CN205302331U - Biological detection device - Google Patents

Abstract

The utility model provides a biological detection device. This biological detection device includes chip, optical emitter, circuit board and overburden. The chip includes photoelectric converter, and the overburden covers on chip, photoelectric converter and optical emitter, the overburden is the printing opacity, optical emitter transmission light, photoelectric converter receives the light of optical emitter transmission, photoelectric converter still sets a camera and carries out photoelectric conversion, obtains the signal of telecommunication, the chip is treated detecting object according to the signal of telecommunication and is detected, the circuit board provides communication channel and power supply for chip and optical emitter. The technical scheme of the utility model can improve the portable of user and this biological detection device's use flexibility ratio, prevent simultaneously that fingerprint identification from being explaind by the false body.

Description

Biological monitor

Technical field

This utility model relates to field of biological detection, particularly relates to a kind of biological monitor.

Background technology

In prior art, for the fingerprint identification module of fingerprint recognition be device separately for organism being carried out the optical module of heart rate detection, In vivo detection or pressing detection etc., making user inconvenient to carry, the flexibility ratio of use is not high, and fingerprint identification module is easily cracked by prosthese.

Utility model content

This utility model provides a kind of biological monitor, this biological monitor is made both to have can recognise that fingerprint, other features of organism being detected again, thus improving the portability of user and the use flexibility ratio of this biological monitor, preventing fingerprint recognition from being cracked by prosthese simultaneously.

First aspect, it is provided that a kind of biological monitor. This biological monitor includes chip, optical transmitting set, circuit board and cover layer; This chip includes optical-electrical converter, and cover layer is covered on chip, optical-electrical converter and optical transmitting set; The light that cover layer is launched through photoemitter; Optical-electrical converter receives that optical transmitting set is launched and passes through the light being reflected back through cover layer again after cover layer is irradiated to examined object; The light being reflected back through cover layer again after what optical transmitting set was launched by optical-electrical converter be irradiated to examined object carries out photoelectric conversion, to obtain the signal of telecommunication; Examined object is detected by the signal of telecommunication that fingerprint detection chip is changed according to optical-electrical converter; Circuit board provides communication port and power supply for this chip, optical transmitting set and optical-electrical converter.

In conjunction with first aspect, in the implementation that the first is possible, optical transmitting set is integrated on chip.

In conjunction with first aspect or implementation that the first is possible, in the implementation that the second is possible, cover layer includes protective layer and color layers, and the adhesive force between protective layer and color layers is more than or equal to 3B; The light transmittance of the light that optical transmitting set is launched more than or equal to 30%, is used for protecting described color layers by protective layer; The all or part of light transmittance to the light that optical transmitting set is launched of color layers is more than or equal to 30%, and the thickness range of color layers is 5 nanometers to 50 microns, and the dielectric constant of color layers is more than 2, and color layers is for providing the appearance color of biological monitor.

In conjunction with the implementation that the second is possible, in the implementation that the third is possible, protective layer is cover plate, and the material of this cover plate is glass, sapphire, pottery, acrylic or plastic cement. Now, cover layer is connected on chip, optical-electrical converter and optical transmitting set by glue or thin film, and the thickness range of glue is 5 microns to 150 microns, electric constant range for 1 to 10, light transmittance is be more than or equal to 90%.

In conjunction with the implementation that the second is possible, in the 4th kind of possible implementation, protective layer is rigidity layer, and the thickness range of rigidity layer is 2 microns to 25 microns, and Mohs' hardness is more than or equal to 3, and dielectric constant range is 1 to 10. Now, color layers is attached on chip, optical-electrical converter and optical transmitting set by spraying method, and color layers and the adhesive force between on chip, optical-electrical converter and optical transmitting set are more than or equal to 3B, and rigidity layer is attached in color layers by spraying method.

In conjunction with the implementation that the second is possible, in the 5th kind of possible implementation, infrared light launched by optical transmitting set. Accordingly, color layers includes at least one of which infrared ray (InfraredRay, IR) ink; Or color layers includes at least one of which infrared ray IR ink and at least one of which conventional printing ink, the local location perforate of this at least one of which conventional printing ink.

In conjunction with the implementation that the second is possible, in the 6th kind of possible implementation, optical transmitting set launches infrared light and HONGGUANG; Color layers includes at least one of which conventional printing ink, the local location perforate of this at least one of which conventional printing ink.

In conjunction with first aspect or implementation that the first is possible, in the 7th kind of possible implementation, cover layer includes thin film, and all or part of light transmittance to the light that optical transmitting set is launched of thin film is more than or equal to 30%.

In conjunction with first aspect or its first possible implementation, in the 8th kind of possible implementation, examined object is carried out fingerprint detection, heart rate detection, pressure detecting, button detection, the detection of blood oxygen, blood pressure detecting and/or In vivo detection according to the signal of telecommunication by chip.

In conjunction with first aspect, in the 9th kind of possible implementation, chip and optical transmitting set utilize plane-welding technology to be welded on circuit board by tin cream or silver slurry, and tin cream or the thickness range of silver slurry between chip and circuit board are 20 microns to 120 microns.

In conjunction with the implementation that the first is possible, in the tenth kind of possible implementation, chip utilizes plane-welding technology to be welded on circuit board by tin cream or silver slurry, and tin cream or the thickness range of silver slurry between chip and circuit board are 20 microns to 120 microns.

In conjunction with first aspect or implementation that the first is possible, in the 11st kind of possible implementation, this biological monitor also includes the collar, this collar utilizes plane-welding technology to be welded on circuit board by tin cream or silver slurry, tin cream or the thickness range of silver slurry between this collar and circuit board are 40 microns to 140 microns, and this collar is around chip, optical transmitting set and optical-electrical converter.

The novel biological monitor of this use is by being used for optical module that organism is detected and the device being used for fingerprint recognition is integrated together, this biological monitor is made both to have can recognise that fingerprint, other features of organism can be detected again, namely a detecting device can complete multiple function, thus improving the portability of user and the use flexibility ratio of this biological monitor, prevent fingerprint recognition from being cracked by prosthese simultaneously.

Accompanying drawing explanation

In order to be illustrated more clearly that the technical scheme of this utility model embodiment, the accompanying drawing used required in this utility model embodiment will be briefly described below, apparently, drawings described below is only embodiments more of the present utility model, for those of ordinary skill in the art, under the premise not paying creative work, it is also possible to obtain other accompanying drawing according to these accompanying drawings.

Fig. 1 is the structural representation of the fingerprint identification device of prior art.

Fig. 2 is the structural representation profile of the biological monitor of one embodiment of this utility model.

Fig. 3 is the structural representation profile of the biological monitor of another embodiment of this utility model.

Fig. 4 is the structural representation profile of the biological monitor of another embodiment of this utility model.

Fig. 5 is the structural representation profile of the biological monitor of another embodiment of this utility model.

Fig. 6 is the structural representation profile of the biological monitor of another embodiment of this utility model.

Fig. 7 is the structural representation profile of the biological monitor of another embodiment of this utility model.

Fig. 8 is the structural representation profile of the biological monitor of another embodiment of this utility model.

Detailed description of the invention

Below in conjunction with the accompanying drawing in this utility model embodiment, the technical scheme in this utility model embodiment is clearly and completely described, it is clear that described embodiment is a part of embodiment of this utility model, rather than whole embodiments. Based on the embodiment in this utility model, the every other embodiment that those of ordinary skill in the art obtain under not making creative work premise, broadly fall into the scope of this utility model protection.

In order to be more fully understood that the biological monitor of this utility model embodiment, first introduce the structure of existing fingerprint identification device below in conjunction with Fig. 1.

As it is shown in figure 1, the fingerprint identification device of prior art includes fingerprint recognition chip 101, circuit board 102, the collar (Ring) 103, cover plate 104 and color layers 105. Fingerprint recognition chip 101 is welded on circuit board 102. Being coated with color layers 105 on fingerprint recognition chip 101, the color of color layers 105 is mated with the appearance color of the equipment installing fingerprint identification device. Color layers 105 is coated with cover plate 104, to protect color layers 105 and fingerprint recognition chip 101. Fingerprint recognition chip 101, color layers 105 and cover plate 104 surrounding are surrounded with the collar 103. The collar 103 is also welded on circuit board 102. Wherein, cover plate 104 can also be changed to rigidity layer.

From the structure of above-mentioned existing fingerprint identification device it can be seen that existing fingerprint identification device is used for carrying out fingerprint recognition, function singleness, and easily cracked by prosthese.

More existing optical modules may be used for the various features of detection organism, if user had both needed to identify fingerprint, need again to carry out feature detection, then need carry fingerprint identification device respectively and the detecting device of optical module is installed, cause carrying inconvenient and using dumb. Therefore the utility model proposes and fingerprint identification device is integrated together with the optical module being used for detecting, form an overall biological monitor.

The biological monitor of this utility model embodiment is specifically introduced below in conjunction with Fig. 2 to Fig. 8.

Fig. 2 show the structural representation profile of the biological monitor of one embodiment of this utility model. As in figure 2 it is shown, this biological monitor includes cover layer 201, optical transmitting set 202, optical-electrical converter 203, chip 204 and circuit board 205.

Cover layer 201 can pass through the light that optical transmitting set is launched. And, cover layer may be provided for the appearance color of this biological monitor, and the appearance color that namely this biological monitor finally displays to the user that mainly is determined by cover layer 201. Cover layer 201 can absorb the light of some wavelength and can allow the light therethrough of some specific wavelength, in order to the light that optical transmitting set is sent does selectivity and propagates, it is ensured that has certain transmitance to having to use up and has certain absorbability to without using up.

In most cases, the appearance color of the equipment that the appearance color that cover layer 201 provides is installed with this biological monitor mates.

Optical transmitting set 202 provides light source, it is possible to for single package body or multiple packaging body, it is possible to comprise one or more emission wavelength chip. The wave-length coverage of light that optical transmitting set 202 is launched is 390 nanometers (nm) to 1300nm. Present stage, optical transmitting set 202 dominant emission wavelength is the light of 525nm, 625nm, 720nm, 840nm or 950nm.

Cover layer 201 when the light transmission cover it side that optical transmitting set 202 is launched, after being irradiated to biology (finger as shown in Figure 2) to be detected, reflect and through the cover layer 201 covered above optical-electrical converter 203, finally arrive optical-electrical converter 203.

Optical-electrical converter 203 receives the light (being the communication process of light as denoted by the arrows in fig. 2) returning to again optical-electrical converter 203 after a series of communication processes that optical transmitting set 202 is launched, and these light received are carried out opto-electronic conversion, to obtain the signal of telecommunication.

Chip 204 comprises a series of circuit, the signal of telecommunication of gained can be changed according to optical-electrical converter 203 carry out fingerprint recognition and carry out other detections of examined object, according to as described in the heart rate of electrical signal detection examined object, examined object is carried out In vivo detection or pressing detection or other detection. Namely whole biological monitor is made can to realize fingerprint recognition and other detection functions. Chip 204 can perform fingerprint recognition and other detection functions simultaneously, it is also possible to is perform fingerprint recognition and other detection functions respectively.

In this utility model embodiment, optical-electrical converter 203 has been integrated on chip 204, and this is a kind of example simply. But it practice, optical-electrical converter can also be not integrated on chip 204, this is not limited as by this utility model.

Circuit board 205 carries chip 204, optical-electrical converter 203 and optical transmitting set 202, provides communication port and power supply for chip 204, optical-electrical converter 203 and optical transmitting set 202 simultaneously. Namely chip 204, optical-electrical converter 203 and optical transmitting set 202 are directly or indirectly fixed on circuit board 205.

Biological monitor of the present utility model is by being used for optical module that organism is detected and the device being used for fingerprint recognition is integrated together, this biological monitor is made both to have can recognise that fingerprint, other features of organism can be detected again, namely a detecting device can complete multiple function, thus improving the portability of user and the use flexibility ratio of this biological monitor, prevent fingerprint recognition from being cracked by prosthese simultaneously.

In this utility model embodiment, alternatively, cover layer can be one layer of color layers with hardness, it is also possible to including color layers and protective layer, protective layer is with hardness. Adhesive force between protective layer and color layers is generally higher than the 3B in the standard " test of ASTMD3359-1997 PASS " equal to American Society Testing and Materials (AmericanSocietyforTestingandMaterials, ASTM) after decocting in water hundred lattice.The light transmittance of the light that described optical transmitting set is launched is needed more than or equal to 30% by color layers and protective layer, so ensure that the light transmission cover layer 201 that optical transmitting set 202 is launched. Now; optical-electrical converter 203 primary recipient is after the light transmittance of light in color layers, optical transmitting set 202 the launched part colours layer more than or equal to 30% is launched and passed through to optical transmitting set 202 and protective layer is irradiated to examined object, again through the light on protective layer and color layers, the light transmittance of the light that optical transmitting set 202 the is launched part colours layer more than or equal to 30% being reflected back. Alternatively, protective layer can be cover plate or rigidity layer etc.

In this utility model embodiment, cover layer can also include special thin film, such as plating anti-reflection film, filter membrane, infrared film or one-way membrane etc. This thin film can be the transparent or semitransparent thin film coating IR ink, it is also possible to be common colored thin film.

When cover layer includes band color films, on thin film, punch or do special pattern and realize printing opacity in local. The diameter in hole is between 5 microns to 50 microns, and pitch of holes ranges for 10 microns to 100 microns, and light transmittance is greater than or equal to 30%.

Cover layer can also include the thin film of special substance. As when infrared light launched by optical transmitting set, this thin film can be can the thin film made of the material of saturating infrared light, such as acrylic material.

When cover layer includes thin film, generally also need to strengthen film surface hardness, to protect this thin film.

In this utility model embodiment, alternatively, cover layer can also is that the transmitance to the light that optical transmitting set is launched is more than or equal to 30%, and existing hardness is with again coloured material.

Fig. 3 is the structural representation profile of the biological monitor of another embodiment of this utility model. Accompanying drawing labelling identical with Fig. 2 in Fig. 3 represents identical implication, repeats no more herein. As it is shown on figure 3, on photoemitter 202 directly fixing circuit board 205 again, protective layer is cover plate 302, and namely cover layer includes color layers 301 and cover plate 302.

Color layers 301 provides the appearance color of this biological monitor, and the appearance color that namely this biological monitor finally displays to the user that mainly is determined by color layers 301. Color layers 301 can absorb the light of some wavelength and can allow the light therethrough of some specific wavelength, in order to the light that optical transmitting set is sent does selectivity and propagates, it is ensured that has certain transmitance to having to use up and has certain absorbability to without using up. In most cases, the appearance color of the equipment that the appearance color that color layers 301 provides is installed with this biological monitor mates. Under normal circumstances, all or part of light transmittance to the light that optical transmitting set 202 is launched of color layers 301 needs more than or equal to 30%, and the thickness range of color layers 301 is 5 nanometers to 50 microns, and dielectric constant is more than 2.

Cover plate 302 is transparent semiconductor material and nontransparent material, generally can be selected for glass, sapphire, pottery, acrylic or plastic cement material etc. The light transmittance of the light that optical transmitting set 202 is launched is preferably greater than or equal to 30% by cover plate 302.

In this utility model embodiment, color layers 301 is attached on cover plate 302, color layers 301 is by glue or treats that the thin film of viscosity is connected on chip 204, optical-electrical converter 203 and optical transmitting set 202, the thickness range of glue or thin film is 5 microns to 150 microns, dielectric constant range for 1 to 10, the light transmittance of the light that optical transmitting set is sent can more than or equal to 90%.And glue or thin film need to possess good physics and chemical stability, bonding force, minimum thermal coefficient of expansion and water absorption. In most cases, can fill with enough glue in the top of optical transmitting set 202 and surrounding, come off the deformation with cover plate reducing color layers.

When cover layer covers on chip 204 and optical transmitting set 202, it is possible to be that color layers 301 is close to chip 204 surface, it is also possible to be that chip 204 surface is close to by cover plate 302. And, the cover layer of this utility model embodiment can also be connected by other means with between chip and optical transmitting set, and this utility model contrast is not limited as.

It should be understood that in the structural representation profile shown in Fig. 3, have gap between optical transmitting set 202 and chip 204 and color layers 301, this is intended merely to embodiment optical transmitting set 202 better and is not affixed on chip 204, but is directly anchored on circuit board 205. This utility model is not limited as whether there being space between optical transmitting set 202 and chip 204 and color layers 301.

Fig. 4 is the structural representation profile of the biological monitor of another embodiment of this utility model. Accompanying drawing labelling identical in Fig. 4 and Fig. 3 represents identical implication, repeats no more herein. Biological monitor shown in Fig. 4 and Fig. 3 is different in that, optical transmitting set 202 and optical-electrical converter 203 are all integrated on chip 204, thus being indirectly fixed on circuit board 205.

Fig. 5 is the structural representation profile of the biological monitor of another embodiment of this utility model. Accompanying drawing labelling identical with Fig. 4 in Fig. 5 represents identical implication, repeats no more herein. Biological monitor shown in Fig. 5 and Fig. 4 is different in that, protective layer is rigidity layer, and namely cover layer includes color layers 301 and rigidity layer 501.

The thickness range of rigidity layer 501 is 2 microns to 25 microns, and Mohs' hardness is more than or equal to 3, and dielectric constant range is 1 to 10, and the light transmittance of the light that optical transmitting set is sent is more than or equal to 30%.

Now, color layers 301 is attached on chip 204, optical-electrical converter 203 and 202 optical transmitting set by spraying method. Adhesive force between color layers 301 and chip 204, optical-electrical converter 203 and optical transmitting set 202 is generally higher than the 3B in the standard " test of ASTMD3359-1997 PASS " equal to American Society Testing and Materials (AmericanSocietyforTestingandMaterials, ASTM) after decocting in water hundred lattice. Rigidity layer 501 is attached in color layers 301 by spraying method.

In this utility model embodiment, alternatively, optical transmitting set 202 can also be not integrated on chip 204.

When optical transmitting set is fixed on chip, many employings include the cover layer of rigidity layer and color layers to cover chip, optical-electrical converter and optical transmitting set.

In above-mentioned embodiment of the present utility model, biological monitor can also include the collar. The collar can utilize plane-welding technology to be welded on circuit board 205 by tin cream or silver slurry. Tin cream or the thickness range of silver slurry between the collar and circuit board 205 are 40 microns to 140 microns. The collar is around chip 104, optical transmitting set 202 and optical-electrical converter 203.

When optical transmitting set is directly anchored on circuit board, it is typically between the collar and optical transmitting set and optical-electrical converter and uses glue to increase the stationarity between three; When optical transmitting set is first fixed on chip, chip is fixed on circuit boards again, is typically in the collar and uses glue increase stationarity therebetween with chip chamber.The dielectric constant range of the glue used is 1 to 10, and the transmitance of the light that optical transmitting set is sent, more than or equal to 90%, is provided simultaneously with good physics and chemical stability, less thermal coefficient of expansion and water absorption.

Sectional view when biological monitor as shown in Figure 3 includes the collar 601 is as shown in Figure 6, sectional view when biological monitor as shown in Figure 4 includes the collar 701 as it is shown in fig. 7, sectional view when biological monitor as shown in Figure 5 includes the collar 801 as shown in Figure 8. Accompanying drawing labelling identical with Fig. 3, Fig. 4 and Fig. 5 respectively in Fig. 6, Fig. 7 and Fig. 8 represents identical implication, repeats no more herein.

It it should be understood that, in structural representation profile shown in Fig. 6, Fig. 7 and Fig. 8, can have between the collar 601, the collar 701 or the collar 801 and chip 204, color layers 301, cover plate 302 or rigidity layer 501 and/or optical transmitting set can also be very close to each other, and this is not limited as by this utility model.

In above-mentioned embodiment of the present utility model, optical transmitting set 202 can be launched infrared light or launch infrared light and HONGGUANG simultaneously.

When infrared light launched by optical transmitting set 202, color layers 301 can include one or more layers IR ink; Maybe can include at least one of which IR ink and at least one of which conventional printing ink, but the local location of conventional printing ink needs perforate so that most of infrared light that optical transmitting set 202 is launched can pass through from the place of perforate. When launching infrared light and HONGGUANG when optical transmitting set 202, color layers 301 can include one or more layers conventional printing ink, and now, the local location of conventional printing ink needs perforate so that most of infrared light that optical transmitting set 202 is launched can pass through from the place of perforate.

The shape of the perforate of the local location of above-mentioned conventional printing ink can be fabricated to various pattern according to demand.

Color layers can make the colors such as black, white, redness, gold, silver color, pink as desired.

In several embodiments provided herein, it should be understood that disclosed device, it is possible to realize by another way. Such as, device embodiment described above is merely schematic.

The above; it is only detailed description of the invention of the present utility model; but protection domain of the present utility model is not limited thereto; any those familiar with the art is in the technical scope that this utility model discloses; change can be readily occurred in or replace, all should be encompassed within protection domain of the present utility model. Therefore, protection domain of the present utility model should be as the criterion with scope of the claims.

Claims (12)

1. a biological monitor, it is characterised in that including: chip, optical transmitting set, circuit board and cover layer;

Described chip includes optical-electrical converter, and described cover layer is covered on described chip, described optical-electrical converter and described optical transmitting set;

The light that described cover layer is launched through described optical transmitting set;

Described optical-electrical converter receives that described optical transmitting set is launched and passes through the light being reflected back through described cover layer again after described cover layer is irradiated to examined object;

The described light being reflected back is carried out photoelectric conversion by described optical-electrical converter, obtains the signal of telecommunication;

Described examined object is detected by described chip according to the described signal of telecommunication;

Described circuit board is described chip, described optical transmitting set and described optical-electrical converter provide communication port and power supply.

2. biological monitor according to claim 1, it is characterised in that described optical transmitting set is integrated on the chip.

3. biological monitor according to claim 1 and 2, it is characterised in that described cover layer includes protective layer and color layers, and the adhesive force between described protective layer and described color layers is more than or equal to 3B;

The light transmittance of the light that described optical transmitting set is launched more than or equal to 30%, is used for protecting described color layers by described protective layer;

The all or part of light transmittance to the light that described optical transmitting set is launched of described color layers is more than or equal to 30%, the thickness range of described color layers is 5 nanometers to 50 microns, the dielectric constant of described color layers is more than 2, and described color layers provides the appearance color of described biological monitor.

4. biological monitor according to claim 3, it is characterised in that described protective layer is cover plate, the material of described cover plate is glass, sapphire, pottery, acrylic or plastic cement;

Described cover layer is connected on described chip, described optical-electrical converter and described optical transmitting set by glue or thin film, the thickness range of described glue or thin film is 5 microns to 150 microns, the dielectric constant of described glue or thin film range for 1 to 10, the light transmittance of described glue or thin film is be more than or equal to 90%.

5. biological monitor according to claim 3, it is characterized in that, described protective layer is rigidity layer, and the thickness range of described rigidity layer is 2 microns to 25 microns, the Mohs' hardness of described rigidity layer is more than or equal to 3, and the dielectric constant range of described rigidity layer is 1 to 10;

Described color layers is attached on described chip, described optical-electrical converter and described optical transmitting set by spraying method, adhesive force between described color layers and described chip, described optical-electrical converter and described optical transmitting set is more than or equal to 3B, and described rigidity layer is attached in described color layers by spraying method.

6. biological monitor according to claim 3, it is characterised in that infrared light launched by described optical transmitting set;

Wherein, described color layers includes at least one of which infrared ray IR ink; Or

Described color layers includes at least one of which infrared ray IR ink and at least one of which conventional printing ink, the local location perforate of described at least one of which conventional printing ink.

7. biological monitor according to claim 3, it is characterised in that described optical transmitting set launches infrared light and HONGGUANG;

Described color layers includes at least one of which conventional printing ink, the local location perforate of described at least one of which conventional printing ink.

8. biological monitor according to claim 2, it is characterised in that described cover layer includes thin film, all or part of light transmittance to the light that optical transmitting set is launched of described thin film is more than or equal to 30%.

9. biological monitor according to claim 1 and 2, it is characterized in that, described examined object is carried out fingerprint detection, heart rate detection, pressure detecting, button detection, the detection of blood oxygen, blood pressure detecting and/or In vivo detection according to the described signal of telecommunication by described chip.

10. biological monitor according to claim 1, it is characterized in that, described chip and described optical transmitting set utilize plane-welding technology to be welded on described circuit board by tin cream or silver slurry, and tin cream or the thickness range of silver slurry between described optical transmitting set and described chip and described circuit board are 20 microns to 120 microns.

11. biological monitor according to claim 2, it is characterized in that, described chip utilizes plane-welding technology to be welded on described circuit board by tin cream or silver slurry, and tin cream or the thickness range of silver slurry between described chip and described circuit board are 20 microns to 120 microns.

12. biological monitor according to claim 1 and 2, it is characterized in that, described biological monitor also includes the collar, the described collar utilizes plane-welding technology to be welded on described circuit board by tin cream or silver slurry, and tin cream or the thickness range of silver slurry between the described collar and described circuit board are 40 microns to 140 microns;The described collar is around described chip, described optical transmitting set and described optical-electrical converter.