초록 ▼

A method for calibrating the calculation of a laser power measurement with respect to specified operational and/or environmental parameters in an optoelectronic device, such as an optical transceiver module having a laser diode, is disclosed. In particular, the method includes sensing analog data th

A method for calibrating the calculation of a laser power measurement with respect to specified operational and/or environmental parameters in an optoelectronic device, such as an optical transceiver module having a laser diode, is disclosed. In particular, the method includes sensing analog data that relates to light emission from the laser diode using a monitor photodiode disposed in the optical transceiver module. Additional sensors are then used to sense analog data that relates to the temperature and voltage of the monitor photodiode. The analog data is converted into digital data, then a formulaic relationship that relates the light emission data to the temperature and voltage data is used to calculate the laser power of the laser diode. Calibration by this method accounts for unintended effects caused by temperature and voltage fluctuations in the optical transceiver module.

대표청구항 ▼

What is claimed is: 1. An optical transceiver module, comprising: an optical transmitter containing a laser diode; a first sensor for sensing a predetermined parameter relating to operation of the laser diode, wherein the first sensor is a monitor photodiode, and wherein the predetermined parameter

What is claimed is: 1. An optical transceiver module, comprising: an optical transmitter containing a laser diode; a first sensor for sensing a predetermined parameter relating to operation of the laser diode, wherein the first sensor is a monitor photodiode, and wherein the predetermined parameter relates to laser power of the laser diode; at least one additional sensor for sensing at least one additional parameter that affects measurement of the predetermined parameter; and a processor capable of executing microcode, wherein the microcode, when executed, causes the optical transceiver to perform the following: by the first sensor, sensing data relating to the predetermined parameter; by the at least one additional sensor, sensing data relating to the at least one additional parameter; and according to a formulaic relationship relating the data of the predetermined parameter and the data of the at least one additional parameter, calculating a result relating to the predetermined parameter, wherein the formulaic relationship is configured to eliminate discrepancies relating to temperature and voltage fluctuations of the monitor photodiode. 2. The optical transceiver module as defined in claim 1, wherein the at least one additional parameter alters the calculation of the result relating to the predetermined parameter. 3. The optical transceiver module as defined in claim 1, wherein the formulaic relationship includes an offset and slope factor for the predetermined parameter, and a slope factor for the at least one additional parameter. 4. The optical transceiver module as defined in claim 1, wherein the at least one additional parameter includes a first parameter relating to temperature of the monitor photodiode and a second parameter relating to voltage of the monitor photodiode. 5. The optical transceiver module as defined in claim 1, wherein the formulaic relationship includes a linear equation. 6. In an optical transceiver module having an optical transmitter that includes a laser diode, a method for calculating the laser power of the laser diode, the method comprising: by a monitor photodiode, sensing analog data relating to light emission from the laser diode; by additional sensors, sensing analog data relating to the temperature and voltage of the monitor photodiode; converting the analog data into digital data; and by a formulaic relationship relating the light emission data to the temperature and voltage data, calculating the laser power of the laser diode, wherein the formulaic relationship is configured to eliminate discrepancies relating to temperature and voltage fluctuations of the monitor photodiode. 7. The method for calculating as defined in claim 6, wherein the method is at least partially performed by a processor executing microcode. 8. The method for calculating as defined in claim 7, further comprising: loading microcode from a persistent memory location into a system memory location. 9. The method for calculating as defined in claim 6, further comprising, reporting the calculated laser power to a host system. 10. The method for calculating as defined in claim 9, wherein the method is repeated periodically or when requested by the host system. 11. The method for calculating as defined in claim 10, wherein the temperature and voltage data in the formulaic relationship alters the calculated laser power result. 12. In an optical transceiver module having an optical transmitter that includes a laser diode, a method for calculating the laser power of the laser diode, the method comprising: loading microcode from a persistent memory location into a system memory location; by a monitor photodiode, sensing analog data relating to light emission from the laser diode; by additional sensors, sensing analog data relating to the temperature and voltage of the monitor photodiode; converting the analog data into digital data; and by a formulaic relationship relating the light emission data to the temperature and voltage data, calculating the laser power of the laser diode, wherein the formulaic relationship is configured to eliminate discrepancies relating to temperature and voltage fluctuations of the monitor photodiode, wherein the method is at least partially performed by a processor executing the microcode.