DE10244700A1 - Operating point stabilization for laser transmitter in optical telecommunications system provided by temperature regulation device controlled for maintaining required laser transmitter oscillation frequency - Google Patents

Abstract

The operating point stabilization is provided by a temperature regulation device (60) with a heat source/sink and a temperature sensor, supported in good thermal contact with the laser transmitter (40) and an associated control unit (50), allowing the temperature of the laser transmitter to be adjusted for maintaining the required oscillation frequency of the laser transmitter. An Independent claim for an operating point stabilizer for a laser transmitter is also included.

Description

FIELD OF THE INVENTION

The present invention relates to an inexpensive Operating point stabilization of an optical laser transmission device, the for Telecommunication systems is suitable; Such a laser transmission device find e.g. in the form of (DFB) laser diodes used in optical transmission networks.

BACKGROUND THE INVENTION

The 7 shows a typical basic structure of a telecommunications transmission network in the subscriber-near area, in which the signals of different communication stations 12-1 to 12-7 with a multiplex method (time division multiplex, frequency division multiplex) over a network 10 be transmitted. Multiple communication stations 12-1 to 12-7 are via optical branch lines 14-1 to 14-7 with the optical network 10 connected. A main station 12-1 in this case communicates with all connected substations 12-2 to 12-7 , In order to ensure a consistently good transmission quality between all secondary stations and the main station, it is important that the transmission properties of the secondary stations in particular are stabilized. In addition to the electrical properties of the secondary stations (electrical frequency response, jitter, signal shape ...), the optical properties such as output power and frequency of the optical laser transmitter are particularly important. It is common practice to use laser transmission devices with temperature control units (eg thermoelectric coolers) integrated in the transmission module in the case of high demands on the transmission quality. 5 shows an example of the structure of a conventional laser transmission unit, consisting of the light-emitting semiconductor chip 93 , the optical fiber 95 who with the network 10 is connected to the temperature sensor 94 , possibly a mounting plate 92 and the thermoelectric element 91 , All elements 91 to 95 are in one housing 90 united. The Elements 91 . 92 and 94 form the temperature control unit.

With the help of these temperature control units and suitable control electronics, one can check the chip temperature of the laser transmitter even with a larger variance the housing temperature the laser transmission device at a constant temperature level hold what a stabilization of the output parameters of the laser transmission device (output power and frequency). The temperature control unit allows this to cool the chip as needed or to warm. The disadvantage of this in the housing the laser transmission device built-in temperature control unit is that the cost of the laser emitter well above the cost of a non-temperature-controlled laser transmission device and the required housing one significantly increased Requires space (volume). The high cost of a laser transmission device with integrated temperature control unit prevent the use of this Laser emission devices in price-sensitive applications, at which the requirements for the constancy of the output parameters of the Transmission laser do not justify the additional expenses.

SUMMARY THE INVENTION

It is the object of the invention to specify an operating point stabilization for laser transmission devices that in price-sensitive cases an inexpensive Stabilization of the output parameters of the laser transmission device allows.

According to the invention, a tempering integrated in the laser transmission device is dispensed with. Rather, one is external to the housing of the laser transmission device attached tempering suggested the most cost effective If only allowed, the laser transmission device to warm up. Here, only a very inexpensive heat generator (electrical resistance, Transistor ...) required, the thermal with the laser emitter is associated. The chip temperature of the laser can either indirectly via one thermally with the case the temperature sensor connected to the laser transmitter (NTC, PTC, diode ...) can be determined or directly via the Measurement of the electrical voltage across the chip of the laser transmitter with a defined one Electricity. An electronic control device provides the generated in the heat generator heat output so that the one you want Chip temperature and thus the desired Output parameters (optical power, optical frequency) of the laser transmission device be achieved.

DESCRIPTION THE DRAWINGS

1 Fig. 12 is a schematic block diagram showing a general structure of a first embodiment of the invention.

2 Fig. 12 is a schematic block diagram showing a general structure of external tempering.

3 Fig. 12 is a schematic block diagram showing a general structure of a controller

4 Fig. 12 is a schematic block diagram showing a general structure of a second embodiment of the controller.

5 Fig. 12 is a schematic block diagram showing a general structure of a general laser emitting unit with an integrated temperature control device.

6 gives the connection between the chip voltage of the laser transmission unit as a function of the chip temperature / wavelength with a permanently impressed current

7 is a schematic block diagram of an optical transmission network in the near-subscriber area.

DETAILED DESCRIPTION OF THE INVENTION

In the following, embodiments of the present invention with reference to the accompanying drawings in detail described.

The 1 Fig. 12 is a schematic block diagram showing a general structure of a first embodiment of the invention. The reference number 40 denotes a laser emission device, which serves to generate transmission light of a certain power and frequency, which is modulated with the signal to be transmitted and that of the optical network 10 is fed.

The reference number 60 represents an external temperature control device thermally connected to the housing of the laser transmitter device, consisting of a heat source and / or heat sink and possibly a temperature sensor. The reference symbol 50 represents a controller that controls the temperature control device in order to achieve a chip temperature of the laser transmission device that is largely constant with changing operating temperatures.

2 shows a possible structure consisting of the laser transmitter 40 and the temperature control unit 60 that come from a heat source and / or heat sink 62 , a temperature sensor 64 and a mounting plate 65 exists for a thermally good contact of all assembled components 40 . 62 and 64 provides. The heat / cooling capacity generated in the heat source / sink is via the mounting plate 65 on the housing of the laser transmitter unit 40 transfer. The temperature sensor 64 measures the current mounting plate temperature. With a suitable design of the laser transmitter unit 40 can on the mounting plate 65 can also be completely dispensed with. Then the elements 40 and 62 directly connected to each other.

3 describes an analog operated simple control for the arrangement 1 , A bridge circuit formed from the resistors 71 . 72 . 73 and the temperature sensor 64 delivers a differential voltage with a control amplifier 75 intensifies on a heat source - and sink 62 , for example a thermoelectric element is given. The dynamic behavior comes with the elements 77 and 78 affected.

In the regulated state, as much electrical energy is supplied to the heat source and sink until the bridge voltage becomes zero. The desired temperature can be achieved with the resistors 72 and 73 be specified.

Another embodiment shows 4 ,

Instead of an analog one, a digital regulation is proposed here, which forms the electrical voltage typical for the temperature of the housing of the laser transmission device via the voltage divider, consisting of the temperature sensor 64 and the resistance 81 , via an analog / digital converter 82 a microcontroller 83 feeds, which in turn via a digital / analog converter 84 the heat source / sink 62 controls. The program code of the microcontroller essentially simulates the analog control 3 from.

The indirect temperature control described in this invention with a temperature control device connected externally to the housing of the laser transmission device initially has some disadvantages from a technical point of view compared to the internal temperature stabilization of the laser transmission device which is customary in the prior art 5 , Here is the heat source / sink 91 between the chip carrier 92 and the housing 90 , The temperature sensor 94 is also inside the case near the chip 93 arranged on the chip carrier. The glass fiber 95 represents the optical output to the network. The advantage of this arrangement is that one only has to supply the heat source / sink with a comparatively low electrical power in order to get the chip at a given power loss Pv, which is a first approximation of the average over time current Ibias flowing current multiplied by the electrical voltage Ubias occurring across the laser chip minus the optical power emitted from the chip Popt results.

However, this technical implementation is commercial very complex, which is a much higher price than laser emitting devices conditional without internal temperature control.

In contrast, the invention proposes a comparatively inexpensive not to use internally temperature-controlled laser transmitter and externally with a temperature control device that meets the applications to complete.

From a technical point of view, the external temperature control device initially has the disadvantage that, as a rule, higher electrical powers have to be supplied than with internal temperature control. Furthermore, the temperature of the laser chip can only be detected indirectly with an external temperature sensor, since a temperature gradient results from the chip power loss multiplied by the thermal resistance between the chip and the housing. With today's means of signal processing in microcontrollers, however, this temperature gradient can be calculated if the thermal resistance is known. If, on the other hand, the chip power loss is constant during use, the temperature gradient nothing but an offset, ie the chip temperature is always higher than the housing temperature by a defined temperature ΔT.

A constant chip power loss always results when the laser current and the voltage above the Laser chip is constant. A constant voltage at a given one Laser current arises in particular at a constant laser chip temperature a what is generally implied by the invention.

This also opens up another possibility of directly recording the chip temperature more precisely:
At a constant current, the laser voltage is a function of the chip temperature. 6 shows a possible connection. If this characteristic curve is known or has been determined, the temperature of the laser chip can then be determined via the voltage across the laser chip. In this case, the laser chip also becomes a temperature sensor.

Since the frequency (wavelength) of the Laser light is also dependent on the chip temperature, can be determined by the voltage across the Finally, laser chip even the frequency (wavelength) of the laser with defined embossing Derive electricity.

In practice, this characteristic can easily with an optical spectrum analyzer as a frequency meter and a voltmeter can be determined when the electrical supplied to the temperature control unit Performance in the desired Range is varied. The characteristic curve obtained in this way can be laser-specific are saved, with which the relationship between laser chip voltage and frequency is calibrated.

The invention is commercially special attractive if instead of a heat source / sink just a heat source is required to keep the laser chip temperature constant.

This is always the case when the target chip temperature above the operating temperature of the laser transmitter is. in this connection needed one instead of a comparatively expensive thermoelectric element just a heat source, an electrical resistor, transistor, etc. can be. With this you can a very inexpensive Stabilization of the operating point of a laser transmitter device that cannot be heated internally to reach.

The required temperature control output can be minimized, if with constructive measures that of the housing the laser emitting unit radiated or emitted heat or Cooling performance reduced becomes. Simple thermal insulation measures with high-heat-insulating Fabrics such as polystyrene or polyurethane in the form of e.g. Covers can be found here size Make improvements.

Claims (7)

Operating point stabilization of a laser transmission device, characterized in that a laser transmission device ( 40 ), for emitting laser transmission light on the one hand with a temperature control unit ( 60 ) from a heat source / sink ( 62 ) a temperature sensor ( 64 ) and assembly equipment ( 60 ) for good thermal coupling of the laser transmission device ( 40 ), the heat source / sink ( 62 ) and the temperature sensor ( 64 ) exists, and on the other hand with tax funds ( 50 ) for setting the temperature control unit ( 60 ) which is based on a measurement result of the temperature control unit ( 60 ) respond, the control means ( 50 ) via the temperature control unit ( 60 ) control the temperature of the laser transmission device such that the oscillation frequency of the laser transmission device is controlled to an optical target frequency. Operating point stabilization of a laser transmission device according to claim 1, characterized in that as a temperature sensor Diode is used. Operating point stabilization of a laser transmission device according to claim 1, characterized in that instead of the external temperature sensor ( 64 ) in the housing of the laser transmission device ( 40 ) Integrated photodiode is used as a temperature sensor. Operating point stabilization of a laser transmission device, characterized in that a laser transmission device ( 40 ), for emitting laser transmission light on the one hand with a temperature control unit ( 60 ) from a heat source / sink ( 62 ) and assembly equipment ( 60 ) for good thermal coupling of the laser transmission device ( 40 ) and the heat source / sink ( 62 ) exists, and on the other hand with tax funds ( 50 ) for setting the temperature control unit ( 60 ) which respond to a voltage which was previously calibrated as a function of the temperature with an impressed current, the control means ( 50 ) via the temperature control unit ( 60 ) control the temperature of the laser transmission device such that the oscillation frequency of the laser transmission device is controlled to an optical target frequency. Operating point stabilization of a laser transmission device according to one of the claims 1 to 4, characterized in that instead of in the temperature control unit a heat source and just lower a heat source is used. Operating point stabilizer of a laser transmission device according to one of the preceding claims, that alongside the oscillation frequency of the laser transmission device also the emitted light output is set to a setpoint. Working point stabilizer of a laser outside Device according to one of the preceding claims, characterized in that, in order to reduce the required thermal output, thermal insulation measures which are provided by the housing of the laser transmitter unit ( 40 ) reduce radiated or emitted heat or cooling capacity.