阅读说明：本技术 高速光信号发射器件的壳体组件及高速光信号发射器件 (Shell assembly of high-speed optical signal emitting device and high-speed optical signal emitting device ) 是由 鞠兵 维卡斯·马南 赖人铭 于 2021-09-23 设计创作，主要内容包括：本发明涉及一种高速光信号发射器件的壳体组件及高速光信号发射器件,壳体组件包括壳体、热沉基板、激光器和驱动芯片,热沉基板、激光器和驱动芯片封装于壳体内,激光器和驱动芯片按照壳体的轴线方向相邻放置于热沉基板。本发明将驱动芯片和激光器相邻放置安装于热沉基板,并封装于壳体中,使二者连接线路尽可能的短,避免了驱动芯片和半导体激光器之间长的走线,降低了长的走线带来的寄生电感和寄生电容,提高了光发射器件的使用带宽,使得高速光信号发射器件能容易地工作在25Gb/s及以上速率,更适合应用于高速率光通信设备。同时,本发明采用了没有转折的直线光路设计,减少一部分光转折元件和工序,有效降低了高速光信号发射器件的成本。(The invention relates to a shell assembly of a high-speed optical signal emitting device and the high-speed optical signal emitting device. The driving chip and the laser are adjacently arranged on the heat sink substrate and are packaged in the shell, so that the connecting circuit of the driving chip and the laser is as short as possible, long wiring between the driving chip and the semiconductor laser is avoided, parasitic inductance and parasitic capacitance caused by the long wiring are reduced, the use bandwidth of the light emitting device is improved, the high-speed optical signal emitting device can easily work at the speed of 25Gb/s or above, and the high-speed optical signal emitting device is more suitable for being applied to high-speed optical communication equipment. Meanwhile, the invention adopts the design of a straight light path without turning, reduces a part of light turning elements and working procedures, and effectively reduces the cost of the high-speed optical signal transmitting device.)

1. A shell assembly of a high-speed optical signal emitting device is characterized in that the shell assembly works at a speed of 25Gb/s or above and comprises a shell, a heat sink substrate, a laser and a driving chip, wherein the heat sink substrate, the laser and the driving chip are packaged in the shell, and the laser and the driving chip are adjacently placed on the heat sink substrate according to the axial direction of the shell.

2. The housing assembly of claim 1, wherein the laser is soldered or glued to the conductive pattern on the surface of the heat sink substrate by means of gold-tin soldering, and the driving chip is glued to the heat sink substrate by means of conductive glue.

3. The housing assembly of claim 1, wherein the housing is provided with a through pin for transmitting internal and external signals, the driving chip receives an input control signal through the through pin and outputs a driving signal to the laser, the laser is driven to emit light according to the control signal, and a bonding pad on the driving chip for outputting the driving signal is disposed adjacent to the laser.

4. The housing assembly of claim 3, wherein the housing comprises a header and a housing cover, the header and the housing cover combining to form a sealed space inside the housing;

the collector head is embedded with a plurality of the penetrating pins, the inner side of the collector head is provided with a step, and the step is used for fixing the heat sink substrate;

the shell cover is embedded with an optical lens, the optical lens and the laser are coaxially arranged, and the optical lens is used for collecting light rays in the shell cover and is used as an outlet for outward transmission of the light rays.

5. The housing assembly of claim 4, wherein the heat sink substrate is further fixedly connected with a heating resistor, the heating resistor is disposed close to the laser, and the heating resistor is used for heating the laser.

6. The housing assembly of claim 5, wherein the heating resistor is heated by applying current through the PIN of the header, or the heating resistor is heated by applying control voltage to the driving chip through the PIN of the header and then applying current through the driving chip.

7. The housing assembly of claim 1, wherein the housing is a TO-CAN housing or a BOX housing.

8. The housing assembly of a high-speed optical signal transmitter as claimed in any one of claims 1 to 7, wherein the heat sink substrate is provided with an isolation groove, the isolation groove is a strip-shaped groove, and the isolation groove is used for thermal isolation between the driver chip and the laser.

9. A housing assembly for a high speed optical signal emitting device according to any one of claims 1-7, wherein a photodetector is further disposed in the housing, and the photodetector is mounted on the driving chip for monitoring the backward emission of the laser, or the photodetector is mounted in front of the side of the laser for monitoring the forward emission of the laser.

10. A high speed optical signal transmitting device, comprising a connector for interfacing with an external optical fiber connector, a mounting ring for coupling soldering between the connector and the housing, a flexible circuit board for connecting a main board of an optical transceiver module, and a housing assembly of the high speed optical signal transmitting device according to any one of claims 1 to 9.

Technical Field

The invention relates to the technical field of laser diodes, in particular to a shell assembly of a high-speed optical signal emitting device and the high-speed optical signal emitting device.

Background

The high-speed optical signal Transmitter (TOSA) and the Driver chip (Driver) of the semiconductor Laser (LD) commonly used in the optical transceiver module for high-speed optical fiber communication are both disposed on the circuit board of the optical transceiver module. The Driver chip (Driver) is connected to a light emitting device (TOSA) through a flexible circuit board (FPC), and drives a semiconductor Laser (LD) in the TOSA. The driving chip (Driver) is mainly used for coupling the direct current bias current of the semiconductor Laser (LD) with the high-frequency modulation current and providing the modulated driving current for the semiconductor Laser (LD). Meanwhile, the driving chip (Driver) can also amplify an input signal and control the direct current bias current and the high-frequency modulation current so as to enable the laser to be in an optimal working state.

In the prior art, a semiconductor Laser (LD) and a Driver chip (Driver) are respectively located in an optical module motherboard and a Transmitter Optical Subassembly (TOSA), the Laser (LD) and the Driver chip (Driver) are connected by a Flexible Printed Circuit (FPC), and the wiring between the semiconductor Laser (LD) and the Driver chip (Driver) is very long. With the increasing optical communication rate, the problem that the quality of high-frequency signals is affected by parasitic inductance, parasitic capacitance, impedance mismatching and the like easily generated by long high-frequency signal wiring is solved, the operating bandwidths of a driving chip and a semiconductor laser are reduced, and the performance of a light emitting device is affected.

Disclosure of Invention

The invention aims to: aiming at the problems that the wiring between a semiconductor Laser (LD) and a drive chip (Driver) is very long, the parasitic inductance is easily generated by the long high-frequency signal wiring, the high-frequency signal quality is affected by the mismatching of parasitic capacitance and impedance, the operation bandwidths of the drive chip and the semiconductor laser are reduced, and the performance of a light emitting device is affected, the shell assembly of the high-speed light signal emitting device and the high-speed light signal emitting device are provided, the drive chip (Driver) and the semiconductor Laser (LD) are adjacently placed and are packaged in a shell of the light emitting device together, the lead length between the drive chip and the semiconductor laser is shortened as much as possible, and the high-frequency signal quality is improved.

In order to achieve the purpose, the invention adopts the technical scheme that:

a shell assembly of a high-speed optical signal emitting device works at a speed of 25Gb/s and above, and comprises a shell, a heat sink substrate, a laser and a driving chip, wherein the heat sink substrate, the laser and the driving chip are packaged in the shell, and the laser and the driving chip are adjacently placed on the heat sink substrate according to the axial direction of the shell.

According to the shell assembly of the high-speed optical signal emitting device, the driving chip and the laser are adjacently placed, and the driving chip and the laser are mounted on the heat sink substrate together and are packaged in the shell, so that the connection circuit of the driving chip and the laser is as short as possible. The high-speed optical signal transmitting device has the advantages that long wiring between the driving chip and the semiconductor laser is avoided, parasitic inductance and parasitic capacitance caused by the long wiring are reduced, the problem that the high-frequency signal quality is affected due to the fact that the parasitic inductance, the parasitic capacitance, impedance mismatch and the like is solved, the use bandwidth of the optical signal transmitting device is improved, the high-speed optical signal transmitting device can easily work at the speed of 25Gb/s and above, and the high-speed optical signal transmitting device is more suitable for being applied to high-speed optical communication equipment. Meanwhile, the driving chip and the semiconductor laser are arranged along the axial direction of the shell, a straight light path design without turning is adopted, the structure is relatively simple, a part of light turning elements and corresponding mounting procedures are reduced, and the overall cost of the device is effectively reduced.

As a preferred scheme of the invention, the driving chip and the semiconductor laser are connected in a gold wire bonding mode, so that the connection line of the driving chip and the semiconductor laser is as short as possible.

As a preferable aspect of the present invention, the laser is soldered or glued to the conductive pattern on the surface of the heat sink substrate by gold-tin soldering, and the driving chip is glued to the heat sink substrate by conductive glue.

As a preferred scheme of the present invention, the housing is provided with a penetration pin for transmitting internal and external signals, the driving chip receives an input control signal through the penetration pin and outputs a driving signal to the laser, the laser is driven to emit light according to the control signal, and a routing pad for outputting the driving signal on the driving chip is disposed adjacent to the laser, so that a connection line between the driving chip and the semiconductor laser is shortest.

As a preferable scheme of the invention, the shell comprises a collector head and a shell cover, and the collector head and the shell cover are combined to form a sealed space inside the shell;

the collector head is embedded with a plurality of the penetrating pins, the inner side of the collector head is provided with a step, and the step is used for fixing the heat sink substrate;

the shell cover is embedded with an optical lens, the optical lens and the laser are coaxially arranged, a straight line light path design without turning is adopted, and the optical lens is used for collecting light rays in the shell cover and is used as an outlet for outward transmission of the light rays.

As a preferred scheme of the present invention, the heat sink substrate is further fixedly connected with a heating resistor, the heating resistor is disposed close to the laser, and the heating resistor is used for heating the laser. So that the laser can operate normally at very low ambient temperatures.

In a preferred embodiment of the present invention, the heating resistor is heated by applying current to the PIN of the header.

As a preferred embodiment of the present invention, the heating resistor applies a control voltage to the driving chip through the PIN of the header, and then the driving chip applies a current to heat the heating resistor. Through this kind of mode, can prevent the electric current that increases on the PIN needle, the electromagnetic radiation interference that brings also prevents that the too big heat that produces of PIN needle electric current from leading to the micro-deformation of collector head.

As a preferable scheme of the invention, the shell is a TO-CAN shell or a BOX shell.

As a preferred scheme of the present invention, the heat sink substrate is provided with an isolation groove, the isolation groove is a strip-shaped groove, and the isolation groove is used for achieving thermal isolation between the driver chip and the laser, and reducing thermal interference between the driver chip and the laser.

As a preferable scheme of the present invention, a photodetector is further disposed in the housing, and the photodetector is mounted on the driving chip for monitoring the backward light emission of the laser.

As a preferable scheme of the invention, a photoelectric detector is further arranged in the shell, and the photoelectric detector is mounted in front of the laser in side direction and used for monitoring forward light emission of the laser. By adopting a forward optical power monitoring mode, the photoelectric detector can be prevented from being arranged on the driving chip, and the driving chip is effectively protected. In addition, the forward photoelectric detector monitors the forward optical power emitted by the laser, and the optical power monitoring accuracy is higher.

The invention also discloses a high-speed optical signal transmitting device, which comprises a joint, a mounting ring, a flexible circuit board and any shell assembly of the high-speed optical signal transmitting device, wherein the joint is used for butting with an external optical fiber connector, the mounting ring is used for coupling and welding the joint and the shell, and the flexible circuit board is used for connecting a mainboard of an optical transceiver module.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

1. according to the shell assembly of the high-speed optical signal emitting device, the driving chip and the laser are adjacently placed, and the driving chip and the laser are mounted on the heat sink substrate together and are packaged in the shell, so that the connection circuit of the driving chip and the laser is as short as possible. The high-speed optical signal transmitting device has the advantages that long wiring between the driving chip and the semiconductor laser is avoided, parasitic inductance and parasitic capacitance caused by the long wiring are reduced, the problem that the high-frequency signal quality is affected due to the fact that the parasitic inductance, the parasitic capacitance, impedance mismatch and the like is solved, the use bandwidth of the optical signal transmitting device is improved, the high-speed optical signal transmitting device can easily work at the speed of 25Gb/s and above, and the high-speed optical signal transmitting device is more suitable for being applied to high-speed optical communication equipment. Meanwhile, the driving chip and the semiconductor laser are arranged along the axial direction of the shell, a straight light path design without turning is adopted, the structure is relatively simple, a part of light turning elements and corresponding mounting procedures are reduced, and the overall cost of the device is effectively reduced.

2. The heat isolation groove is designed on the heat sink substrate, so that the heat isolation between the driving chip and the laser can be realized, and the thermal interference between the driving chip and the laser is reduced. The heat sink substrate can also realize the routing of electric signals, and the high-frequency electric signal routing on the substrate can realize good high-frequency electric signal impedance matching with the input of the driver and the pins of the tube seat, thereby further improving the use bandwidth of the light emitting device.

3. The invention adopts a forward optical power monitoring mode, can avoid mounting the photoelectric detector on the driving chip and effectively protects the driving chip. In addition, the forward photoelectric detector monitors the forward optical power emitted by the laser, and the optical power monitoring accuracy is higher.

4. The laser heating device is provided with the heating resistor for heating the laser, so that the laser can normally work at a very low ambient temperature. The heating resistor firstly adds control voltage to the driving chip through the PIN needle of the header, then the driving chip adds current to realize heating, the laser which originally works at the lowest temperature of about 0 ℃ can work at the low temperature of-40 ℃ and below so as to support the application of industrial temperature, the increased current on the PIN needle is prevented, the electromagnetic radiation interference is brought, and the PIN needle is prevented from generating heat due to overlarge current to cause the micro deformation of the header.

Drawings

Fig. 1 is a schematic three-dimensional structure diagram of a high-speed optical signal emitting device in embodiment 1 of the present invention;

fig. 2 is a schematic diagram illustrating a high-speed optical signal transmitting device according to embodiment 1 of the present invention;

fig. 3 is a schematic structural diagram of a housing assembly of a high-speed optical signal transmitting device in embodiment 1 of the present invention;

FIG. 4 is a first schematic structural view of a header assembly according to embodiment 1 of the present invention;

FIG. 5 is a second schematic structural view of a header assembly in embodiment 1 of the present invention;

fig. 6 is a schematic view of an internal structure of a housing assembly in which a heat sink substrate, a driver chip, a laser, and a photodetector are placed at a header in embodiment 1 of the present invention;

fig. 7 is a schematic structural view of a heat sink substrate placed on a header in embodiment 1 of the present invention;

FIG. 8 is a view showing the connection of the gold wire between the inside of the housing assembly and the through-needle in example 1 of the present invention;

fig. 9 is a schematic diagram of an optical path output to an external optical fiber of a high-speed optical signal transmitting device in embodiment 1 of the present invention;

fig. 10 is a schematic view illustrating connection between a flexible printed circuit board and a through pin in embodiment 1 of the present invention;

fig. 11 is a schematic view of the inside of a housing assembly in which a heat sink substrate, a driver chip, a laser, a heating resistor, and a photodetector are placed at a header in embodiment 2 of the present invention;

fig. 12 is a view showing the connection of the gold wire between the inside of the housing assembly and the through-needle in embodiment 2 of the present invention.

Icon: 1-light emitting device, 11-shell, 12-connector, 13-mounting ring, 14-flexible circuit board, 2-optical fiber connector, 3-optical transceiver module, 31-main board, 111-header, 1111-header shell, 1112-PIN PIN, 1113-RF PIN PIN, 1114-PIN not penetrating through the shell, molten glass, 112-shell cover, 1121-shell cover shell, 1122-optical lens, 1131-heat sink substrate, 11311-conductive pattern, 11312-routing pad group, 1132-laser, 1133-driving chip, 1134-heating resistor, 1141-photoelectric detector substrate, 1142-photoelectric detector and 121-optical isolator.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings.

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Example 1

The light emitting device 1 provided by the invention works at a speed of 25Gb/s or above, mainly comprises 4 components, a shell TO-CAN 11, a connector accept 12, a mounting ring Z-ring 13 and a flexible circuit board FPC 14, and the appearance of the light emitting device is shown in figure 1. The shell TO-CAN 11 is used for packaging electronic elements and optical devices; the connector Receptacle 12 is used for being butted with the external optical fiber connector 2; the mounting ring Z-ring 13 is used for coupling welding between the connector Receptacle 12 and the shell TO-CAN 11; the flexible circuit board FPC 14 is used to connect the main board 31 of the optical transceiver module 3.

The light emitting device 1 is used in a manner of being placed in the optical transceiver module 3 for transmission of an optical signal, and one light emitting device is used as shown in fig. 2. One end of the connector Receptacle 12 is connected with the external optical fiber connector 2, and one end of the flexible circuit board FPC 14 is welded on the mainboard 31 to receive input signals and control voltage.

The structure body of the shell TO-CAN assembly of the light emitting device 1 comprises a Header TO-Header111 and a shell cover TO-Cap112, wherein the Header TO-Header111 and the shell cover TO-Cap112 are combined TO form a sealed space inside the shell, and the shell assembly of the light emitting device is shown in figure 3. The TO-Header111 shell 1111 is made of metal, and the surface of the TO-Header111 shell is plated with gold. Internal structure of Header TO-Header Assembly As shown in FIG. 4, Header TO-Header111 has 4 or more round metal PIN PINs 1112 penetrating through housing 1111 for DC electrical connection, 2 round metal PIN PINs 1113 penetrating through housing 1111 for high frequency signal input, and 2 round metal PIN PINs 1114 not penetrating through housing 1111. PIN needles 1112 and 1113 are gold-plated, and the inner end and the outer end of the PIN needles are respectively used for internally bonding a gold wire and externally welding the PIN needles with a Flexible Printed Circuit (FPC) 15, so that the TO-CAN 11 of the shell is electrically conducted inside and outside. The shell 1111 is isolated from the PIN 1112 and the PIN 1113 by molten glass 1115 to prevent short circuits. PIN 1114 is gold plated and soldered to housing 1111 as a common ground PIN. All PIN lengths can be designed according TO specific product requirements, and the external schematic of the Header TO-Header assembly is shown in fig. 5. The shell cover TO-Cap112 comprises a metal shell 1121 and an optical lens 1122, wherein the optical lens 1122 is coated with an antireflection film and is used as an optical path outlet of the shell cover TO-Cap112 for converging light and sealing the shell cover TO-Cap 112. The optical lens 1122 and the metal housing 1121 are bonded together by glue. The metal shell 1121 of the case cover TO-Cap and the shell 1111 of the Header TO-Header111 are welded together by resistance welding and require airtightness, and the external schematic view of the Header TO-Header assembly and the case cover TO-Cap assembly after assembly is shown in FIG. 3.

The components inside the TO-CAN housing are schematically shown in FIG. 6. The inside of the Header TO-Header111 is provided with a step for securing TO the heat sink substrate 1131. The laser 1132 and the driver chip 1133 are placed adjacent to each other and mounted on the heat sink substrate 1131. A photodetector 1142 is also mounted within the housing TO-CAN 11 for monitoring the luminous power of the semiconductor laser 1132.

The heat sink substrate 1131 is glued TO Header TO-Header111 as shown in FIG. 7. The heat sink substrate 1131 requires a relatively precise thickness control in order TO position the light bar of the laser 1132 on the optical axis of the housing TO-CAN. The heat sink base plate 1131 is made of a ceramic material with good thermal conductivity, and preferably, the ceramic material is A1N ceramic material, which is beneficial for heat dissipation. Preferably, the heat sink substrate 1131 may be fabricated with a thermal isolation groove 11312, which can achieve thermal isolation between the driver chip 1133 and the laser 1132, and reduce thermal interference between the driver chip 1133 and the laser 1132. The heat sink substrate 1131 is further plated with a conductive pattern 11311 that can implement electrical signal routing, and the conductive pattern 11311 can be used for welding a laser, and when one pole (for example, an N pole or a P pole) of the laser is welded on the conductive pattern, the N pole at the bottom of the laser can be led out onto the conductive pattern 11311 through the conductive pattern 11311. The conductive pattern 11311 may also implement a relatively precise impedance design, so that the high-frequency electrical signal traces on the heat sink substrate 1131 may achieve a good impedance match with the input of the driver and the RF pins of the socket, and the high-frequency electrical signal traces on the heat sink substrate 1131 may ensure an impedance match with the RF pins of the socket.

The semiconductor laser 1132 converts the electrical signal into an optical signal, and emits the optical signal, and the optical signal is soldered or adhered to the conductive pattern 11311 on the surface of the heat sink substrate 1131 by gold-tin soldering. The laser P electrode is connected to the output anode of the driver chip 1133 by a gold wire w 2. The upper surface of the driving chip 1133 is provided with a routing bonding pad group 11331, the PIN 1112 and the PIN 1113 which correspond TO the Header TO-Header111 are in routing connection, gold wires w3 and w4 are used for inputting high-frequency signals, and gold wires w5, w6 and w7 are used for inputting electric signals TO control the bias current, the signal modulation current and the signal gain of the semiconductor laser. Gold wires w1 and w2 are used to output a drive signal to the semiconductor laser 1132, and the drive chip 1133 is also attached to the heat sink substrate 1131 by a conductive adhesive.

The photodetector 1142 is configured to receive laser light emitted by the semiconductor laser 1132, monitor a light emitting power of the semiconductor laser 1132, and feed back the light emitting power to the processor of the motherboard 31, where the processor adjusts the light emitting power of the semiconductor laser 1132 by controlling a voltage of the driving chip 1133, and keeps an output power thereof constant. The photodetector 1142 may be attached to the upper surface of the driving chip 1133 by a non-conductive adhesive to monitor the backward light emission of the semiconductor laser 1132, and preferably, the photodetector 1142 may also be mounted in front of the side of the semiconductor laser 1132 to monitor the forward light emission. The photodetector 1142 electrodes are connected to the corresponding PIN 1112 and common ground through w8, w9, respectively. The TO-CAN package internal and through-pin gold wire connections are shown in FIG. 8.

The metal housing 1121 of the case cover TO-Cap and the housing 1111 of the Header TO-Header111 are welded together by resistance welding. The light from the semiconductor laser 1132 is emitted in the direction of the center axis of the TO-CAN housing, and the optical lens 1122 focuses the light beam, which is output in a converged form TO the TO-CAN assembly 11. After the connector Receptacle 12 and the shell TO-CAN 11 are optically coupled and aligned, the connector Receptacle 12 and the mounting ring Z-ring 13 are subjected TO laser welding, the mounting ring Z-ring 13 and the shell TO-CAN 11 are subjected TO laser welding, and the optical path is shown in FIG. 9. An optical isolator 121 is included on the tap Receptacle 12 optical path to prevent reflected light in the fiber optical path from interfering with the semiconductor laser 1132. After the optical fiber connector is butted with the connector Receptacle 12, light beams can be introduced into the optical fibers for propagation. Because the design of a straight light path without turning is adopted, the structure is relatively simple, and simultaneously, a part of light turning elements and corresponding mounting procedures are reduced.

In addition, the flexible circuit board FPC 14 is soldered TO the PIN on the back surface of the TO-CAN 11 of the housing at a corresponding position TO complete the assembly of the light emitting device, and a schematic diagram of the connection of the flexible circuit board and the through PIN is shown in fig. 10.

Example 2

The light emitting device 1 of the present invention is the same as example 1 in the Header TO-Header111 and the Cap TO-Cap112 of the CAN TO-CAN of embodiment 2 as shown in fig. 3, 4 and 5. The schematic diagram of the components inside the TO-CAN housing is shown in FIG. 11. On Header TO-Header111 is placed a heat sink substrate 1131. The laser 1132 and the driver chip 1133 are placed adjacent to each other and mounted on the heat sink substrate 1131. A heater resistor 1134 is also disposed on the heatsink substrate 1131.

The heat sink substrate 1131 is adhered TO the Header TO-Header111 by glue, the semiconductor laser LD 1132 is soldered or adhered TO the conductive pattern 11311 on the surface of the heat sink substrate 1131 by gold-tin soldering, and the driving chip 1133 is also adhered TO the heat sink substrate 1131 by conductive adhesive. A photodetector 1142 is mounted in front of the side of the semiconductor laser 1132 to monitor forward light emission.

The heating resistor 1134 is attached to the heat sink substrate 1131 by glue at a position close to the laser 1132, and is used for heating the laser 1132 to raise the temperature, so that the laser 1132 can normally work at a very low ambient temperature. The heating resistor 1134 can be heated by applying current TO the PIN on the Header TO-Header111, and preferably, the heating resistor 1134 can also be heated by applying control voltage TO the driving chip 1133 through the PIN on the Header TO-Header111 and then applying current TO the driving chip 1133.

The TO-CAN package internal and through-pin gold wire connections are shown in FIG. 12. The P electrode of the semiconductor laser LD 1132 is connected to the output anode of the driving chip 1133 through a gold wire w 2. The upper surface of the driving chip 1133 is provided with a routing bonding pad group 11331, the PIN 1112 and the PIN 1113 which correspond TO the Header TO-Header111 are in routing connection, gold wires w3 and w4 are used for inputting high-frequency signals, and gold wires w6 and w7 are used for inputting electric signals and controlling bias current, signal modulation current and signal gain of the semiconductor laser. Gold wires w1 and w2 are used to output a drive signal to the semiconductor laser 1132, and the drive chip 1133 is also attached to the heat sink substrate 1131 by a conductive adhesive. The photodetector 1142 electrodes are connected to the corresponding PIN 1112 and common ground through w8, w9, respectively. One end of the heating resistor 1134 is connected to the common ground through w10, and the other end is connected to a bonding pad on the upper surface of the driving chip 1133 through w11 to provide current for the heating resistor 1134, and the other bonding pad on the upper surface of the driving chip 1133 is connected to the corresponding PIN 1112 through w12 to provide a control voltage required by the driving chip 1133 to apply current to the heating resistor 1134.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.