to a second input signal, and the second output port is connected to an output load resistor, and wherein when the first control signal switches the first and second switching devices of the first path on and the second control signal switches the first and second switching devices of the second path on, the second input signal is applied to the first output port at a first phase angle, and wherein when the first control signal switches the first and second switching devices of the first path off and the second control signal switches the first and second switching devices of the second path off, the second input signal is applied to the first output port at the first phase angle plus 180.degree., and wherein when the first control signal switches the first and second switching devices of the first path on and the second control signal switches the first and second switching devices of the second path off, the first input signal is applied to the first output port at a second phase angle, and wherein when the first control signal switches the first and second switching devices of the first path off and the second control signal switches the first and second switching devices of the second path on, the first input signal is applied to the first output port at the second phase angle plus 180.degree.. |
| Claim: | 11. The device according to claim 5 wherein the first and second switches of the first phase shifter and the first and second switches of the second phase shifter are field effect controlled devices. |
| Claim: | 12. The device according to claim 1 wherein the input coupler, the first path coupler and the second path coupler are 3 dB 90.degree. hybrid couplers. |
| Claim: | 13. The device according to claim 1 wherein the second input port is connected to an input load. |
| Claim: | 14. A low noise electronic control device comprising |
| Claim: | a first low noise amplifier associated with the first path, said first amplifier responsive to signals applied to the first path from the input coupler to provide an amplified first path signal; |
| Claim: | a first phase shifter associated with the first path, said first phase shifter being responsive to the amplified first path signal from the first low noise amplifier, said first phase shifter including a first path coupler and first and second switching devices, said switching devices being simultaneously switched between an on state and an off state by, a first control signal to control the operation of the first phase shifter; |
| Claim: | a second amplifier associated with the second path, said second amplifier being responsive to signals applied to the second path from the input coupler to provide an amplified second path signal; |
| Claim: | a second phase shifter associated with the second path, said second phase shifter being responsive to the amplified second path signal from the second low noise amplifier, said second phase shifter including a second path coupler and first and second switching devices, said switching devices of the second phase shifter being simultaneously switched between an on state and an off state by a second control signal to control the operation of the second phase shifter; and |
| Claim: | an output coupler, said output coupler including a first output port and a second output port connected to the output coupler, said output coupler coupling an output signal from the first path and an output signal from the second path into the first and second output ports. |
| Claim: | 15. The device according to claim 14 wherein the input coupler is responsive to a first input signal applied to the first input port and a second input signal applied to second input port, and wherein the input coupler applies the first input signal to the first path at a first phase and the first input signal to the second path at a second phase, and applies the second input signal to the first path at the first phase and the second input signal to the second path at the second phase. |
| Claim: | 16. The device according to claim 15 wherein the first and second phases are 90.degree. apart in phase. |
| Claim: | 17. The device according to claim 14 wherein the input coupler, the first path coupler, the second path coupler and the output coupler are 3 dB 90.degree. hybrid couplers. |
| Claim: | 18. The device according to claim 14 wherein the first and second switching devices of the first phase shifter and the first and second switching devices of the second phase shifter are field effect controlled devices. |
| Claim: | 19. A low noise electronic control device comprising |
| Claim: | an input coupler, said input coupler including at least a first input port, said input coupler coupling input signals at the at least first input port into an input path; |
| Claim: | a low noise amplifier in the input path, said low noise amplifier being responsive to the input signal applied to the input path and generating an amplified low noise input signal; and |
| Claim: | a phase shifter in the input path, said phase shifter including a coupler and first and second switching devices, said coupler being responsive to the amplified input signal, said first and second switching devices being selectively switched on and off by a common control signal to shift the amplified input signal in phase. |
| Claim: | 20. The control device according to claim 19 wherein the first and second switching devices are field effect controlled switches. |
| Current U.S. Class: | 330/124R; 330/295; 333/109; 333/156; 333/164 |
| Current International Class: | H03F 368 |
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| Other References: | Ballantoni, J. V. et al., "A Monolithic High Power Ka Band PIN Switch", IEEE Microwave and Millimeter-Wave Circuits Symposium, pp. 47-50 (1989). Schindler, Manfred J. et al., "DC-40 GHz and 20-40 GHz MMIC SPDT Switches", IEEE, pp. 1486-1493 (1987). Lo, D. C. W. et al., "A Novel Monolithic Balanced Switching Low Noise Amplifier", IEEE MTT-S Digest, pp. 1199-1202 (1994). Neilson, D. et al., "A Broadband Upconverter IC", IEEE MTT-S Digest, pp. 454-458 (1992). Boire, D. C. et al., "4:1 Bandwidth Digital Five Bit MMIC Phase Shifters", IEEE Microwave and Millimeter-Wave Monolithic Circuits Symposium, pp. 69-73 (1989). Mazumder, Shamsur R. et al., "A Novel 6 to 8 GHz 180-Degree Bit Phase Shifter Configuration Having Very Small Amplitude and Phase Errors", IEEE MTT-S Digest, pp. 83-86 (1994). Maas, Steven A., "Balanced and Multiple-Device Circuits", Artech House, pp. 209-221 (1988). |
| Primary Examiner: | Mullins, James B. |
| Attorney, Agent or Firm: | Yatsko, Michael S. |
| رقم الانضمام: | edspgr.05606283 |
| قاعدة البيانات: | USPTO Patent Grants |
| الوصف غير متاح. |