CN201114044Y - 3W multi- carrier power amplifier of TD-SCDMA system base station - Google Patents
3W multi- carrier power amplifier of TD-SCDMA system base station Download PDFInfo
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- CN201114044Y CN201114044Y CNU200720087636XU CN200720087636U CN201114044Y CN 201114044 Y CN201114044 Y CN 201114044Y CN U200720087636X U CNU200720087636X U CN U200720087636XU CN 200720087636 U CN200720087636 U CN 200720087636U CN 201114044 Y CN201114044 Y CN 201114044Y
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02D—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN INFORMATION AND COMMUNICATION TECHNOLOGIES [ICT], I.E. INFORMATION AND COMMUNICATION TECHNOLOGIES AIMING AT THE REDUCTION OF THEIR OWN ENERGY USE
- Y02D30/00—Reducing energy consumption in communication networks
- Y02D30/70—Reducing energy consumption in communication networks in wireless communication networks
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Abstract
The utility model relates to a 3W multi-carrier power amplifier used in a TD-SCDMA system base station. The utility model is characterized in that the power amplifier comprises an input connector (A), a power magnifying circuit, a low-noise magnifying circuit, a switch circuit (13) and a radio frequency switch control circuit (18), wherein, the power magnifying circuit comprises a temperature compensated attenuator (1), a primary amplifier (2), a first medium filter (3), a secondary amplifier (4), a phase shifter (5), a third-stage amplifier (6), a fourth-stage amplifier (7), a fifth-stage amplifier (8), a directional coupler (9), a circulator (10), a coupler (11) and a first radio frequency switch (12); the low-noise magnifying circuit comprises a primary amplifier (14), a secondary amplifier (15), a second radio frequency switch (16) and a second medium filer (17). The 3W multi-carrier power amplifier not only satisfies the requirement of an ACPR but also has high working efficiency; meanwhile, the 3W multi-carrier power amplifier ensures that the power magnifying circuit and the low-noise magnifying circuit work reliably and stably, thereby being widely applicable to the TD-SCDMA system base station.
Description
Technical field
The utility model relates to a kind of power amplifier, is specifically related to a kind of 3W Multi-Carrier Power Amplifier of the TD-SCDMA of being used for system base-station.
Background technology
The TD-SCDMA/3W Multi-Carrier Power Amplifier, because neighboring trace suppresses (ACPR) index request height, good linearity, efficient requires high, for the level Four amplifier, how to select the cooperation of amplifier tubes at different levels in design, is a problem with challenge.For the efficiency index requirement, the power tube of last main amplifying stage can not select the excessive power of can not selecting of power too small.The excessive then power consumption of power is bigger; The too small requirement that then can not satisfy the neighboring trace inhibition again of power.Power amplifier for high efficiency requires and high linear index requires only can not satisfy index request with the back-off technology.
Work of TD-SCDMA/3W Multi-Carrier Power Amplifier and time-division state, inner power amplifier and the work of LNA circuit time-division, under power amplifier volume requirement conditions of higher, how to guarantee that the functional reliability of power amplifier and LNA circuit and stability also are technological challenges.
Summary of the invention
The purpose of this utility model is to provide a kind of 3W Multi-Carrier Power Amplifier of the TD-SCDMA of being used for system base-station, and it had both satisfied the requirement of neighboring trace inhibition (ACPR), can accomplish high efficiency again; Can guarantee again simultaneously that power amplifier and LNA circuit working are reliable, stable.
To achieve these goals, the technical solution of the utility model is: the 3W Multi-Carrier Power Amplifier in the TD-SCDMA system base-station is characterized in that: it comprises input connector A, power amplifier, LNA circuit, switching circuit 13 and radio-frequency (RF) switch control circuit 18; Power amplifier comprises temperature compensation attenuator 1, first order amplifier 2, first dielectric filter 3, second level amplifier 4, phase shifter 5, third level amplifier 6, fourth stage amplifier 7, level V amplifier 8, directional coupler 9, circulator 10, coupler 11, first radio-frequency (RF) switch 12; The LNA circuit comprises first order amplifier 14, second level amplifier 15, second radio-frequency (RF) switch 16 and second dielectric filter 17; Input connector A connects the input of temperature compensation attenuator 1, the output of temperature compensation attenuator 1 connects the input of the first order amplifier 2 of power amplifier, the output of the first order amplifier 2 of power amplifier connects first dielectric filter, 3 inputs, the output of first dielectric filter 3 connects the input of the second level amplifier 4 of power amplifier, the input that the output of the second level amplifier 4 of power amplifier connects phase shifter 5 connects, the output of phase shifter 5 connects the input of third level amplifier 6, and the output of third level amplifier 6 connects the input of fourth stage amplifier 7; The output of fourth stage amplifier 7 connects the input of level V amplifier 8, level V amplifier 8 outputs connect the input of directional coupler 9, directional coupler 9 outputs have two paths of signals, the first via of directional coupler 9 is connected with the first input end of first radio-frequency (RF) switch 12 by the coupled end of directional coupler 9, the second road output of directional coupler 9 links to each other with the port one of circulator 10, port 2 outputs of circulator 10 link to each other with the input of output input connector B, and the port 3 of circulator 10 links to each other with the input of switching circuit 13; First output of switching circuit 13 links to each other with the input of coupler 11, the output of coupler 11 links to each other with second input of first radio-frequency (RF) switch 12, the control end of first radio-frequency (RF) switch 12 is connected with the 1st control end of radio-frequency (RF) switch control circuit 18, and the output of first radio-frequency (RF) switch 12 links to each other with second input of second radio-frequency (RF) switch 16; Second output of switching circuit 13 is connected with the input of the first order amplifier 14 of LNA circuit, the output of the first order amplifier 14 of LNA circuit is connected with the input of the second level amplifier 15 of LNA circuit, the output of the second level amplifier 15 of LNA circuit and the first input end of second radio-frequency (RF) switch 16, the output of second radio-frequency (RF) switch 16 is connected with second dielectric filter, 17 inputs, the output of second dielectric filter 17 is connected with out connector C, the control end of switching circuit 13 is connected with the 2nd control end of radio-frequency (RF) switch control circuit 18, and the control end of second radio-frequency (RF) switch 16 is connected with the 3rd control end of radio-frequency (RF) switch control circuit 18.
Described temperature compensation attenuator 1 is the 3-9 or the 6-9 of SANGSHINE company; The amplifier tube of the first order amplifier 2 of power amplifier is the RF3315 of RFMD company, first dielectric filter 3 is the DFCH32G01HDNAA of MURURA company, the amplifier tube of the second level amplifier 4 of power amplifier is the RF3315 of RFMD company, phase shifter 5 is the PS214-315 of SKYWORKS company, the third level amplifier 6 of power amplifier is the HMC454 of HITTITE company, the amplifier tube of the fourth stage amplifier 7 of power amplifier is the MRF282ZR1 or the MRF282SR1 of FREESCALE company, and the amplifier tube of the level V amplifier 8 of power amplifier is the MRF6S19060NBR1 or the MRF6S19060HR3 of FREESCALE company; Directional coupler 9 is the XC2100A-20 of ANAREN company; Circulator 10 reaches the M201025CFS1ZW of letter company for Shanghai, and coupler 11 is the JP520 of ANAREN company; First radio-frequency (RF) switch 12 is the HMC194MS8E of HITTITE company; Switching circuit 13 is the WKB018025P in 55 in Nanjing, the amplifier tube of the first order amplifier 14 of LNA circuit is the ATF54143 of Agilent company, the amplifier tube of the second level amplifier 15 of LNA circuit is the ATF53189 of Agilent company, second dielectric filter 17 is the DFCH32G01HDNAA of MURURA company, and second radio-frequency (RF) switch 16 is the HMC194MS8E of HITTITE company; Chip in the radio-frequency (RF) switch control circuit 18 is the 74AHC04 or the 74AHC08 of TI company.
The utility model is in order to satisfy high efficiency requirement, the model and the operating state of suitable selection power tubes at different levels; Suppress the requirement of (ACPR) and very big surplus capacity arranged in order to satisfy neighboring trace, adopt pre-distortion technology, thus make power amplifier when power output is 3W ± the 1.6MHz band is outer to be suppressed≤-48dBc, the outer inhibition of ± 3.2MHz band≤-53dBc; And by high low temperature test, stability and reliability experiment and HALT experiment, power amplifier and LNA circuit working are reliable, stable; This power amplifier consumes little, and total operating efficiency is 9%~10%.
Useful fruit of the present utility model is: both satisfied the requirement of neighboring trace inhibition (ACPR), can accomplish high efficiency again; Can guarantee again simultaneously that power amplifier and LNA circuit working are reliable, stable.
Description of drawings
Fig. 1 is the utility model schematic block circuit diagram
Embodiment
As shown in Figure 1, a kind of 3W Multi-Carrier Power Amplifier that is used for the TD-SCDMA system base-station, it comprises input connector A, power amplifier, LNA circuit, switching circuit 13 and radio-frequency (RF) switch control circuit 18; Power amplifier comprises temperature compensation attenuator 1, first order amplifier 2, first dielectric filter 3, second level amplifier 4, phase shifter 5, third level amplifier 6, fourth stage amplifier 7, level V amplifier 8, directional coupler 9, circulator 10, coupler 11, first radio-frequency (RF) switch 12; The LNA circuit comprises first order amplifier 14, second level amplifier 15, second radio-frequency (RF) switch 16 and second dielectric filter 17; Input connector A connects the input of temperature compensation attenuator 1, the output of temperature compensation attenuator 1 connects the input of the first order amplifier 2 of power amplifier, the output of the first order amplifier 2 of power amplifier connects first dielectric filter, 3 inputs, the output of first dielectric filter 3 connects the input of the second level amplifier 4 of power amplifier, the input that the output of the second level amplifier 4 of power amplifier connects phase shifter 5 connects, the output of phase shifter 5 connects the input of third level amplifier 6, and the output of third level amplifier 6 connects the input of fourth stage amplifier 7; The output of fourth stage amplifier 7 connects the input of level V amplifier 8, level V amplifier 8 outputs connect the input of directional coupler 9, directional coupler 9 outputs have two paths of signals, the first via of directional coupler 9 is connected with the first input end of first radio-frequency (RF) switch 12 by the coupled end of directional coupler 9, the second road output of directional coupler 9 links to each other with the port one of circulator 10, port 2 outputs of circulator 10 link to each other with the input of output input connector B, and the port 3 of circulator 10 links to each other with the input of switching circuit 13; First output of switching circuit 13 links to each other with the input of coupler 11, the output of coupler 11 links to each other with second input of first radio-frequency (RF) switch 12, the control end of first radio-frequency (RF) switch 12 is connected with the 1st control end of radio-frequency (RF) switch control circuit 18, and the output of first radio-frequency (RF) switch 12 links to each other with second input of second radio-frequency (RF) switch 16; Second output of switching circuit 13 is connected with the input of the first order amplifier 14 of LNA circuit, the output of the first order amplifier 14 of LNA circuit is connected with the input of the second level amplifier 15 of LNA circuit, the output of the second level amplifier 15 of LNA circuit and the first input end of second radio-frequency (RF) switch 16, the output of second radio-frequency (RF) switch 16 is connected with second dielectric filter, 17 inputs, the output of second dielectric filter 17 is connected with out connector C, the control end of switching circuit 13 is connected with the 2nd control end of radio-frequency (RF) switch control circuit 18, and the control end of second radio-frequency (RF) switch 16 is connected with the 3rd control end of radio-frequency (RF) switch control circuit 18.
Described temperature compensation attenuator 1 is the 3-9 or the 6-9 of SANGSHINE company; The amplifier tube of the first order amplifier 2 of power amplifier is the RF3315 of RFMD company, first dielectric filter 3 is the DFCH32G01HDNAA of MURURA company, the amplifier tube of the second level amplifier 4 of power amplifier is the RF3315 of RFMD company, phase shifter 5 is the PS214-315 of SKYWORKS company, the third level amplifier 6 of power amplifier is the HMC454 of HITTITE company, the amplifier tube of the fourth stage amplifier 7 of power amplifier is the MRF282ZR1 or the MRF282SR1 of FREESCALE company, and the amplifier tube of the level V amplifier 8 of power amplifier is the MRF6S19060NBR1 or the MRF6S19060HR3 of FREESCALE company; Directional coupler 9 is the XC2100A-20 of ANAREN company; Circulator 10 reaches the M201025CFS1ZW of letter company for Shanghai, and coupler 11 is the JP520 of ANAREN company; First radio-frequency (RF) switch 12 is the HMC194MS8E of HITTITE company; Switching circuit 13 is the WKB018025P in 55 in Nanjing, the amplifier tube of the first order amplifier 14 of LNA circuit is the ATF54143 of Agilent company, the amplifier tube of the second level amplifier 15 of LNA circuit is the ATF53189 of Agilent company, second dielectric filter 17 is the DFCH32G01HDNAA of MURURA company, and second radio-frequency (RF) switch 16 is the HMC194MS8E of HITTITE company; Chip in the radio-frequency (RF) switch control circuit 18 is the 74AHC04 or the 74AHC08 of TI company.
The input signal of power amplifier part is through input connector A, through inputing to the first order amplifier 2 of power amplifier after 1 decay of temperature compensation attenuator, the output of the first order amplifier 2 of power amplifier is connected the filtering that realizes input signal with the input of first dielectric filter 3, guarantee that input signal is a signal in the working frequency range, first dielectric filter, 3 outputs are connected with the input of the two-stage amplifier 4 of power amplifier, the output of the second level amplifier 4 of power amplifier is connected with the input of phase shifter 5, the output of phase shifter 5 connects the input of third level amplifier 6, the output of third level amplifier 6 is connected with the input of fourth stage amplifier 7, and the output of fourth stage amplifier 7 is connected with the input of level V amplifier 8; This Pyatyi amplifier realization is satisfied the requirement of gain and power output, efficient, linearity to the amplification of signal, cooperates with phase shifter circuit simultaneously, improves the index of power amplifier linearity and efficient.During power amplifier work, the control principle of switching circuit 13 is when first output of switching circuit 13 links to each other with the input of coupler 11, first radio-frequency (RF) switch 12 is sent high-low level by system and is determined it is forward power detection or backward power detection at this moment, port 2 outputs of circulator 10 are connected with output input connector B, are the physical interface of power amplifier power output.Described phase shifter 5 is adjusted the phase place of power amplifier by the voltage control phase shifter, makes the phase distortion minimum of power amplifier, improves the linearity of power amplifier.
The input signal of LNA circuit part inputs to the port 2 of circulator (10) through output input connector B, the output of the port 2 of circulator (10) is connected with the input of switching circuit (13), switching circuit (13) is subjected to the control (control end of switching circuit 13 is connected with the 2nd control end of radio-frequency (RF) switch control circuit 18) of radio-frequency (RF) switch control circuit 18, when the complete machine power amplifier was in the work of LNA state, switching circuit (13), the first radio-frequency (RF) switch WKB018025P partly linked to each other with LNA.Second output of switching circuit (13) is connected with the input of the first order amplifier (14) of LNA circuit, the output of the first order amplifier (14) of LNA circuit is connected with the input of the second level amplifier (15) of LNA circuit, output to the second radio-frequency (RF) switch (16) of second level amplifier (15), second radio-frequency (RF) switch (16) is subjected to the control (control end of radio-frequency (RF) switch 16 is connected with the 3rd control end end of radio-frequency (RF) switch control circuit 18) of radio-frequency (RF) switch control circuit 18, when the complete machine power amplifier is in the work of LNA state, the output of second radio-frequency (RF) switch (16) is connected with the input of second dielectric filter (17), and the output of second dielectric filter (17) links to each other with out connector C.
The explanation of TD-SCDMA power amplifier time-division synchronous control technique:
TD-SCDMA power amplifier time-division synchronous control technique is divided into three bulks: one, amplifier power supply time-division management; Two, amplifier power supply protection; Three, radio-frequency channel diverter switch protection.
One, amplifier power supply time-division management:
The LDMOS power amplifying device can normally be used on off state, and the switching response time of its device own can not make a big impact to the response speed of system fully substantially at tens nanosecond orders.Concrete switch control point, the grid and the drain electrode that are selected in device have only minute differences.But, consider that drain electrode is big by electric current, control device is required height, generally be selected in grid and do the switch control point.
Select grid to do the time-division control point, generally use electronic switch to get final product as diverter switch.As CD4066, the aanalogvoltage that can pass through when 5V powers is 5V, electric current 20mA, switching response time representative value 35ns.Be enough to meet the demands.
If the use single-pole single-throw switch (SPST), the control point of switch still drains and all can face a problem no matter be chosen in grid.It is exactly the response time of turn-offing.The resistance to earth that is used for power amplification LDMOS device grids and drain electrode all is very big, when being installed in the power amplifier generally more than 5M Europe.Cause switch to close like this and have no progeny, the path that the electric charge that accumulates does not have bleed off is gone up in grid or drain electrode, closes and has no progeny for a long time, and the voltage in grid or the drain electrode still remains on the very high voltage, can not satisfy the requirement of TD-SCDMA agreement to the time slot switch speed.Ways of addressing this issue is to add discharge circuit to grid or drain electrode.Because the electric current of grid is minimum,, when closing, make the grounded-grid discharge so the discharge circuit of grid can use single-pole double-throw switch (SPDT).Drain current is bigger, and common single-pole double-throw switch (SPDT) can not bear big electric current and big voltage, so need make discharge circuit with triode or metal-oxide-semiconductor.
Two, amplifier power supply protection:
For cutting down the consumption of energy, reduce operating cost, the TD-SCDMA system requires very high for the efficient of power amplifier.While is for the consideration of the problem of the isolation of up-downgoing.Determined the up-downgoing passage in the power amplifier to require when up (descending) works descending (up) to turn-off fully.So the power supply of up-downgoing is not allow that electricity work is arranged simultaneously.For the control timing that the prevents outside input malfunction that is interfered causes power supply to open work simultaneously.Partly added the power interlock protection at power management.Specific practice is to use comparator that the supply voltage of up-downgoing is monitored, the supervisory signal that comparator obtains feeds back to the logic control part, the logic control part is carried out the interlocking logic to the supervisory signal of two-way, guarantees that another road mains switch can not be opened when one road power supply has electricity.
Three, radio-frequency channel diverter switch protection:
The mode of working along both lines is used in the diverter switch of up-downgoing radio-frequency channel and the design of insulation blocking.Select the PIN pipe radio-frequency (RF) switch of high tolerance power high-isolation on the one hand for use.Unite on the other hand and use circulator and radio-frequency (RF) switch, add circulator between passage diverter switch, power amplifier output and antenna port, the use circulator increases the isolation between PA passage and the LNA passage.
The design of the sequential safety of the diverter switch of radio-frequency channel.The switching sequence of channel switch is synchronous with the work of up-downgoing two-way amplifier.Because the amplifier of LNA passage all is a small signal amplifier, the tolerance performance number of device is not high.If the sequential mistake of the diverter switch of radio-frequency channel has switched to the LNA passage when PA works.Then the output of PA has been added on the LNA entirely when total reflection, and therefore the device of LNA can damage.
The method that solves is that ability switched to the diverter switch of radio-frequency channel on the LNA passage when LNA power supply was opened with the sequential of the diverter switch of radio-frequency channel and LNA power management control signal hook.
Claims (2)
1.TD-SCDMA the 3W Multi-Carrier Power Amplifier in the system base-station is characterized in that: it comprises input connector (A), power amplifier, LNA circuit, switching circuit (13) and radio-frequency (RF) switch control circuit (18); Power amplifier comprises temperature compensation attenuator (1), first order amplifier (2), first dielectric filter (3), second level amplifier (4), phase shifter (5), third level amplifier (6), fourth stage amplifier (7), level V amplifier (8), directional coupler (9), circulator (10), coupler (11), first radio-frequency (RF) switch (12); The LNA circuit comprises first order amplifier (14), second level amplifier (15), second radio-frequency (RF) switch (16) and second dielectric filter (17); Input connector (A) connects the input of temperature compensation attenuator (1), the output of temperature compensation attenuator (1) connects the input of the first order amplifier (2) of power amplifier, the output of the first order amplifier (2) of power amplifier connects first dielectric filter (3) input, the output of first dielectric filter (3) connects the input of the second level amplifier (4) of power amplifier, the input that the output of the second level amplifier (4) of power amplifier connects phase shifter (5) connects, the output of phase shifter (5) connects the input of third level amplifier (6), and the output of third level amplifier (6) connects the input of fourth stage amplifier (7); The output of fourth stage amplifier (7) connects the input of level V amplifier (8), level V amplifier (8) output connects the input of directional coupler (9), directional coupler (9) output has two paths of signals, the first via of directional coupler (9) is connected with the first input end of first radio-frequency (RF) switch (12) by the coupled end of directional coupler (9), the second road output of directional coupler (9) links to each other with the port one of circulator (10), port 2 outputs of circulator (10) link to each other with the input of output input connector (B), and the port 3 of circulator (10) links to each other with the input of switching circuit (13); First output of switching circuit (13) links to each other with the input of coupler (11), the output of coupler (11) links to each other with second input of first radio-frequency (RF) switch (12), the control end of first radio-frequency (RF) switch (12) is connected with the 1st control end of radio-frequency (RF) switch control circuit (18), and the output of first radio-frequency (RF) switch (12) links to each other with second input of second radio-frequency (RF) switch (16); Second output of switching circuit (13) is connected with the input of the first order amplifier (14) of LNA circuit, the output of the first order amplifier (14) of LNA circuit is connected with the input of the second level amplifier (15) of LNA circuit, the output of the second level amplifier (15) of LNA circuit and the first input end of second radio-frequency (RF) switch (16), the output of second radio-frequency (RF) switch (16) is connected with second dielectric filter (17) input, the output of second dielectric filter (17) is connected with out connector (C), the control end of switching circuit (13) is connected with the 2nd control end of radio-frequency (RF) switch control circuit (18), and the control end of second radio-frequency (RF) switch (16) is connected with the 3rd control end of radio-frequency (RF) switch control circuit (18).
2. the 3W Multi-Carrier Power Amplifier in the TD-SCDMA system base-station according to claim 1 is characterized in that: described temperature compensation attenuator (1) is the 3-9 or the 6-9 of SANGSHINE company; The amplifier tube of the first order amplifier (2) of power amplifier is the RF3315 of RFMD company, first dielectric filter (3) is the DFCH32G01HDNAA of MURURA company, the amplifier tube of the second level amplifier (4) of power amplifier is the RF3315 of RFMD company, phase shifter (5) is the PS214-315 of SKYWORKS company, the third level amplifier (6) of power amplifier is the HMC454 of HITTITE company, the amplifier tube of the fourth stage amplifier (7) of power amplifier is the MRF282ZR1 or the MRF282SR1 of FREESCALE company, and the amplifier tube of the level V amplifier (8) of power amplifier is the MRF6S19060NBR1 or the MRF6S19060HR3 of FREESCALE company; Directional coupler (9) is the XC2100A-20 of ANAREN company; Circulator (10) reaches the M201025CFS1ZW of letter company for Shanghai, and coupler (11) is the JP520 of ANAREN company; First radio-frequency (RF) switch (12) is the HMC194MS8E of HITTITE company; Switching circuit (13) is the WKB018025P in 55 in Nanjing, the amplifier tube of the first order amplifier (14) of LNA circuit is the ATF54143 of Agilent company, the amplifier tube of the second level amplifier (15) of LNA circuit is the ATF53189 of Agilent company, second dielectric filter (17) is the DFCH32G01HDNAA of MURURA company, and second radio-frequency (RF) switch (16) is the HMC194MS8E of HITTITE company; Chip in the radio-frequency (RF) switch control circuit (18) is the 74AHC04 or the 74AHC08 of TI company.
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Cited By (1)
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CN107896116A (en) * | 2016-09-30 | 2018-04-10 | 南京誉葆科技有限公司 | A kind of Data-Link radio system |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN107896116A (en) * | 2016-09-30 | 2018-04-10 | 南京誉葆科技有限公司 | A kind of Data-Link radio system |
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Granted publication date: 20080910 Termination date: 20101022 |