CN218677156U - TO-CAN packaging device of detector chip - Google Patents

Abstract

The utility model relates TO a TO-CAN packaging device of a detector chip, which comprises a ceramic substrate, a TIA chip, a TO base and a detector chip, wherein the ceramic substrate is eutectic welded on the TO base, and the TIA chip is inversely arranged on the ceramic substrate; the detector chip is attached to the TIA chip, and the cathode of the detector chip is electrically connected with the corresponding metal area on the ceramic substrate; only the IN pin of the TIA chip is connected with the anode of the detector chip through a gold wire, and other pins of the TIA chip are IN contact type electrical connection with the ceramic substrate. The utility model avoids the reduction of the sensitivity of the optical module to receive signals and the bandwidth due to the introduction of too many parasitic parameters by routing in the process of packaging the high-speed detector chip; meanwhile, because the TIA chip and the detector chip are arranged on the ceramic substrate, the ceramic substrate is simultaneously connected with the pins of the TO base, and the heat dissipation effect of increasing the contact area is also realized on the whole device through the arrangement of the metal extension area.

Description

TO-CAN packaging device of detector chip

Technical Field

The utility model relates TO a high speed detector chip technical field specifically is a TO-CAN packaging hardware of detector chip.

Background

With the promotion of novel applications such as cloud computing, mobile internet, internet of things and three-network integration on bandwidth and sensitivity requirements, the optical communication market enters a high-speed development period. The detector chip as the optical signal receiving end is a core optical chip of the optical module receiving end, and has an important strategic position. With the increase of the communication speed of the optical module, the distance is lengthened, the required response time of receiving signals is shortened, and the requirements on receiving end detector devices are higher and higher. At present, in most application scenarios, a detector PD/APD chip and a TIA chip are packaged into a TO-CAN with a limited volume, the detector chip and the TIA chip are subjected TO eutectic soldering on a TO base in a conventional operation, and the detector chip, the TIA chip and each pin of the TO base are connected in a routing mode. With the continuous improvement of the speed, the requirements on the sensitivity of the detector chip and the TIA chip and the packaging and routing are higher and higher under the condition of ensuring that the received signal is not distorted and delayed. Because each chip and TO base pin are more, adopt traditional interconnection routing mode can introduce many parasitic parameters, lead TO sensitivity and bandwidth TO reduce too much when really using, especially in 25Gbps and above high speed optical module, the external parasitic parameter that additionally introduces is more, can lead TO the performance that the optical module received the signal TO descend. Technically, the traditional mode has defects and influences the normal use of the high-speed optical module.

For TO-CAN packaging of detector chips: document CN212461686U adopts a gold wire bonding mode TO connect the probe and the TO base when the probe is packaged, that is, both adopt a gold wire bonding mode TO connect, and document CN214954233U sets the TO base when the optical module is constructed, and connects the conducting strip and the TO base for realizing a circuit path.

At present, in a traditional TO-CAN packaging mode of a detector chip, a PD/APD chip and a TIA chip are respectively eutectic-welded on a TO base, and then each chip and a pin of the TO base are interconnected in a metal routing mode. Because the detector chip, TIA chip and TO base pin are in large quantity, the position arrangement is compact and the distance is limited, at least more than ten TO twenty lines with different quantity and length need TO be marked in order TO achieve the interconnection in use by a routing mode, although the TO-CAN packaging is airtight packaging, the shaking and falling in the use process and long time later, gold lines CAN collapse and be connected TO cause short circuit of individual pins, thereby causing the invalidation and scrapping of optical modules. These are potential risks. The metal routing interconnection process needs special equipment, needs to be loaded and unloaded to be transported after chip surface mounting is completed, and manually and man-hour go to complete the routing process, and because the pins are closely arranged, the space is small, and the inconvenience of the process can also cause the loss of the yield.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is TO provide a TO-CAN packaging hardware of detector chip CAN solve partial defect among the prior art at least.

In order to achieve the above object, the embodiment of the present invention provides the following technical solutions: a TO-CAN packaging device of a detector chip comprises a ceramic substrate, a TIA chip, a TO base and the detector chip, wherein the ceramic substrate is eutectic-welded on the TO base, and the TIA chip is inversely arranged on the ceramic substrate; the detector chip is attached to the TIA chip, and the cathode of the detector chip is electrically connected with the corresponding metal area on the ceramic substrate; and only the IN pin of the TIA chip is connected with the anode of the detector chip through a gold wire, and other pins of the TIA chip are electrically connected with the ceramic substrate IN a contact manner.

Furthermore, all grounding pins of the TIA chip are electrically connected with the GND metal ring of the ceramic substrate, and partial pins of the TIA chip except the grounding pins are electrically connected with partial metal areas on the ceramic substrate in a one-to-one correspondence manner.

Furthermore, a VCC pin on the TIA chip is electrically connected with a VCC metal area on the ceramic substrate in a contact mode, a Vout + pin and a Vout-pin on the TIA chip are electrically connected with a Vout + metal area and a Vout-metal area on the ceramic substrate in a contact mode respectively, and a Reset pin of the TIA chip is electrically connected with a Reset metal area of the ceramic substrate in a contact mode.

Furthermore, metal extension areas are arranged on a VCC metal area, a Vout + metal area, a Vout-metal area and a Reset metal area of the ceramic substrate, and all pins on the TIA chip are electrically connected with the metal extension areas of the corresponding ceramic substrate in a contact mode and isolated from the GND metal coil circuit.

Further, a resistor or a capacitor is arranged in the metal extension area of the VCC metal area of the ceramic substrate.

Further, there are a plurality of the resistors or the capacitors, and each of the resistors or each of the capacitors is connected in series.

Furthermore, each metal area on the ceramic substrate is electrically connected with each pin on the TO base in a one-TO-one correspondence manner.

Furthermore, n metal areas are arranged on the ceramic substrate, n is larger than 1, each metal area is correspondingly provided with a metal extension area, the metal extension areas corresponding TO the n-1 metal areas are electrically connected with the n-1 pins on the TO base in a one-TO-one corresponding contact mode, and the metal extension areas of the metal areas of the rest 1 ceramic substrate are connected with the cathode of the detector chip.

Furthermore, a VCC pin, a Vout + pin, a Vout-pin and a Reset pin of the TIA chip are arranged on the lower surface of the TIA chip, and an IN pin of the TIA chip is arranged on the upper surface of the TIA chip.

And the height of the grounding upright posts is controlled TO enable the bottom surface of the ceramic substrate TO be flush with the pins.

Compared with the prior art, the beneficial effects of the utility model are that: a TO-CAN packaging device of a detector chip reduces the number of interconnection routing TO the maximum extent in the TO-CAN packaging process through direct contact type electric connection, and avoids the reduction of the sensitivity and bandwidth of an optical module receiving signal caused by too many parasitic parameters introduced by routing in the high-speed detector chip packaging process; simultaneously, because TIA chip and detector chip all place ceramic substrate on, ceramic substrate also links TO each other simultaneously with each pin of TO base, has also played a radiating effect of increase area of contact TO whole device through the setting in metal extension district, TO this packaging technology's improvement, because the quantity of routing reduces, has promoted production efficiency, has reduced the gold thread and has collapsed and lead TO the risk of harmfully and inefficacy.

Drawings

Fig. 1 is a schematic top view of a ceramic substrate of a TO-CAN packaging apparatus for a high-speed detector chip according TO an embodiment of the present invention;

fig. 2 is a schematic diagram of a top view angle of a TIA chip of a TO-CAN packaging apparatus for a high-speed detector chip according TO an embodiment of the present invention after flip-mounting;

fig. 3 is a schematic diagram illustrating a top view of a TO base of a TO-CAN packaging apparatus for a high-speed detector chip according TO an embodiment of the present invention;

fig. 4 is a schematic diagram illustrating a side view of a ceramic substrate of a TO-CAN packaging apparatus for a high-speed detector chip according TO an embodiment of the present invention;

fig. 5 is a schematic diagram illustrating a top view angle of a detector chip of a TO-CAN packaging apparatus for a high-speed detector chip according TO an embodiment of the present invention;

fig. 6 is a schematic diagram of a TO-CAN packaging apparatus for a high-speed detector chip according TO an embodiment of the present invention;

in the reference symbols: 1-a ceramic substrate; 2-GND metal ring; a 3-VCC metal region; a 4-PD metal region; 5-Reset metal region; 6-Vout-metal region; 7-Vout + metal region; 8-a metal extension region; 9-a grounding upright post; 10-capacitance or resistance; 11-TIA chip; 12-a ground pin; 13-VCC pin; 14-IN pin; 15-Reset pin; 16-Vout-pin; 17-Vout + pin; an 18-TO header; a 19-TO ground pin; 20-insulating surrounding resin; 21-a detector chip; 22-a photosensitive surface; 23-a positive electrode; 24-negative electrode.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

The first embodiment is as follows:

referring TO fig. 1 TO 6, an embodiment of the present invention provides a TO-CAN packaging method for a high-speed detector chip, including the following steps: s1, flip-chip mounting a TIA chip 11 on a ceramic substrate 1, electrically connecting all grounding pins of the TIA chip 11 with GND metal rings 2 of the ceramic substrate 1, and electrically connecting partial pins on the TIA chip 11 with partial metal areas on the ceramic substrate 1 in a one-to-one correspondence manner; only the IN pin of the TIA chip is connected with the detector chip by a gold wire, and other pins are directly and electrically connected with the ceramic substrate IN a contact manner; s2, after mounting and electric connection are finished, eutectic welding is carried out on the ceramic substrate 1 on the TO base 18, and each metal area on the ceramic substrate 1 is electrically connected with each pin on the TO base 18 in a one-TO-one correspondence mode; and S3, then, mounting the detector chip 21 on the TIA chip 11, electrically connecting the anode 23 of the detector chip 21 with an IN pin on the TIA chip 11, and electrically connecting the cathode 24 of the detector chip 21 with a corresponding metal area on the ceramic substrate 1. In the embodiment, the number of interconnection routing is reduced TO the maximum extent in the TO-CAN packaging process by the method of flip-chip welding the TIA chip 11 on the ceramic substrate 1 with a circuit design, the whole TO packaging only uses two wires for connecting 23 and 24, the routing process time is greatly shortened, the production efficiency is improved, the risks of badness and failure caused by gold wire collapse are reduced, and because routing is reduced, the problem that too many parasitic parameters are introduced into routing in the packaging process of the high-speed detector chip 21 is avoided, the sensitivity and the bandwidth of signal transmission CAN be integrally improved, the product performance is improved, meanwhile, because the TIA chip 11 and the detector chip 21 are placed on the ceramic substrate 1, the ceramic substrate 1 is also simultaneously connected with pins of the TO base 18, a function of increasing the contact area for radiating the whole device is achieved, the production efficiency is improved, because the number of routing is reduced, and the risk of badness and failure caused by gold wire collapse is reduced.

Whole scheme integrated level is high, and ceramic substrate 1's circuit structure can design in advance according TO different products, and the batch production of being convenient for compares the mode of traditional every chip subsides dress routing alone, needn't carry out the independent adjustment of the position and the angle of every chip on the narrow and small TO base 18 of relative space in the packaging process, has avoided the artifical operating error that brings. The TO base 18 has a TO ground pin 19 thereon.

Specifically, before encapsulating detector chip 21, accomplish the installation of TIA chip 11, ceramic substrate 1 and TO base 18 earlier, utilize TIA chip 11 flip-chip TO paste and cover the routing that can reduce among the packaging process TO avoid the various problems that can appear in traditional encapsulation, simultaneously because the chip all pastes on ceramic substrate 1, the radiating effect also can promote greatly. The steps are repeated, batch production can be realized, and errors caused by manual wiring are reduced.

The following are specific examples:

referring to fig. 1 to 6 as an optimized solution of the embodiment of the present invention, in the step S1, the VCC pin 13 on the TIA chip 11 is electrically connected to the VCC metal area 3 on the ceramic substrate 1, the Vout + pin 17 and the Vout-pin 16 on the TIA chip 11 are electrically connected to the Vout + metal area 7 and the Vout-metal area 6 on the ceramic substrate 1, respectively, and the Reset pin 15 of the TIA chip 11 is electrically connected to the Reset metal area 5 of the ceramic substrate 1. In the present embodiment, as shown in fig. 1, five metal regions on the ceramic substrate 1 can be eutectic-welded with the TO base 18 pins at corresponding positions TO form a circuit connection, and the GND metal ring 2 and the TO base 18 are connected TO ground. Each pin metal area runs through the whole ceramic substrate 1, each metal extension area 8 is connected with the corresponding pin metal area and isolated from the GND metal coil 2, capacitors or resistors 10 are connected in series between the VCC metal area 3 and the metal extension area 8 of the ceramic substrate 1 and between the PD metal area 4 and the metal extension area 8 of the ceramic substrate 1 for impedance matching, wherein the number of the capacitors or resistors 10 can be multiple and is not limited to one shown in FIG. 1, and if multiple capacitors or resistors 10 are connected in series, the capacitors or resistors can be connected in series. Taking the left metal extension area 3 in fig. 1 as an example, if a capacitor or a resistor 10 needs to be connected, the corresponding pin of the TIA chip can be directly and electrically connected to the area above the capacitor or the resistor 10, and at this time, the circuit passes through the capacitor or the resistor 10; if the capacitor or the resistor 10 is not required to be connected, the corresponding pin of the TIA chip can be directly and electrically connected to the area below the capacitor or the resistor 10. The entire ceramic substrate 1 is designed to provide the necessary electrical path, ground, and isolation between the various lines.

Referring TO fig. 1 TO 6 as an optimized solution of the embodiment of the present invention, in the step S2, the VCC metal area 3, vout + metal area 7, vout-metal area 6, reset metal area 5 on the ceramic substrate 1 are sequentially connected TO the VCC pin 13, vout + pin 17, vout-pin 16, and Reset pin 15 of the TO base 18 in a one-TO-one correspondence manner. In this embodiment, the TO base 18 pin definition and the ceramic substrate 1 metal region definition are consistent, so that the TO base 18 pin definition and the ceramic substrate 1 metal region definition can be perfectly connected with the TO base 18 pin after the ceramic substrate is mounted, and the circuits are isolated.

When n metal regions are arranged on the ceramic substrate 1, n is larger than 1, each metal region is correspondingly provided with a metal extension region, wherein n-1 metal regions correspond TO n-1 pins on the TO base 18 one by one, and the rest 1 metal regions of the ceramic substrate are connected with the cathode of the detector chip. As shown in fig. 6, the ceramic substrate 1 has five metal regions, each metal region is correspondingly provided with a metal extension region, and four of the five metal regions are connected with four pins on the TO base 18 in a one-TO-one correspondence manner. The remaining ceramic substrate metal region 4 is connected to the detector chip cathode 24. And the VCC metal area, the Vout + metal area, the Vout-metal area and the Reset metal area of the ceramic substrate are all provided with metal extension areas, and all pins on the TIA chip are electrically connected with the corresponding metal extension areas in a direct contact manner and are isolated from the GND metal coil circuit. The ceramic substrate metal area range is enlarged through setting up the metal extension area on ceramic substrate in this application, be convenient for be connected with the corresponding pin contact of TIA chip or TO base, avoided in the current scheme between TIA chip and ceramic chip TO and all adopt ten last gold threads TO connect between ceramic chip and the TO base, and then promoted the device performance, increased heat radiating area.

As an optimization scheme of the embodiment of the present invention, please refer TO fig. 1 TO 6, further including a plurality of grounding posts 9 connected TO the TO base 18, each grounding post 9 is connected TO the GND metal ring 2, and the height of the grounding post 9 is controlled TO make the bottom surface of the ceramic substrate 1 flush with the pins. In this embodiment, the number of the grounding posts 9 is four, the four grounding posts 9 are arranged in a square shape, and the height of each grounding post 9 is 300 μm. This is because the TO base 18 pin has a height difference of about 300um from the TO base 18, and the grounding stud 9 is used TO make the whole bottom surface of the ceramic substrate 1 flush with the pin for stabilization.

As an optimization scheme of the embodiment of the present invention, please refer TO fig. 1 TO 6, in the step S3, the photosensitive surface 22 of the detector chip 21 is attached TO the TIA chip 11 at a position corresponding TO the middle of the whole TO base 18. The anode 23 of the detector chip 21 is connected with the IN pin 14 of the TIA chip 11 by wire bonding, and the cathode 24 of the detector chip 21 is connected with the metal extension area 8 of the PD metal area 4 of the ceramic substrate 1 by wire bonding. In this embodiment, referring to fig. 5, the photosensitive surface 22 of the detector chip 21 faces upward to receive external optical signals, so as to ensure that the detector chip receives light centrally, and the bottom substrate portion is conveniently attached to the TIA chip 11. The positive electrode 24 faces upwards, and is convenient TO be connected with the TIA chip 11 and the TO base 18 pin for routing.

Referring to fig. 1 to 6 as an optimized solution of the embodiment of the present invention, the VCC pin 13, vout + pin 17, vout-pin 16, and Reset pin 15 of the TIA chip 11 are on the lower surface of the TIA chip 11, and the IN pin 14 of the TIA chip 11 is on the upper surface of the TIA chip 11. In this embodiment, all the ground pins 12 on the TIA chip 11 are arranged in the same range as the GND metal loop 2 on the ceramic substrate 1, and when the TIA chip 11 is attached to the ceramic substrate 1, each pin is connected to the GND metal loop 2 on the ceramic substrate 1 and grounded. VCC pin 13, vout + pin 17, vout-pin 16 and Reset pin 15 on the TIA chip 11 are arranged on the lower surface of the TIA chip 11, and are connected with the corresponding metal extension areas 8 of the pins of the ceramic substrate 1 on the ceramic substrate 1 at the positions which are isolated from other circuits, so that the TIA chip 11 is connected with the ceramic substrate 1 by the circuits. The IN pin 14 of the TIA chip 11 is on the upper surface of the TIA chip 11, and is convenient for wire bonding connection with the detector chip 21. By the position setting mode, most pins of the TIA chip can be directly electrically connected with the TO base under the TIA chip in a direct contact mode. In the prior art, the pins of the TIA chip are all disposed above the chip. In addition, most of the connecting circuits of the TIA chip are hidden on the lower surface by the mode of arranging the pins, and cannot be directly seen after being packaged, so that the confidentiality is further enhanced.

As an optimized solution of the embodiment of the present invention, please refer TO fig. 1 TO 6, an insulating surrounding resin 20 is disposed around each pin of the TO base 18. In the present embodiment, the insulation surrounding resin 20 can achieve insulation.

Example two:

referring TO fig. 1 TO 6, an embodiment of the present invention further provides a TO-CAN package device for a high-speed probe chip, which is consistent with the structure of the method of the above embodiment. The device specifically comprises a ceramic substrate 1, a TIA chip 11, a TO base 18 and a detector chip 21, wherein the TIA chip 11 is flip-chip mounted on the ceramic substrate 1, all grounding pins of the TIA chip 11 are electrically connected with a GND metal ring 2 of the ceramic substrate 1, and meanwhile, partial pins of the TIA chip 11 except the grounding pins are electrically connected with partial metal areas on the ceramic substrate 1 in a one-TO-one correspondence manner; only the IN pin 14 of the TIA chip 11 is connected with the detector chip 21 by a gold thread, and other pins are directly and electrically connected with the ceramic substrate IN a contact way; the ceramic substrate is eutectic-welded on the TO base, and each metal area on the ceramic substrate 1 is electrically connected with each pin on the TO base 18 in a one-TO-one correspondence manner; the detector chip 21 is attached to the TIA chip 11, and the anode of the detector chip 21 is electrically connected to the IN pin 14 on the TIA chip 11, and the cathode of the detector chip 21 is electrically connected to the corresponding metal area on the ceramic substrate 1. In this embodiment, through the method of flip-chip bonding of TIA chip 11 on ceramic substrate 1 with circuit design, furthest has reduced the quantity of interconnection routing in the TO-CAN packaging process, whole TO packaging only need TO beat two lines of connection 23, 24, has shortened the process time of routing greatly, has promoted production efficiency, and reduced the gold thread collapse and lead TO the bad and risk of inefficacy, and because of having reduced the routing, avoided in the packaging process of high-speed detector chip 21 because too many parasitic parameters have been introduced TO the routing, CAN wholly promote the sensitivity and the bandwidth of signal transmission, the performance of product has been improved, simultaneously, because place TIA chip 11 and detector chip 21 on ceramic substrate 1, ceramic substrate 1 also links TO each pin of TO base 18 simultaneously, play an increase contact area radiating effect TO whole device, TO this packaging technology's improvement, because the quantity of routing reduces, has promoted production efficiency, reduced the risk that leads TO badness and inefficacy because of the collapse.

Whole scheme integrated level is high, and ceramic substrate 1's circuit structure can design in advance according TO different products, and the batch production of being convenient for compares the mode of traditional every chip subsides dress routing alone, needn't carry out the independent adjustment of the position and the angle of every chip on the narrow and small TO base 18 of relative space in the packaging process, has avoided the artifical operating error that brings.

As an optimized solution of the embodiment of the present invention, please refer to fig. 1 to 6, a VCC pin 13 on the TIA chip 11 is electrically connected to a VCC metal area 3 on the ceramic substrate 1 in a contact manner, a Vout + pin 17 and a Vout-pin 16 on the TIA chip 11 are electrically connected to a Vout + metal area 7 and a Vout-metal area 6 on the ceramic substrate 1 in a contact manner, respectively, and a Reset pin 15 of the TIA chip 11 is electrically connected to a Reset metal area 5 of the ceramic substrate 1 in a contact manner. And the VCC metal area 3, the Vout + metal area 7, the Vout-metal area 6 and the Reset metal area 5 of the ceramic substrate 1 are all provided with metal extension areas, and each pin on the TIA chip 11 is electrically connected with the metal extension area of the corresponding ceramic substrate 1 in a contact manner and is isolated from the GND metal ring 2. And a resistor or a capacitor is arranged in the metal extension area of the VCC metal area 3 of the ceramic substrate 1. The number of the resistors or the capacitors is multiple, and the resistors or the capacitors are connected in series. In this embodiment, capacitors or resistors 10 are connected in series between the VCC metal area 3 and the metal extension area 8 of the ceramic substrate 1 and between the PD metal area 4 and the metal extension area 8 of the ceramic substrate 1 for impedance matching, wherein the number of the capacitors or resistors 10 may be plural, and is not limited to one shown in fig. 1, and if plural, they may be connected in series. Taking the left metal extension area 3 in fig. 1 as an example, if a capacitor or a resistor 10 needs to be connected, the corresponding pin of the TIA chip can be directly and electrically connected to the area above the capacitor or the resistor 10, and at this time, the circuit passes through the capacitor or the resistor 10; if the capacitor or the resistor 10 is not required to be connected, the corresponding pin of the TIA chip can be directly and electrically connected to the lower area of the capacitor or the resistor 10. The entire ceramic substrate 1 is designed to provide the necessary electrical paths, ground, and isolation between the various lines.

As an optimization scheme of the embodiment of the present invention, please refer TO fig. 1 TO 6, where n metal areas are located on the ceramic substrate 1, n is greater than 1, and each metal area is correspondingly provided with a metal extension area, where the metal extension area corresponding TO n-1 metal areas is electrically connected TO n-1 pins on the TO base in a one-TO-one correspondence contact manner, and the metal extension area of the metal area of the remaining 1 ceramic substrate is connected TO the negative electrode of the detector chip. In this embodiment, as shown in fig. 6, there are five metal regions on the ceramic substrate 1, each metal region is correspondingly provided with a metal extension region, and four of the five metal regions are connected with four pins on the TO base 18 in a one-TO-one correspondence manner. The remaining ceramic substrate metal region 4 is connected to the detector chip cathode 24. And the VCC metal area 3, the Vout + metal area 7, the Vout-metal area 6 and the Reset metal area 5 of the ceramic substrate 1 are all provided with metal extension areas, and all pins on the TIA chip 11 are electrically connected with the corresponding metal extension areas in a direct contact manner and are isolated from the GND metal ring 2. The ceramic substrate metal area scope has been enlarged through set up the metal extension district on ceramic substrate 1 in this application, be convenient for be connected with TIA chip 11 or the corresponding pin contact of TO base 18, avoided in the current scheme between TIA chip and ceramic chip TO and all adopt ten gold thread connections between ceramic chip and the TO base, and then promoted the device performance, increased heat radiating area.

Referring to fig. 1 to 6 as an optimized solution of the embodiment of the present invention, the VCC pin 13, vout + pin 17, vout-pin 16, and Reset pin 15 of the TIA chip 11 are on the lower surface of the TIA chip 11, and the IN pin 14 of the TIA chip 11 is on the upper surface of the TIA chip 11. In this embodiment, all the ground pins 12 on the TIA chip 11 are arranged in the same range as the GND metal loop 2 on the ceramic substrate 1, and when the TIA chip 11 is attached to the ceramic substrate 1, each pin is connected to the GND metal loop 2 on the ceramic substrate 1 and grounded. VCC pin 13, vout + pin 17, vout-pin 16 and Reset pin 15 on the TIA chip 11 are arranged on the lower surface of the TIA chip 11, and are connected with the corresponding metal extension areas 8 of the pins of the ceramic substrate 1 on the ceramic substrate 1 at the positions which are isolated from other circuits, so that the TIA chip 11 is connected with the ceramic substrate 1 by the circuits. The IN pin 14 of the TIA chip 11 is on the upper surface of the TIA chip 11, and is convenient for wire bonding connection with the detector chip 21. By the position setting mode, most pins of the TIA chip can be directly electrically connected with the TO base under the TIA chip in a direct contact mode. In the prior art, the pins of the TIA chip are all disposed above the chip. In addition, most of the connecting circuits of the TIA chip are hidden on the lower surface by the mode of arranging the pins, and cannot be directly seen after being packaged, so that the confidentiality is further enhanced.

As an optimization scheme of the embodiment of the present invention, please refer TO fig. 1 TO 6, further including a plurality of grounding pillars connected TO the TO base, each of the grounding pillars is connected TO the GND metal ring, and the height of the grounding pillars is controlled TO make the bottom surface of the ceramic substrate flush with the pins. In this embodiment, the number of the grounding posts 9 is four, the four grounding posts 9 are arranged in a square shape, and the height of each grounding post 9 is 300 μm. This is because the TO base 18 pin has a height difference of about 300um from the TO base 18, and the grounding stud 9 is used TO make the whole bottom surface of the ceramic substrate 1 flush with the pin for stabilization.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. The TO-CAN packaging device of the detector chip is characterized in that: the device comprises a ceramic substrate, a TIA chip, a TO base and a detector chip, wherein the ceramic substrate is eutectic-welded on the TO base, and the TIA chip is inversely arranged on the ceramic substrate; the detector chip is attached to the TIA chip, and the cathode of the detector chip is electrically connected with the corresponding metal area on the ceramic substrate; and only the IN pin of the TIA chip is connected with the anode of the detector chip through a gold wire, and other pins of the TIA chip are electrically connected with the ceramic substrate IN a contact manner.

2. The TO-CAN package device of a probe chip as claimed in claim 1, wherein: all grounding pins of the TIA chip are electrically connected with the GND metal ring of the ceramic substrate, and partial pins except the grounding pins on the TIA chip are electrically connected with partial metal areas on the ceramic substrate in a one-to-one correspondence manner.

3. The TO-CAN package device of a probe chip as claimed in claim 2, wherein: and a VCC pin on the TIA chip is in contact electrical connection with a VCC metal area on the ceramic substrate, a Vout + pin and a Vout-pin on the TIA chip are respectively in contact electrical connection with the Vout + metal area and the Vout-metal area on the ceramic substrate, and a Reset pin of the TIA chip is in contact electrical connection with the Reset metal area of the ceramic substrate.

4. The TO-CAN package device of a probe chip as claimed in claim 3, wherein: and metal extension areas are arranged on the VCC metal area, the Vout + metal area, the Vout-metal area and the Reset metal area of the ceramic substrate, and pins on the TIA chip are electrically connected with the metal extension areas of the corresponding ceramic substrate in a contact manner and are isolated from the GND metal coil circuit.

5. The TO-CAN package device of a probe chip as claimed in claim 4, wherein: and a resistor or a capacitor is arranged in the metal extension area of the VCC metal area of the ceramic substrate.

6. The TO-CAN package for a probe chip as recited in claim 5, wherein: the number of the resistors or the capacitors is multiple, and the resistors or the capacitors are connected in series.

7. The TO-CAN package device of a probe chip as claimed in claim 1, wherein: and each metal area on the ceramic substrate is electrically connected with each pin on the TO base in a one-TO-one correspondence manner.

8. The TO-CAN package for a probe chip as recited in claim 7, wherein: the device comprises a TO base, a ceramic substrate and a detector chip, wherein the ceramic substrate is provided with n metal areas, n is larger than 1, each metal area is correspondingly provided with a metal extension area, the metal extension areas corresponding TO the n-1 metal areas are electrically connected with n-1 pins on the TO base in a one-TO-one corresponding contact mode, and the metal extension areas of the metal areas of the rest 1 ceramic substrate are connected with the cathode of the detector chip.

9. The TO-CAN package device of a probe chip as claimed in claim 1, wherein: and a VCC pin, a Vout + pin, a Vout-pin and a Reset pin of the TIA chip are arranged on the lower surface of the TIA chip, and an IN pin of the TIA chip is arranged on the upper surface of the TIA chip.

10. The TO-CAN package device of a probe chip as claimed in claim 2, wherein: the grounding device is characterized by further comprising a plurality of grounding upright columns connected with the TO base, wherein each grounding upright column is connected with the GND metal ring, and the height of each grounding upright column is controlled TO enable the bottom surface of the ceramic substrate TO be flush with the pins.

Images