CN209151171U - A kind of photoelectric conversion circuit for satellite photoreceiver - Google Patents

Abstract

The utility model discloses a kind of photoelectric conversion circuits for satellite photoreceiver, the satellite photoreceiver includes optical power sample circuit and level-one amplifying circuit, comprising: capacitor C1, capacitor C3, capacitor C4, capacitor C38, capacitor C39, photodetector PIN-IN, inductance L2, resistance R1 and resistance R2；Photodetector PIN-IN ground terminal ground connection, cathode connect 5V DC voltage, are grounded further through capacitor C38, capacitor C39, and anode is grounded by capacitor C1, and connect level-one amplifying circuit, while further through inductance L2, resistance R2 connection optical power sample circuit；Inductance L2 is grounded by resistance R1；The both ends of resistance R2 pass through capacitor C3 and capacitor C4 ground connection respectively.The photoelectric conversion circuit of the utility model can receive broader input optical power range, high conversion efficiency, and circuit structure is simple, low in cost.

Description

A kind of photoelectric conversion circuit for satellite photoreceiver

Technical field

The utility model belongs to photoreceiver components, especially a kind of photoelectric conversion electricity for satellite photoreceiver Road.

Background technique

Traditional CATV and satellite L-Band is that two different modes are transmitted, and the bandwidth of operation of CATV is 47-860MHz, is defended The bandwidth of operation 950-2150MHz of star L-Band.In order to reduce the cost of operator, propose CATV and satellite L-Band same The transmission mode of optical fiber link.It is a kind of with the satellite photoreceiver that can receive wider range bandwidth therefore, it is necessary to research and develop, it uses It is provided in the broadband signal for receiving CATV and satellite L-Band while reducing the cost of operator for user richer Program resource.Wherein, important component of the photoelectric conversion circuit as satellite photoreceiver, structure are very crucial.

Summary of the invention

The purpose of this utility model is that: a kind of photoelectric conversion circuit for satellite photoreceiver is provided, can receive Broader input optical power range, high conversion efficiency, and circuit structure is simple, it is low in cost.

The technical solution adopted in the utility model is as follows:

A kind of photoelectric conversion circuit for satellite photoreceiver, the satellite photoreceiver include optical power sample circuit With level-one amplifying circuit；The photoelectric conversion circuit, comprising: capacitor C1, capacitor C3, capacitor C4, capacitor C38, capacitor C39, light Electric explorer PIN-IN, inductance L2, resistance R1 and resistance R2；Photodetector PIN-IN ground terminal ground connection, cathode connect 5V DC voltage is grounded further through capacitor C38, capacitor C39, and anode is grounded by capacitor C1, and connects level-one amplifying circuit, together When further through inductance L2, resistance R2 connection optical power sample circuit；Inductance L2 is grounded by resistance R1；Distinguish at the both ends of resistance R2 It is grounded by capacitor C3 and capacitor C4.

Further, the optical power sample circuit, comprising: capacitor C49, capacitor C50, amplifier U2B, resistance R22, electricity Hinder R23 and resistance R24；The resistance R2 of the positive input connection photoelectric conversion circuit of amplifier U2B, and connect by capacitor C49 Ground；The reverse input end of amplifier U2B is grounded by resistance R22；The output end of amplifier U2B is reversed with it by resistance R23 Input terminal connection.

Further, the level-one amplifies capacitor, comprising: amplifier U4, inductance L2, inductance L4, capacitor C2, capacitor C40 With capacitor C41；The input terminal of amplifier U4 passes through the anode of the photodetector PIN-IN of capacitor C2 connection photoelectric conversion circuit, One end of its output end connection inductance L3；One end of the other end connection inductance L4 of inductance L3；The other end of inductance L4 connects 5V DC voltage, while being grounded further through capacitor C40 and capacitor C41.

Further, the level-one amplifying circuit uses GaASMMIC.

In conclusion by adopting the above-described technical solution, the beneficial effects of the utility model are:

The photoelectric conversion circuit of the utility model can receive broader input optical power range, high conversion efficiency, and electricity Line structure is simple, low in cost.

Detailed description of the invention

It, below will be to use required in embodiment in order to illustrate more clearly of the technical solution of the utility model embodiment Attached drawing be briefly described, it should be understood that the following drawings illustrates only some embodiments of the utility model, therefore should not be by Regard the restriction to range as, for those of ordinary skill in the art, without creative efforts, may be used also To obtain other relevant attached drawings according to these attached drawings.

Fig. 1 is the satellite optical receiver circuit structure chart with three-level enlarger of the utility model.

Fig. 2 is the DC/DC circuit diagram of the utility model.

Fig. 3 a-3b is the AGC electric operation control circuit figure of the utility model.

Fig. 4 is the photoelectric conversion circuit figure of the utility model.

Fig. 5 is the level-one amplification circuit diagram of the utility model.

Fig. 6 is the variable attenuation circuit figure of the utility model.

Fig. 7 is the signal distribution circuit figure of the utility model.

Fig. 8 is the second amplifying circuit figure of the utility model.

Fig. 9 is the three-stage amplifier figure of the utility model.

Figure 10 is the main signal output circuit figure of the utility model.

Figure 11 is the detection signal output apparatus figure of the utility model.

Specific embodiment

In order to make the purpose of the utility model, technical solutions and advantages more clearly understood, below in conjunction with attached drawing and implementation Example, the present invention will be further described in detail.It should be appreciated that specific embodiment described herein is only to explain this Utility model is not used to limit the utility model, i.e., the described embodiments are only a part of the embodiments of the utility model, Instead of all the embodiments.The component of the utility model embodiment being usually described and illustrated herein in the accompanying drawings can be with each Different configurations is planted to arrange and design.Therefore, the detailed of the embodiments of the present invention provided in the accompanying drawings is retouched below The range for being not intended to limit claimed invention is stated, but is merely representative of the selected embodiment of the utility model. Based on the embodiments of the present invention, those skilled in the art are obtained all without making creative work Other embodiments are fallen within the protection scope of the utility model.

The feature of the utility model and performance are described in further detail with reference to embodiments.

Embodiment

A kind of satellite optical receiver circuit provided in this embodiment, as shown in Figure 1, comprising: AGC control circuit, photoelectricity turn Change circuit, level-one amplifying circuit, variable attenuation circuit, signal distribution circuit, detection signal output apparatus, second amplifying circuit, Three-stage amplifier and main signal output circuit；The photoelectric conversion circuit is sequentially connected level-one amplifying circuit, variable attenuation electricity Road and signal distribution circuit；The first via output end of the signal distribution circuit is sequentially connected second amplifying circuit, three-level amplification Circuit and main signal output circuit；Second road output end connecting detection signal output apparatus of the signal distribution circuit；It is described AGC control circuit is connect with photoelectric conversion circuit and variable attenuation circuit simultaneously.

After photoelectric conversion circuit receives the optical power signals of CATV and satellite L-Band and is converted into radiofrequency signal, it is sent to Level-one amplifying circuit is sent to variable attenuation circuit through the amplified signal of level-one, and the signal after decaying is distributed by signal Circuit is divided into two-way radiofrequency signal: radiofrequency signal RF1 required for successively exporting after second level amplification and three-level amplification all the way； Radiofrequency signal RF2 of the another way through detection circuit output for product working status detection.In first order amplification, pass through AGC Control circuit samples optical power currently entered, and extremely according to the size output pwm signal of the input optical power of sampling Variable attenuation circuit adjusts the control voltage of attenuator circuit, guarantees to provide the signal of suitable output size for next stage processing, To realize the accurate control function of AGC.

Satellite optical receiver circuit simultaneously further include: DC/DC circuit；Using the DC/DC circuit connection external electrical of low noise Source is the power supply of other function circuit, reduces the interference to other function circuit.

The structure and working principle of entire satellite optical receiver circuit are described in detail below:

(1) DC/DC circuit

As shown in Fig. 2, a kind of DC/DC circuit provided in this embodiment, specifically includes that electric connector DC12VIN, diode D8, diode D9, capacitor C23, capacitor C24, capacitor C25, capacitor C26, capacitor C27, capacitor C28, capacitor C29, direct current conversion Module U1, diode D10, inductance L1, resistance R32, resistance R31, capacitor C33, capacitor C34, capacitor C35, capacitor C36, capacitor C37 and capacitor C38；The positive input of electric connector DC12VIN terminates 12V power supply；The negative input end of diode D8, diode D9 Positive input terminal and capacitor C23, capacitor C24, capacitor C25 and one end of capacitor C26 connect the just defeated of electric connector DC12VIN Enter end；The end G of electric connector DC12VIN and the end gnd ground connection, the positive input terminal of diode D8 and capacitor C23, capacitor C24, The other end of capacitor C25 and capacitor C26 ground connection；The voltage input end of the negative input end connection DC conversion modules U1 of diode D9 1 foot of (1 foot), DC conversion modules U1 is grounded by capacitor C27, capacitor C28 and capacitor C29；4 feet of DC conversion modules U1 Vacantly, 5 feet, 6 feet, 7 feet and 8 feet ground connection；One end of feedback end (3 foot) the connection resistance R31 of DC conversion modules U1, resistance Output end of the other end of R31 as DC/DC circuit exports 5V as the power supply of other function circuit；The other end of resistance R31 connects The positive input terminal of diode D10；The voltage output end (2 foot) of the negative input end connection DC conversion modules of diode；Inductance L1 It is connected in parallel on the both ends of resistance R31；Resistance R32, resistance R31, capacitor C33, capacitor C34, capacitor C35, capacitor C36, capacitor C37 and One end of capacitor C38 is grounded, and the other end connects the other end of resistance R31.

Wherein, diode D8 is TVS protection diode, prevents the component of the excessively high damage subsequent conditioning circuit of input voltage, especially It is reversal connection power supply, and the peak voltage powered suddenly.Diode D9 guarantees that the 12V voltage of input is DC conversion modules U1 1 foot (voltage input end) unidirectionally power, prevent electric current shipwreck；

Capacitor C23, capacitor C24, capacitor C25, capacitor C26, capacitor C27, capacitor C28 and capacitor C29 are as low frequency filtering Circuit prevents low-frequency disturbance；Inductance L1, capacitor C33, capacitor C34, capacitor C35, capacitor C36, capacitor C37 and capacitor C38 conduct Resonator filter circuit；

The feedback end (3 foot) of DC conversion modules U1 divides circuit by external resistance R31 and resistance R32, for examining Survey and adjust output voltage.

DC conversion modules U1 is the DC conversion modules of low switching frequency, preferably, the DC power supplier U1 Switching frequency≤200KHz, can choose XL1509.

(2) AGC control circuit

As best shown in figures 3 a and 3b, AGC control circuit provided in this embodiment specifically includes that MCU, MCU select new pool science and technology T84F16T20；And

Optical power sample circuit specifically includes that capacitor C49, capacitor C50, amplifier U2B, resistance R22, resistance R23 and electricity Hinder R24；The optical power output end of the positive input connection photoelectric conversion circuit of amplifier U2B, and be grounded by capacitor C49； The reverse input end of amplifier U2B is grounded by resistance R22；The output end of amplifier U2B passes through resistance R23 and its reversed input End connection；The output end of amplifier U2B passes through the optical power sampling end (20 foot) of resistance R24 connection MCU (U5)；

AGC signal follows circuit, comprising: capacitor C52, capacitor C53, capacitor C56, resistance R27, resistance R28, resistance R29 With amplifier U2A；The AGC signal output end (1 foot) of MCU (U5) connects one end of resistance R27 and resistance R28 simultaneously；Resistance R27 The other end ground connection；The positive input of resistance R28 connection amplifier U2A, and pass through capacitor C52 and capacitor C53 capacity earth； The output end of amplifier U2A is connect with its reverse input end, and is grounded by capacitor C56；Meanwhile the output end of amplifier U2A Pass through the AGC control signal input of capacitor R29 connection variable attenuation circuit；

The input optical power values of acquisition are sent into the optical power sampling end of MCU (U5) after the amplification of optical power sample circuit (20 foot)；Input optical power values according to the spacing of 0.5dBm, are carried out+3dBm~-7dBm input optical power values by MCU with it The scheme of comparison of tabling look-up is corresponded and is carried out in the way of the corresponding 20dB pad value of+3dBm to the corresponding 0dB pad value of -7dBm Pwm signal output, pwm signal are the digital signal of different duty, follow circuit to amplify and filter using AGC signal and export AGC controls signal.

The AGC control circuit, further includes reset circuit；The reset circuit includes: resistance R25, resistance R26 and capacitor C51；The reset terminal (4 foot) of MCU passes sequentially through resistance R25 and connects 5V DC voltage with resistance R26；Resistance R25 and resistance R26 it Between be grounded by capacitor C51；

The AGC control circuit further includes state circuit for lamp；The state circuit for lamp include: resistance R33, resistance R35 and Dual-colored LED lamp；By resistance R33 connection 5V DC voltage, green light signals end (2 foot) passes through the power end (1 foot) of dual-colored LED lamp 18 feet of resistance R35 connection MCU (U5), red signal end (3 foot) connect 17 feet of MCU (U5)；By 17 feet of MCU (U5) and 18 feet export the bright light color of control signal control dual-colored LED lamp respectively, for the size according to the input optical power values of sampling Range is alarmed, and judges whether to work normally, if the model that the input optical power values of sampling do not record in the table tabled look-up In enclosing, then red alarm is shown, otherwise show that green light indicates to work normally.

(3) photoelectric conversion circuit

As shown in figure 4, the photoelectric conversion circuit, comprising: capacitor C1, capacitor C3, capacitor C4, capacitor C38, capacitor C39, Photodetector PIN-IN, inductance L2, resistance R1 and resistance R2；Photodetector PIN-IN ground terminal ground connection, cathode connection 5V DC voltage is grounded further through capacitor C38, capacitor C39, and anode is grounded by capacitor C1, and connects level-one amplifying circuit, Simultaneously further through optical power input terminal (the positive input of amplifier U2B of inductance L2, resistance R2 connection optical power sample circuit End)；Inductance L2 is grounded by resistance R1；The both ends of resistance R2 pass through capacitor C3 and capacitor C4 ground connection respectively；

Photodetector PIN-IN selects O-Send OPD-1-4-C-P-SC, receives the light function of CATV and satellite L-Band Rate signal is simultaneously converted into after radiofrequency signal output to level-one amplifying circuit, meanwhile, pass through inductance L2, resistance R1, resistance R2, capacitor The load branch of C3 and capacitor C4 composition is exported to the optical power sample circuit of AGC control circuit.Capacitor C38 and capacitor C39 are The 5V DC voltage of input provides filter action.

(4) level-one amplifying circuit

As shown in figure 5, the level-one amplifies capacitor, comprising: amplifier U4, inductance L2, inductance L4, capacitor C2, capacitor C40 With capacitor C41；The input terminal of amplifier U4 passes through the RF signal input end (photodetection of capacitor C2 connection photoelectric conversion circuit The anode of device PIN-IN), output end connects one end of inductance L3；The other end of inductance L3 connects variable attenuation circuit, simultaneously One end of inductance L4 is connected again；The other end of inductance L4 connects 5V DC voltage, while connecing further through capacitor C40 and capacitor C41 Ground.

The radiofrequency signal progress first order amplification that level-one amplifying circuit exports photoelectric conversion circuit, gain amplifier 20db, So that subsequent conditioning circuit is handled.Capacitor C40 and capacitor C41 provides filter action for the 5V DC voltage of input.

(5) variable attenuation circuit

As shown in fig. 6, the variable attenuation circuit, comprising: π type diode, and it is connected to the AGC control of π type diode Signal input circuit, radiofrequency signal input circuit, radiofrequency signal output circuit and pad value reference circuit processed；The AGC control The AGC signal of signal input circuit connection AGC control circuit follows circuit；The radiofrequency signal input circuit connection level-one amplification Circuit；The radiofrequency signal output circuit connection signal distributor circuit；Specifically, the variable attenuation circuit, comprising: π type two Pole pipe D1, capacitor C5, capacitor C6, capacitor C7, capacitor C8, capacitor C9, capacitor C10, capacitor C11, capacitor C42, capacitor C55, electricity Hinder R3, resistance R4, resistance R5, resistance R6, resistance R7, resistance R8, resistance R9 and inductance L17；1 foot of π type diode D1 passes through Capacitor C11 connection signal distributor circuit；2 feet of π type diode D1 are grounded by capacitor C55 and capacitor C6, and connect AGC control The AGC signal output end of circuit；3 feet of π type diode D1 pass through capacitor C5 connection level-one amplifying circuit；The 4 of π type diode D1 Foot is grounded by capacitor C7, and connects one end of resistance R5；5 feet of π type diode D1 are grounded by capacitor C8, and connect resistance One end of R6；The other end of resistance R5 and resistance R6 are grounded by capacitor C9 and capacitor C10；Meanwhile the other end of resistance R6 connects One end of connecting resistance R7；The other end of resistance R7 is grounded by resistance R8, further through resistance R9 connection 5V DC voltage；Resistance R9 One end of connection 5V DC voltage also passes through capacitor C42 and is grounded；

Wherein, the model HMSP3816 of π type diode D1 is made of 4 diodes；The variable attenuation circuit connects The AGC for receiving the output of AGC control circuit controls signal, and the control voltage by controlling π type diode D1 adjusts variable attenuation circuit Pad value, provide sizeable radiofrequency signal for subsequent conditioning circuit.Wherein, resistance R3 and resistance R4 is π type diode D1's Load resistance；Resistance R5, resistance R6, resistance R7, resistance R8, resistance R9, capacitor C9, capacitor C10 and capacitor C42 form itself and decline Depreciation control circuit controls itself pad value 3db of variable attenuation circuit；Capacitor C55, capacitor C6 and inductance L17 are controlled as AGC The filter circuit of signal processed.

(6) signal distribution circuit

As shown in fig. 7, the signal distribution circuit, comprising: adjustable resistance W, inductance L16, capacitor C56, resistance R10, electricity Hinder R11 and resistance R12；Resistance R10 is connected with one end of resistance R11, while variable decline is connected between resistance R10 and resistance R11 Powered down road；The other end of resistance R10 and resistance R11 are separately connected the both ends of resistance R12；One end of resistance R10 connects inductance L16 One end, while connecting second amplifying circuit；The other end of inductance L16 is grounded by capacitor C56, is connect further through adjustable resistance W Ground；One end connection detection circuit of resistance R11；

The resistance combination method of salary distribution that the signal distribution circuit is formed using resistance R10, resistance R11 and resistance R12, will The radiofrequency signal all the way of variable attenuation circuit output is divided into two-way radiofrequency signal；Wherein, by the other end of resistance R10 as Output end all the way, by the other end of resistance R11 as the second road output end；The radiofrequency signal of the first via output end is successively It is main output signal RF1 by the output of second amplifying circuit, three-stage amplifier and main signal output circuit；Second road is defeated The radiofrequency signal of outlet output is detection signal RF2 by the output of detection output circuit.

(7) second amplifying circuit

As shown in figure 8, the second amplifying circuit, comprising: amplifier U5, inductance L7, inductance L8, capacitor C12, capacitor C45；The input terminal of amplifier U5 connects one end of inductance L7 by capacitor C12 connection signal distributor circuit, output end；Inductance The other end of L7 connects three-stage amplifier, while connecting one end of inductance L8 again；The other end of inductance L8 connects 5V direct current Pressure, while being grounded further through capacitor C45；Wherein, of adjustable resistance W, capacitor C56 and inductance L16 composition signal distribution circuit With absorbing circuit.

The radiofrequency signal for the first via output end output that the second amplifying circuit exports signal distribution circuit carries out two Grade amplification, gain amplifier 20db；Wherein, capacitor C45 and inductance L8 provides filter action for the 5V DC voltage of input.

(8) three-stage amplifier

As shown in figure 9, the three-stage amplifier, comprising: amplifier U6, inductance L9, inductance L10, capacitor C13, capacitor C14, capacitor C16, capacitor C46, resistance R13；Amplifier U6 passes sequentially through C capacitor C16, resistance R13, capacitor C13 connection second level Amplifying circuit；It is grounded between capacitor 13 and capacitor R13 by capacitor C14；The output end of amplifier U6 passes sequentially through inductance L9, electricity Feel L10 and capacitor C46 ground connection；Main signal output circuit is connected between inductance L9 and inductance L10；

The radiofrequency signal that the three-stage amplifier exports second amplifying circuit carries out three-level amplification, gain amplifier 16db。

(9) main signal output circuit

As shown in Figure 10, the main signal output circuit, comprising: capacitor C17, capacitor C18, resistance R14, resistance R15, electricity Hinder R16, diode D2, diode D3 and out connector RFOUT1；1 foot of out connector RFOUT1 passes sequentially through capacitor C18, resistance R16, resistance R14, capacitor C17 connection three-stage amplifier；It is connect between resistance R14 and resistance 16 by resistance R15 Ground, while 3 feet of diode D2 are connected again；1 foot and 2 feet of diode D2 is separately connected 1 foot and 2 feet of diode D3；Two poles 3 feet of pipe D3 are grounded；

The main signal output circuit prevents the excessively high damage of moment main signal levels from putting by diode D2 and diode D3 Large chip.

(10) output circuit is detected

As shown in figure 11, the detection output circuit, comprising: detection signal amplification circuit and detection signal output apparatus；

The detection signal amplification circuit, comprising: amplifier U11, inductance L12, inductance L13, capacitor C20 and capacitor C44； The input terminal of amplifier U11 connects one end of inductance L12 by capacitor C20 connection signal distributor circuit, output end；Inductance The other end connecting detection signal output apparatus of L12, while one end of inductance L13 is connected again；The other end of inductance L13 connects 5V DC voltage, while being grounded further through capacitor C44；

The detection signal output apparatus, comprising: capacitor C21, capacitor C49, resistance R17, resistance R18, resistance R19, two Pole pipe D4, diode D5 and out connector RFOUT2；1 foot of out connector RFOUT2 passes sequentially through capacitor C49, resistance R19, resistance R17, capacitor C21 connecting detection signal amplification circuit；It is grounded between resistance R17 and resistance 19 by resistance R18, together When again connect diode D4 3 feet；1 foot and 2 feet of diode D4 is separately connected 1 foot and 2 feet of diode D5；Diode D5's 3 feet ground connection；

The radiofrequency signal for the second road output end output that the detection output circuit exports signal distribution circuit carries out two Grade amplification, exports the radiofrequency signal of 20db lower than main signal, is used for signal detection, can check the work shape of satellite photoreceiver State.

The working principle of the detection signal output apparatus passes through diode D4 and diode with main signal output circuit D5 prevents the excessively high damage amplification chip of moment detection signal level.

Preferably, the level-one amplifying circuit, second amplifying circuit and three-stage amplifier are extremely low using noise GaASMMIC (GaAs MMIC).

The above is only the preferred embodiment of the utility model only, is not intended to limit the utility model, all at this Made any modifications, equivalent replacements, and improvements etc., should be included in the utility model within the spirit and principle of utility model Protection scope within.

Claims (4)

1. a kind of photoelectric conversion circuit for satellite photoreceiver, the satellite photoreceiver include optical power sample circuit and Level-one amplifying circuit, which is characterized in that the photoelectric conversion circuit, comprising: capacitor C1, capacitor C3, capacitor C4, capacitor C38, electricity Hold C39, photodetector PIN-IN, inductance L2, resistance R1 and resistance R2；Photodetector PIN-IN ground terminal ground connection, bears Pole connects 5V DC voltage, is grounded further through capacitor C38, capacitor C39, and anode is grounded by capacitor C1, and connects level-one and put Big circuit, while further through inductance L2, resistance R2 connection optical power sample circuit；Inductance L2 is grounded by resistance R1；Resistance R2 Both ends pass through respectively capacitor C3 and capacitor C4 ground connection.

2. being used for the photoelectric conversion circuit of satellite photoreceiver as described in claim 1, which is characterized in that the optical power is adopted Sample circuit, comprising: capacitor C49, capacitor C50, amplifier U2B, resistance R22, resistance R23 and resistance R24；Amplifier U2B is just To the resistance R2 of input terminal connection photoelectric conversion circuit, and it is grounded by capacitor C49；The reverse input end of amplifier U2B passes through Resistance R22 ground connection；The output end of amplifier U2B is connect by resistance R23 with its reverse input end.

3. being used for the photoelectric conversion circuit of satellite photoreceiver as described in claim 1, which is characterized in that the level-one amplification Capacitor, comprising: amplifier U4, inductance L2, inductance L4, capacitor C2, capacitor C40 and capacitor C41；The input terminal of amplifier U4 passes through The anode of the photodetector PIN-IN of capacitor C2 connection photoelectric conversion circuit, output end connect one end of inductance L3；Inductance One end of the other end connection inductance L4 of L3；The other end of inductance L4 connects 5V DC voltage, while further through capacitor C40 and electricity Hold C41 ground connection.

4. the photoelectric conversion circuit as described in any one of claims 1-3 for satellite photoreceiver, which is characterized in that described Level-one amplifying circuit uses GaASMMIC.