Claims
- 1. An optical transmitter, comprising:
a laser diode; a laser driver having a data input for receiving input data and providing a drive signal to the laser diode corresponding to the input data; a laser diode power monitoring photodiode for monitoring the laser optical output power and providing a laser power monitoring signal; and an automatic power control circuit coupled to receive the laser power monitoring signal, the automatic power control circuit comprising a comparator for comparing the monitored laser power to a reference level and a control circuit, coupled to the comparator output, for providing a digital power control value corresponding to the difference between the monitored laser power and the reference level, the automatic power control circuit employing the digital power control value to provide a power control signal to the laser driver.
- 2. An optical transmitter as set out in claim 1, wherein said automatic power control circuit further comprises a transimpedance amplifier for converting the laser power monitoring signal to a voltage signal and providing the voltage signal to the comparator.
- 3. An optical transmitter as set out in claim 1, wherein said automatic power control circuit further comprises a nonvolatile storage for storing said reference level as a digital reference value.
- 4. An optical transmitter as set out in claim 1, wherein said automatic power control circuit further comprises a memory for storing said digital power control value.
- 5. An optical transmitter as set out in claim 4, wherein the transmitter transmits bursts of modulated light and wherein said memory stores said digital power control value between bursts.
- 6. An optical transmitter as set out in claim 3, wherein said automatic power control circuit further comprises a reference digital to analog converter for converting the digital reference value to a DC voltage and providing the DC reference voltage to said comparator.
- 7. An optical transmitter as set out in claim 1, wherein said control circuit comprises a counter which is coupled to receive the comparator output and which provides the digital power control value as an output.
- 8. An optical transmitter as set out in claim 7, wherein said counter is incremented when the laser power level is below the reference level.
- 9. An optical transmitter as set out in claim 7, wherein said counter is decremented when the laser power level is above the reference level.
- 10. An optical transmitter as set out in claim 7, wherein said control circuit further comprises a digital filter coupled between the comparator and the counter.
- 11. An optical transmitter as set out in claim 10, wherein said control circuit further comprises a digital hysteresis control circuit coupled to the comparator output and providing a feedback signal thereto.
- 12. An optical transmitter as set out in claim 1, further comprising a shut-off circuit, coupled to the automatic power control circuit, for shutting off the laser driver if the monitored power exceeds a preset safety level.
- 13. An optical transmitter as set out in claim 12, wherein the shut-off circuit comprises a laser power monitoring circuit receiving a laser power monitoring signal from the automatic power control circuit and a shut-off circuit latch.
- 14. An optical transmitter as set out in claim 13, wherein the shut-off circuit further comprises a laser diode driver current monitoring circuit receiving the laser drive current from the laser driver and wherein the shut-off circuit shuts off the laser driver if the laser drive current exceeds a preset safety level.
- 15. An optical transmitter as set out in claim 1, further comprising a digital to analog converter for converting the digital power control value to an analog power control signal and wherein the automatic power control circuit provides the analog power control signal to control the laser driver.
- 16. An optical transmitter, comprising:
a laser diode; a laser driver having a data input for receiving input data and providing a drive signal to the laser diode corresponding to the input data, the drive signal having a modulation level for a high data input logic level and a lower bias level for a low input logic level; a laser diode power monitoring photodiode providing a laser power monitoring signal; and an automatic power control circuit coupled to receive the laser power monitoring signal, the automatic power control circuit comprising a first comparator for comparing the laser power to a modulation reference level, a second comparator for comparing the laser power to a bias reference level, a control circuit, coupled to the first and second comparators, for providing a digital modulation power control value corresponding to the difference between the laser power for a high input data logic level and the modulation reference level and a digital bias power control value corresponding to the difference between the laser power for a low input data logic level and the bias reference level, the automatic power control circuit controlling the modulation level of the laser driver drive signal in response to the digital modulation power control value and controlling the bias level of the laser driver drive signal in response to the digital bias power control value.
- 17. An optical transmitter as set out in claim 16, wherein said control circuit comprises a clock input for receiving a clock signal in phase with the input data.
- 18. An optical transceiver, comprising:
a transmitter comprising a laser diode providing modulated optical signals, a laser driver coupled to a data input and providing a drive signal to the laser diode corresponding to the input data, a laser diode power monitoring photodiode providing a laser power monitoring signal, and digital power control means for comparing the laser power monitoring signal to a reference value, deriving digital power adjustment values corresponding to the difference, controlling the laser driver based on the adjustment values, and storing the digital power adjustment values; and a receiver comprising a front end coupled to receive input modulated light from an optical fiber and providing a corresponding digital electrical signal and a back end coupled to receive the digital electrical signal and provide output clock and data signals.
- 19. A burst mode optical data transmission system, comprising:
a plurality of transmitters providing burst mode modulated optical signals, each of said transmitters including optical power monitoring means for monitoring the output optical power and digital power control means for controlling the optical power based on the difference between the monitored output optical power and a reference value, the digital power control means including means for storing a digital value corresponding to the control between bursts; at least one optical fiber optically coupled to the transmitters; and a receiver optically coupled to the fiber and receiving the burst mode modulated optical signals.
- 20. A method for transmitting data over an optical network in a burst mode, comprising:
providing modulated light to an optical fiber in a burst, the burst comprising a plurality of data bits; monitoring the output optical power of the modulated light; comparing the monitored output optical power to a reference value; deriving a digital adjustment value based on the difference between the monitored output optical power and the reference value; controlling the optical power based on the digital adjustment value; placing the transmitter in a low power sleep mode after transmission of the burst; and storing the digital adjustment value until transmission of the next burst.
RELATED APPLICATION INFORMATION
[0001] The present application claims priority under 35 USC 119 (e) of provisional application serial No. 60/230,130 filed Sep. 5, 2000 the disclosure of which is incorporated herein by reference.
Provisional Applications (1)
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Number |
Date |
Country |
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60230130 |
Sep 2000 |
US |