RU98114103A - SELF-TEST DIAGRAM IN MICROWAVE EQUIPMENT - Google Patents

Claims (19)

1. A self-checking circuit in microwave equipment containing directional couplers, each of which serves to separate and isolate a portion of the microwave signal from each observation point in the microwave path of the main signal, detectors, each of which serves to detect the extracted signal from the said directional coupler temperature measuring means, each of which serves to measure the temperature of said detector, a plurality of amplification means, each of which serves to amplify the detected signal from said detector, a plurality of analog-to-digital conversion means, each of which serves to convert the output signal from said amplification means into digital data, an interface for interfacing with the external environment with respect to the signal from said temperature measuring means and with respect to digital data from said analog-to-digital conversion means, a first storage device for storing signal values transmitted via said interface, a second storage device for storing a control program and various data, a central processing circuitry for comparing and analyzing signals stored in said first storage device using a control program and data stored in said second storage device, and for outputting a comparison and analysis result, and means for displaying output signal of the central processing circuit.  2. The circuit according to claim 1, characterized in that said detector uses an envelope detection method.  3. The circuit according to claim 1, characterized in that each said temperature measuring means comprises a temperature sensor for measuring temperature, an amplifier for amplifying the temperature value, and an analog-to-digital converter for converting the amplified value to digital data.  4. The circuit according to claim 1, characterized in that said interface assigns a corresponding special identification number to signals from said temperature measuring means and signals from said observation points.  5. The circuit according to claim 1, characterized in that said second storage device has a program for setting the limit values of the data detected at each observation point and for displaying the fact that these detected data is outside the limit value.  6. The circuit of claim 1, wherein said second storage device has a program for compensating data values detected at said corresponding observation point for the electrical characteristic and gain of said corresponding amplification means.  7. The circuit according to claim 1, characterized in that the said second storage device has a program for compensating for the temperature characteristics of said detectors, which vary in accordance with the temperature.  8. The circuit according to claim 1, characterized in that said second storage device has a program for generating a resulting value of data detected at the corresponding observation point, from the point following said corresponding observation point to the last, as the “WORK” state, when the data value detected at the corresponding observation point is not in the range of limit values.  9. The circuit of claim 1, wherein said second storage device has a program for detecting data values at a particular observation point.  10. Self-checking circuits in a variety of microwave equipment, containing directional couplers, each of which serves to separate and isolate a portion of the microwave signal from each observation point in the microwave path of the main signal of many microwave equipment, detectors, each of which is used to detect the extracted signal from the aforementioned directional coupler, a plurality of temperature measuring means, each of which serves to measure the temperature of said detector, a plurality of amplification means, each of which serves to the detection signal from the said detector, a lot of analog-to-digital conversion means, each of which is used to convert the output signal from the said amplification means into digital data, interfaces, each of which is used to perform pairing with the external environment with respect to the signal from the said measuring means temperature and in relation to digital data from the aforementioned means of analog-to-digital conversion, the first storage devices, each of which serves to store the values of the signals transmitted through the said interface, second storage devices, each of which serves to store the control program and various data, central processing circuits, each of which serves to compare and analyze signals stored in the said first storage devices, using the control program and data stored in said second storage devices, and outputting the result of comparison and analysis, and means, each of which serves to display the resulting value exiting the central processing circuit.  11. The circuit of claim 10, wherein said interface transmits said digital data to said central processing circuit using a remote data communication function.  12. A method of self-testing in microwave equipment, which includes the following steps: separating and extracting a portion of the microwave signal at each observation point in the microwave path of the main signal using each corresponding directional coupler, detecting the extracted part of the signal using each detector, amplifying the signal detected by each said detector, using each amplifier, measuring the ambient temperature of each said detector using each of said means from temperature grazing, converting the output signal of each of said amplification means into digital data using an analog-to-digital conversion unit, pairing with the external environment with respect to the signal from the temperature measuring means and the signal from the analog-to-digital conversion means using the interface, storing signal values, transmitted through the aforementioned interface, in the first storage device, storing the control program and various data necessary for checking the microwave equipment in the second storage device, comparing and analyzing signals stored in said first storage device using a control program and data stored in said second storage device, and generating a resulting comparison and analysis value using a central processing circuit, and displaying the resulting value issued from said central processing circuit.  13. The method according to p. 12, characterized in that the step of comparing and analyzing signals stored in said first storage device using a control program and data stored in said second storage device, and generating a resulting comparison and analysis value using said central processing scheme, includes the following steps: reading data values measured at each observation point from the first to the last, which are stored in said first storage device, reading e temperature values measured at each observation point from the first to the last, which are stored in said first storage device, reading the temperature and electrical characteristics of each said detector at each said observation point, the amplification factors of each said amplification means, and the limiting values of the data from said second a storage device, compensating each data value of each said observation point stored in said first storage device ve, for each corresponding electrical and temperature characteristic of each said detector and each corresponding gain of each mentioned amplification means, compensation of each compensated value for the temperature values measured at each observation point, generating the resulting value as "FAILURE" when the data value of the corresponding observation point is outside the range of limit values, and generating the resulting value as "FAILURE" when the data value is corresponding point of observation does not exceed the limit values.  14. The method according to p. 12, characterized in that the step of comparing and analyzing the signals stored in the first memory device using the control program and the data stored in the second memory device and generating a resulting comparison and analysis value using the said central processing circuit , includes the step of setting all the initial resulting values of each observation point to "FAIL".  15. The method according to p. 12, characterized in that the step of comparing and analyzing signals stored in said first storage device using a control program and data stored in said second storage device and generating a resulting comparison and analysis value using said central processing scheme, includes the step of selectively outputting data values of a particular observation point.  16. The method according to p. 13, characterized in that the step of generating the resulting value as "FAILURE" when the data value of the corresponding observation point is outside the range of limit values includes a step of displaying the resulting values of the data of the observation points from the point following the corresponding point of observation, to the last, as "WORK".  17. The method according to p. 13, characterized in that the step of generating the resulting value as "FAILURE" when the data value of the corresponding observation point is outside the range of limit values includes a feedback input step for sequentially comparing the data values of each observation point, the following after said first observation point, after comparing the data values of said first observation point.  18. The method according to p. 13, characterized in that the step of generating the resulting value as “WORK”, when the data value of the corresponding observation point does not exceed the limit values, includes a feedback input step for sequentially comparing the data values of each observation point following said first observation point, after comparing the data values of said first observation point.  19. The method according to p. 12, characterized in that the step of displaying the resulting value issued from said central processing circuit using said display includes a step for introducing feedback for sequentially outputting the resulting values of each observation point following said first observation point , after issuing the resulting value of said first observation point.