JP4652188B2 - High frequency module device - Google Patents

Description

  The present invention relates to a high-frequency module device used for a communication device, a radar device, or the like.

  As an oscillator used in the microwave / millimeter wave band, a configuration of a high-order subharmonic injection-locked oscillator has been proposed (see, for example, Non-Patent Document 1). This type of injection-locked oscillator outputs a harmonic signal synchronized with a reference signal, and is a technique useful for reducing the price of a high-frequency oscillator such as a millimeter wave band. The phased array antenna is a technique useful for improving communication performance and radar performance by changing an antenna beam in a target direction in communication and radar (for example, see Non-Patent Document 2). In general, in a transmission / reception apparatus used for radar and communication, one antenna is commonly used for transmission and reception, and a transmission / reception high-frequency module is often mounted in one casing (see, for example, Non-Patent Document 3).

Kenji Kamogawa, Kazuhiko Toyoda, etc. “High-order subharmonic MMIC injection synchronous oscillator” 1998 IEICE General Conference Proceedings, IEICE, C-2-32, March 1998 Takashi Yoshida “Revised Radar Technology” edited by The Institute of Electronics, Information and Communication Engineers, P5 to P9 Naoshi Iida "Satellite Communications" Ohm, P124-P129

  In a conventional communication device or radar device, in a high frequency region such as a millimeter wave band, a transmission module and a reception module are installed at a remote location, and a reference signal of about 10 MHz is provided to each module in order to synchronize transmission and reception. Applied. For this reason, it is necessary to separately provide a PLL circuit and an oscillation circuit for each module, resulting in an increase in the size of the apparatus.

  The present invention has been made to solve the above problems, and in a high-frequency region such as a millimeter wave band, the high-frequency module that enables simple synchronization even when the transmitting module and the receiving module are installed at remote locations. The object is to obtain a device.

RF module device according to the present invention, a reference signal source for outputting a reference signal in a microwave band, a power divider for dividing a reference signal, based on the amount provided reference signal N (an integer) times the frequency An RF signal is generated by mixing the signal and the IF signal , a transmission module that supplies the generated RF signal to the transmission antenna, and a frequency of M (integer) times based on the reference signal distributed by the power distributor A receiving module that extracts the IF signal by mixing the signal and the RF signal received by the receiving antenna . The transmitting module and the receiving module are mounted in different housings, and the transmitting module is distributed by the input power distributor. A first injection-locked oscillator that outputs a signal having a frequency N times in synchronization with the frequency of the reference signal, and a signal having an N-times frequency output by the first injection-locked oscillator and an input A transmission mixer that generates an RF signal by mixing the IF signal and a transmission amplifier that amplifies the RF signal generated by the transmission mixer and supplies the RF signal to the transmission antenna. A second injection-locked oscillator that outputs a signal having a frequency M times in synchronization with the frequency of the reference signal distributed by the power distributor, and a low-noise amplifier that amplifies the RF signal received by the input receiving antenna; And a receiving mixer that mixes the RF signal amplified by the low noise amplifier and the M-frequency signal output by the second injection-locked oscillator to extract the IF signal .

According to the present invention, it is possible to input a reference signal from an oscillator to a transmission module and a reception module installed at remote positions with low loss and little phase shift. Therefore, it is possible to reduce the size of the apparatus, and there is an effect of functioning as a useful configuration as the signal N times or M times the frequency of the reference signal becomes a high frequency such as a millimeter wave band. In addition, power loss occurs in the millimeter wave band in the multiplier, but in the case of an injection-locked oscillator, oscillation power depending on the element can be obtained, which is useful in terms of high output.

Embodiment 1 FIG.
1 is a block circuit diagram showing a configuration of a high-frequency module device according to Embodiment 1 of the present invention.
In the figure, a reference signal source 1 is means for outputting a reference signal having a frequency fo in the microwave band, and is constituted by, for example, a voltage controlled oscillator. The power distributor 2 is means for distributing the output wave of the reference signal source 1 into two and supplying it to the transmission module 3 and the reception module 4. The transmission module 3 is mounted on the casing and multiplies the frequency of the distributed reference signal by N (integer), generates an RF signal based on the N-fold signal, and uses the generated RF signal to the transmission antenna. It is a means to supply. In the first embodiment, the transmission module 3 includes a multiplier (first multiplier) 31, a transmission mixer 32, and a transmission amplifier 33. The multiplier 31 is means for generating a signal obtained by multiplying the frequency of the reference signal distributed by the power distributor 2 by N. The transmission mixer 32 is means for generating an RF signal by mixing a signal having a frequency N times that of a reference signal and an input IF signal. The transmission amplifier 33 is means for amplifying the output wave of the transmission mixer 32 and supplying it to the transmission antenna 5. The reception module 4 is mounted in a housing different from the transmission module, generates a signal obtained by multiplying the frequency of the reference signal distributed by the power distributor by M (integer), and a signal whose frequency is M times the reference signal. And means for extracting the IF signal by mixing the RF signal received by the receiving antenna. In the first embodiment, the reception module 4 includes a multiplier (second multiplier) 41, a reception mixer 42, and a low noise amplifier 43. The multiplier 41 is a means for generating a signal obtained by multiplying the frequency of the reference signal distributed by the power distributor by M. The low noise amplifier 43 is means for amplifying the RF signal received by the receiving antenna 6. The reception mixer 42 is means for extracting the IF signal by mixing the amplified RF signal and the signal multiplied by M.

Next, the operation will be described.
A reference signal (power) having a frequency fo in the microwave band is output from the reference signal source 1 and distributed to two outputs by the power distributor 2. One output of the power distributor 2 is input to the transmission module 3. N × fo wave power synchronized with the frequency fo is generated from the multiplier 31 and mixed with the IF signal in the transmission mixer 32 to be an RF signal having the sum frequency (N × fo + fif). The RF signal obtained by the transmission mixer 32 is amplified by the transmission amplifier 33, supplied to the transmission antenna 5, and radiated. On the other hand, in the receiving module 4, the received RF signal extracted from the incoming radio wave by the receiving antenna 6 is amplified by the low noise amplifier 43 and input to the receiving mixer 42. The multiplier 41 receives the other output of the power distributor 2 and generates power of a wave of frequency M × fo synchronized with the frequency fo. In the receiving mixer 42, the power of the wave having the frequency M × fo is mixed with the received RF signal to output an IF signal.

  As described above, according to the first embodiment, the power of 1 / N of the local oscillation frequency used in the transmission mixer 32 and 1 / M of the local oscillation frequency used in the reception mixer 42 is provided outside the module. In addition, it is obtained by branching from the same reference signal source 1 and is generated to power at each local oscillation frequency by the multipliers 31 and 41 in the module. Therefore, it is possible to input the reference signal to the transmission module and the reception module installed at remote positions with low loss and little phase shift. Therefore, the apparatus can be reduced in size, and the more the N times or M times the frequency fo becomes a high frequency such as a millimeter wave band, the more useful the function can be.

Embodiment 2. FIG.
2 is a block circuit diagram showing a configuration of a high-frequency module device according to Embodiment 2 of the present invention. In the figure, parts corresponding to those in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted in principle. Here, the transmission module 3 includes an injection locking oscillator (first) 35 instead of the multiplier 31 of the first embodiment, and the reception module 4 includes an injection locking oscillator (second) instead of the multiplier 41. 45.
The injection locking oscillator 35 is a means for generating a signal having a frequency N times that is synchronized with the frequency fo of the reference signal distributed by the power distributor 2. The injection locked oscillator 45 is a means for generating a signal (M × fo) having a frequency M times that is synchronized with the frequency fo of the reference signal distributed by the power distributor 2.

Next, the operation will be described.
The reference signal (power) of the frequency fo in the microwave band output from the reference signal source 1 is distributed into two by the power distributor 2 and input to the transmission module 3 and the reception module 4 respectively. In the transmission module 3, one output of the power distributor 2 is generated by the injection locking oscillator 35 into the power of the wave having the frequency N × fo synchronized with the frequency fo and supplied to the transmission mixer 32. Further, the other output of the power distributor 2 is generated in the receiving module 4 by the injection locking oscillator 45 into the power of the wave of the frequency M × fo synchronized with the frequency fo, and is supplied to the receiving mixer 42. Since the operations by the transmission mixer 32 and the reception mixer 42 are the same as those in the first embodiment, description thereof is omitted.

  As described above, according to the second embodiment, the power of 1 / N of the local oscillation frequency used in the transmission mixer 32 and 1 / M of the local oscillation frequency used in the reception mixer 42 is provided outside the module. Further, the power is obtained by branching from the same reference signal source 1, and generated by the injection-locked oscillators 35 and 45 in the module to generate power at the respective local oscillation frequencies. Therefore, as in the first embodiment, it is possible to input a reference signal to a transmission module and a reception module that are installed at remote positions with low loss and little phase shift. In the multiplier of the first embodiment, power loss occurs in the millimeter wave band. However, in the case of an injection-locked oscillator, oscillation power depending on the element is obtained, which is useful in terms of high output.

Embodiment 3 FIG.
3 is a block circuit diagram showing a configuration of a high-frequency module device according to Embodiment 3 of the present invention. In the figure, parts corresponding to those in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted in principle. Here, the transmission module 3 includes a modulator 36 instead of the transmission mixer 32 of the first embodiment, and the reception module 4 includes a demodulator 46 instead of the reception mixer 42.
The modulator 36 is a unit that generates an RF signal by modulating a signal having a frequency generated by the multiplier 31 that is N times the reference signal with a modulation signal that is input. The demodulator 46 is a means for generating an IF signal by mixing the received RF signal and a signal having a frequency M times that of the reference signal generated by the multiplier 41.

Next, the operation will be described.
In the transmission module 3, when the power of the wave of the frequency N × fo generated by the multiplier 31 is supplied to the modulator 36, it is modulated by the input modulation signal. The modulated output is power amplified by the transmission amplifier 33 and radiated from the transmission antenna 5. On the other hand, in the receiving module 4, the received RF signal received by the receiving antenna 6 and amplified by the low noise amplifier 43 is input to the demodulator 46 and the power of the wave of frequency M × fo generated by the multiplier 41. The signal is mixed and demodulated into an IF signal.

  As described above, according to the third embodiment, power having a frequency fo of 1 / N of the local oscillation frequency used in the modulator 36 and 1 / M of the local oscillation frequency used in the demodulator 46 is provided outside the module. In addition, the power is obtained from the same reference signal source 1 and branched, and is generated by the multipliers 31 and 41 in the module for the power of the respective local oscillation frequencies. Therefore, as in the first embodiment, the reference signal can be input to the transmission module and the reception module installed at remote positions with low loss and little phase shift. This is a useful configuration.

Embodiment 4 FIG.
4 is a block circuit diagram showing a configuration of a high-frequency module device according to Embodiment 4 of the present invention. In the figure, parts corresponding to those in FIG. RF module device of FIG. 4, the same injection-locked oscillator 35 as that used in Embodiment 2 of FIG. 2, instead of the multiplier 31, also Ru der obtained by applying the injection locking oscillator 45 in place of the multiplier 41. Therefore, description of each component is omitted in principle.

Next, the operation will be described.
The reference signal (power) of the frequency fo in the microwave band output from the reference signal source 1 is distributed into two by the power distributor 2 and input to the transmission module 3 and the reception module 4 respectively. In the transmission module 3, one output of the power distributor 2 is generated into N × fo wave power synchronized with the frequency fo by the injection locking oscillator 35, supplied to the modulator 36, and modulated by the IF signal. The other output of the power distributor 2 is generated in the receiving module 4 as M × fo wave power synchronized with the frequency fo by the injection locking oscillator 45, supplied to the demodulator 46, and mixed with the received RF signal. Thus, the IF signal is demodulated.

  As described above, according to the fourth embodiment, the power of 1 / N of the local oscillation frequency used by the modulator 36 and 1 / M of the local oscillation frequency used by the demodulator 46 is provided outside the module. Further, the power is obtained by branching from the same reference signal source 1, and generated by the injection-locked oscillators 35 and 45 in the module to generate power at the respective local oscillation frequencies. Therefore, it is possible to input a reference signal to a transmission module and a reception module installed at distant positions with low loss and little phase shift, which is a useful configuration in the case of a direct conversion method or the like.

Embodiment 5 FIG.
5 is a block circuit diagram showing a configuration of a high-frequency module device according to Embodiment 5 of the present invention. In the figure, parts corresponding to those in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted in principle. Here, in contrast to the configuration of FIG. 1, the transmission module 3 does not include the transmission mixer 32, and the output of the multiplier 31 is directly amplified by the transmission amplifier 33.

Next, the operation will be described.
The power of the microwave band frequency fo output from the reference signal source 1 is distributed into two by the power distributor 2 and input to the transmission module 3 and the reception module 4 respectively. In the transmission module 3, one output of the power distributor 2 is generated into N × fo wave power synchronized with the frequency fo by the multiplier 31, amplified by the transmission amplifier 33, and then radiated from the transmission antenna 5. Is done. The other output of the power distributor 2 is generated by the multiplier 41 in the Mxfo wave power synchronized with the frequency fo by the multiplier 41, supplied to the reception mixer 42, and mixed with the received RF signal. Frequency converted.

  As described above, according to the fifth embodiment, the power of the frequency fo, which is 1 / N of the frequency of the transmission wave generated by the transmission module 3 and 1 / M of the local oscillation frequency used by the reception mixer 42, is supplied to the outside of the module. Obtained by branching from the same reference signal source 1 provided in the circuit, and the multipliers 31 and 41 in the module generate power of each frequency. Therefore, it is possible to input the reference signal to the transmission module and the reception module installed at remote positions with low loss and little phase shift. The configuration of the fifth embodiment is useful in, for example, an FM radar that performs frequency modulation using a voltage controlled oscillator as the reference signal source 1.

Embodiment 6 FIG.
6 is a block circuit diagram showing a configuration of a high-frequency module device according to Embodiment 6 of the present invention. In the figure, parts corresponding to those in FIG. 5 are denoted by the same reference numerals, and description thereof will be omitted in principle. Here, the same injection locking oscillator 35 described in the second embodiment is applied instead of the multiplier 31 in the configuration of FIG. 5, and an injection locking oscillator 45 is provided instead of the multiplier 41.

Next, the operation will be described.
The reference signal (power) of the frequency fo in the microwave band output from the reference signal source 1 is distributed into two by the power distributor 2 and input to the transmission module 3 and the reception module 4 respectively. In the transmission module 3, one output of the power distributor 2 is generated as N × fo wave power synchronized with the frequency fo by the injection locking oscillator 35, and is input to the transmission amplifier 33 to be amplified and then transmitted. It is supplied to the antenna 5 and radiated. Further, the other output of the power distributor 2 is generated in the receiving module 4 as M × fo wave power synchronized with the frequency fo by the injection locking oscillator 45, supplied to the receiving mixer 42, and mixed with the received RF signal. Frequency conversion.

  As described above, according to the sixth embodiment, the frequency fo is 1 / N of the frequency of the transmission wave generated by the transmission module 3 and 1 / M of the local oscillation frequency used by the reception mixer 42 of the reception module 4. The power is obtained by branching from the same reference signal source 1 provided outside the module, and generated by the injection-locked oscillators 35 and 45 in the module to the power of the respective frequencies. Therefore, it is possible to input the reference signal to the transmission module and the reception module installed at remote positions with low loss and little phase shift. The configuration of the sixth embodiment is useful in, for example, an FM radar that performs frequency modulation with a voltage-controlled oscillator as the reference signal source 1.

Embodiment 7 FIG.
FIG. 7 is a block circuit diagram showing the configuration of the high-frequency module device according to Embodiment 7 of the present invention. In the figure, portions corresponding to those in FIG. 2 are denoted by the same reference numerals, and description thereof will be omitted in principle. Here, power distributors 37 and 47 and phase shift circuits 38 and 48 are newly provided in the transmission module 3 and the reception module 4. Further, here, the transmitting antenna 5 and the receiving antenna 6 are each composed of a plurality of element antennas to form a phased array antenna or a diversity antenna. The power distributor (first distributor) 37 is means for distributing the output wave amplified by the transmission amplifier 37 in accordance with the number of elements of the transmission antenna 5. The phase shift circuit (first phase shifter group) 38 is means for adjusting the phase of each output wave distributed by the power distributor 37 according to each element of the transmission antenna 5. The phase shift circuit (second phase shifter group) 48 is means for adjusting the phase of the received RF signal received by each element of the receiving antenna 6 to match. The power distributor (second distributor) 47 is a means for synthesizing the received RF signal whose phase is matched by the phase shift circuit 48.

Next, the operation will be described.
A reference signal (power) having a frequency fo in the microwave band is output from the reference signal source 1 and distributed to two outputs by the power distributor 2. One output of the power distributor 2 is input to the transmission module 3. Operations up to the injection locking oscillator 35, the transmission mixer 32, and the transmission amplifier 33 are the same as those in the second embodiment. The output wave (N × fo + fif) power-amplified by the transmission amplifier 33 is distributed according to the number of elements of the transmission antenna 5 by the power distributor 37 and is output to the corresponding phase shift circuit 38. The distributed output wave is adjusted by the phase shift circuit 38 and then supplied to each element of the transmission antenna 5 to be radiated. On the other hand, in the receiving module 4, the received RF signals extracted from the respective elements of the receiving antenna 6 are phase-adjusted by the phase shift circuit 48, synthesized by the power distributor 47, and output to the low noise amplifier 43. The operations of the injection locked oscillator 45, the reception mixer 42, and the low noise amplifier 43 are the same as those in the second embodiment, and an IF signal is output from the reception mixer 42.

  As described above, according to the seventh embodiment, the same effect as in the second embodiment can be obtained. In addition, since the phase of each output wave can be set by providing the power distributor and the phase shift circuit, it can be applied to an active phased array antenna that changes the antenna pattern. Further, since transmission and reception can be performed at an arbitrary phase, it is possible to obtain a phased array and diversity effect.

Embodiment 8 FIG.
FIG. 8 is a block circuit diagram showing a configuration of a high-frequency module device according to Embodiment 8 of the present invention. In the figure, the power distributor 2 has a function of branching a plurality of reference signals having a frequency fo in the microwave band and supplying them to a plurality of transmission modules 3 and a plurality of reception modules 4. The reference signal source 1, the transmission module 3, the reception module 5, and the reception antenna 6 have the same configuration as that described in the second embodiment in FIG. Each transmission module 3 and each reception module 4 are mounted in different cases.

Next, the operation will be described.
The reference signal (power) of the frequency fo in the microwave band output from the reference signal source 1 is distributed to a plurality of outputs by the power distributor 2 and supplied to each of the plurality of transmission modules 3 and the plurality of reception modules 4. Is done. Each transmitting module 3 and each receiving module 4 perform the same operation as described in the second embodiment.
Therefore, with the configuration of the eighth embodiment, as in each of the above embodiments, the reference signal can be input to the transmission module and the reception module installed at remote positions with low loss and little phase shift. There is. In addition, since the degree of freedom regarding the arrangement of a plurality of transmission / reception modules is increased, there is an effect of enhancing the effects of phased array and diversity.

Embodiment 9 FIG.
9 is a block circuit diagram showing a configuration of a high-frequency module device according to Embodiment 9 of the present invention. In the figure, the high-frequency module device of the ninth embodiment is configured only by the transmission system of FIG.
In the ninth embodiment, the reference signal (power) of the microwave band frequency fo output from the reference signal source 1 is distributed to a plurality of outputs by the power distributor 2 and supplied to each of the plurality of transmission modules 3. Is done. In each transmission module 3, the same operation as described in the second embodiment is performed.
Therefore, the configuration of the ninth embodiment has an effect that a reference signal can be input to a transmission module installed at a remote position with a low loss and a small phase shift, as in the above embodiments. In addition, there is an effect of enhancing the effects of phased array and diversity when applied to a transmission system of a communication apparatus.

Embodiment 10 FIG.
10 is a block circuit diagram showing a configuration of a high-frequency module device according to Embodiment 10 of the present invention. In the figure, the high-frequency module device of the ninth embodiment is configured only by the receiving system of FIG.
In the tenth embodiment, the reference signal (power) of the frequency fo in the microwave band output from the reference signal source 1 is distributed to a plurality of outputs by the power distributor 2 and supplied to each of the plurality of receiving modules 4. Is done. Each receiving module 4 performs the same operation as described in the above embodiments.
Therefore, the configuration of the tenth embodiment has an effect that a reference signal can be input to a receiving module installed at a distant position with low loss and little phase shift, as in the above embodiments. In addition, there is an effect of enhancing the effects of phased array and diversity when applied to a receiving system of a communication device.

Embodiment 11 FIG.
FIG. 11 is a block circuit diagram showing a configuration of a high frequency module device according to Embodiment 11 of the present invention. In the figure, portions corresponding to those in FIG. 8 are denoted by the same reference numerals, and description thereof will be omitted in principle. The high frequency module device according to the eleventh embodiment is provided with a plurality of phase shift circuits 7 and 8 in addition to the configuration of FIG.
Each of the phase shift circuits 7 and 8 is a means for adjusting the phase of the power of the frequency fo of the microwave band distributed by the power distributor 2. Each transmission module 3 and reception module 4 are the same as those in the fourth embodiment shown in FIG.

In the eleventh embodiment, the reference signal (power) of the frequency fo in the microwave band output from the reference signal source 1 is distributed to a plurality of outputs by the power distributor 2 and given to the plurality of phase shift circuits 7 and 8. After being adjusted in phase, the signals are supplied to a plurality of transmission modules 3 and reception modules 4, respectively. Each transmission module 3 and reception module 4 perform the same operation as described in the fourth embodiment.
Therefore, with the configuration of the eleventh embodiment, there is an effect that the reference signal can be input to the receiving module installed at a remote position with low loss. In addition, by providing a phase shift circuit between each module and the reference signal source, it is possible to set the phase of the wave input to each module, and it can be applied to active phased array antennas that change the antenna pattern. It is. Even when Nfo is a high frequency wave such as a millimeter wave band, the phase shift circuit only needs to be designed with the frequency fo. is there. Furthermore, even when the connection line length between the reference signal source and the plurality of modules is not equal, the optimum phase shift amount can be set by the phase shift circuit, so that the input phases to all the modules can be made equal.

Embodiment 12 FIG.
In the twelfth embodiment, each of the transmission module 3 and / or the reception module 4 in each of the above embodiments is packaged using a process microfabrication technique such as a micromachining technique. This makes it possible to configure a small module.
Therefore, an array antenna that handles a high frequency region such as a millimeter wave band has a short antenna element interval, so that each module needs to be made small. However, by applying Embodiment 12, a small module is realized. be able to. This also has the advantage that the restriction of the mounting part is eliminated and the degree of freedom can be expanded.

Embodiment 13 FIG.
In the thirteenth embodiment, each of the transmission module 3 and the reception module 4 in the first to eleventh embodiments is combined with the respective transmission antenna 5 and reception antenna 6 to process micromachining such as micromachining technology. Each is packaged and integrated using technology. This makes it possible to configure a small module.
Therefore, in addition to the advantages of the thirteenth embodiment, the transmission loss between the antenna and the module can be reduced by integrating the antenna with the module. In addition, by arranging as many modules as necessary for a desired antenna gain, a scalable radar and communication device can be realized.

It is a block circuit diagram which shows the structure of the high frequency module apparatus by Embodiment 1 of this invention. It is a block circuit diagram which shows the structure of the high frequency module apparatus by Embodiment 2 of this invention. It is a block circuit diagram which shows the structure of the high frequency module apparatus by Embodiment 3 of this invention. It is a block circuit diagram which shows the structure of the high frequency module apparatus by Embodiment 4 of this invention. It is a block circuit diagram which shows the structure of the high frequency module apparatus by Embodiment 5 of this invention. It is a block circuit diagram which shows the structure of the high frequency module apparatus by Embodiment 6 of this invention. It is a block circuit diagram which shows the structure of the high frequency module apparatus by 7 of Embodiment of this invention. It is a block circuit diagram which shows the structure of the high frequency module apparatus by Embodiment 8 of this invention. It is a block circuit diagram which shows the structure of the high frequency module apparatus by Embodiment 9 of this invention. It is a block circuit diagram which shows the structure of the high frequency module apparatus by Embodiment 10 of this invention. It is a block circuit diagram which shows the structure of the high frequency module apparatus by Embodiment 11 of this invention.

Explanation of symbols

1 reference signal source, 2, 37, 47 power distributor, 3 transmission module, 4 reception module, 5 transmission antenna, 6 reception antenna, 7, 8, 38, 48 phase shift circuit, 31, 41 multiplier, 32 transmission mixer , 33 Transmitting amplifier, 35, 45 Injection-locked oscillator, 42 receiving mixer, 43 low noise amplifier, 36 modulator, 46 demodulator.

Claims (11)

A reference signal source for outputting a microwave band reference signal;
A power distributor for distributing the reference signal;
Min provided the by mixing the signal and IF signal N (integer) multiple of the frequency based on the reference signal to generate an RF signal, a transmitting module for supplying the generated the RF signal to the transmitting antenna,
And a reception module for taking out the IF signal by mixing the RF signal received by M (an integer) times the signal receiving antenna of a frequency based on the previous SL said reference signal distributed by the power distributor,
The transmission module and the reception module are mounted in different cases,
The transmission module includes:
A first injection-locked oscillator that outputs a signal having a frequency N times in synchronization with the frequency of the reference signal distributed by the input power divider;
A transmission mixer that generates an RF signal by mixing the signal of N times the frequency output by the first injection-locked oscillator and the input IF signal;
A transmission amplifier that amplifies the RF signal generated by the transmission mixer and supplies the amplified RF signal to the transmission antenna;
The receiving module is
A second injection-locked oscillator that outputs a signal having a frequency M times in synchronization with the frequency of the reference signal distributed by the input power divider;
A low noise amplifier for amplifying an RF signal received by the input receiving antenna;
A high-frequency module comprising: a reception mixer that mixes the RF signal amplified by the low-noise amplifier and the M-frequency signal output from the second injection-locked oscillator to extract an IF signal apparatus. A reference signal source for outputting a microwave band reference signal;
A power distributor for distributing the reference signal;
And generates an RF signal, sends supplies the generated the RF signal to the transmitting antenna module by minute arranged signals of N (integer) multiple of the frequency based on the reference signal and the modulation signal,
And a reception module for taking out the IF signal by mixing the RF signal received by M (an integer) times the signal receiving antenna of a frequency based on the previous SL said reference signal distributed by the power distributor,
The transmission module and the reception module are mounted in different cases,
The transmission module includes:
A first injection-locked oscillator that outputs a signal having a frequency N times in synchronization with the frequency of the reference signal distributed by the input power divider;
A modulator that generates an RF signal by modulating the N-times frequency signal output by the first injection-locked oscillator with an input modulation signal;
A transmission amplifier that amplifies the RF signal generated by the modulator and supplies the amplified RF signal to the transmission antenna;
The receiving module is
A second injection-locked oscillator that outputs a signal having a frequency M times in synchronization with the frequency of the reference signal distributed by the input power divider;
A low noise amplifier for amplifying an RF signal received by the input receiving antenna;
A high-frequency module comprising: a demodulator that mixes the RF signal amplified by the low-noise amplifier and the M-frequency signal output from the second injection-locked oscillator to extract an IF signal apparatus. A reference signal source for outputting a microwave band reference signal;
A power distributor for distributing the reference signal;
The N (integer) multiple of the frequency of the signal based on the amount provided the said reference signal and a transmission module to be supplied to the transmitting antenna,
And a reception module for taking out the IF signal by mixing the RF signal received by M (an integer) times the signal receiving antenna of a frequency based on the previous SL said reference signal distributed by the power distributor,
The transmission module and the reception module are mounted in different cases,
The transmission module includes:
A first injection-locked oscillator that outputs a signal having a frequency N times in synchronization with the frequency of the reference signal distributed by the input power divider;
A transmission amplifier that amplifies the signal of the N times frequency output by the first injection-locked oscillator and supplies the signal to the transmission antenna;
The receiving module is
A second injection-locked oscillator that outputs a signal having a frequency M times in synchronization with the frequency of the reference signal distributed by the input power divider;
A low noise amplifier for amplifying an RF signal received by the input receiving antenna;
A high-frequency module comprising: a reception mixer that mixes the RF signal amplified by the low-noise amplifier and the M-frequency signal output from the second injection-locked oscillator to extract an IF signal apparatus. The sending module
A first distributor that distributes the output wave amplified by the transmission amplifier in accordance with the number of elements of the transmission antenna;
A first phase shifter group that adjusts the phase of each output wave distributed by the first distributor and supplies the output wave to each element of the transmission antenna;
The receiving module
A second phase shifter group that adjusts the phase of each received RF signal received by each element of the receiving antenna to match each other;
Of claims 1 to 3, characterized in that it comprises a second distributor for phase by the second phase shifter group is input by combining the received RF signal matched to a low noise amplifier The high frequency module apparatus of any one of Claims. A plurality of transmission modules and reception modules are provided,
5. The high frequency device according to claim 1 , wherein the power distributor distributes a reference signal of a microwave band output from a reference signal source to the plurality of transmission modules and the plurality of reception modules. Modular device. 6. The high-frequency module device according to claim 5 , wherein each transmission module and each reception module are mounted in different housings. A reference signal source for outputting a microwave band reference signal;
A power distributor for distributing the reference signal;
Min provided the by mixing the signal and IF signal N (integer) multiple of the frequency based on the reference signal to generate an RF signal, multiple transmit module supplies the generated the RF signal to the transmitting antenna It equipped with a door,
The plurality of transmission modules are mounted in different cases,
The transmission module includes:
A first injection-locked oscillator that outputs a signal having a frequency N times in synchronization with the frequency of the reference signal distributed by the input power divider;
A transmission mixer that generates an RF signal by mixing the signal of N times the frequency output by the first injection-locked oscillator and the input IF signal;
A high-frequency module device comprising: a transmission amplifier that amplifies the RF signal generated by the transmission mixer and supplies the amplified RF signal to the transmission antenna . A reference signal source for outputting a microwave band reference signal;
A power distributor for distributing the reference signal;
Mixing the RF signal received divided arranged signal of M (integer) multiple of the frequency based on the reference signal and the receiving antenna and a plurality of receiving modules taking out an IF signal,
The plurality of receiving modules are mounted in different cases,
The receiving module is
A second injection-locked oscillator that outputs a signal having a frequency M times in synchronization with the frequency of the reference signal distributed by the input power divider;
A low noise amplifier for amplifying an RF signal received by the input receiving antenna;
A high-frequency module comprising: a reception mixer that mixes the RF signal amplified by the low-noise amplifier and the M-frequency signal output from the second injection-locked oscillator to extract an IF signal apparatus. 9. The high frequency device according to claim 5 , wherein a phase shift circuit is provided between the power distributor and each transmission module and between the power distributor and each reception module. 10. Modular device. At least one of the transmitting module and receiving module, any of claim 9 that is configured to packaged using micromachining techniques such as micromachining, respectively from claim 1, wherein 1 The high-frequency module device according to item. 2. The combination of a transmission module and a transmission antenna and at least one of a combination of a reception module and a reception antenna are each configured by packaging using a micromachining technique such as micromachining. The high-frequency module device according to claim 9 .

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