JP4522317B2 - Communication device - Google Patents

Description

  The present invention relates to a communication apparatus that performs frequency conversion on a communication signal a plurality of times, and more particularly to a communication apparatus that performs frequency conversion using a multi-loop frequency synthesizer.

  2. Description of the Related Art Conventionally, in a circuit configuration of a communication wireless device, a double conversion method composed of two local oscillators has been widely used. Advantages of the double conversion method include easy filtering at an intermediate frequency and inexpensive amplifier configuration.

  FIG. 7 shows a basic configuration of the double conversion method, and constitutes the transmission unit 100 in the communication apparatus. In the frequency converter 1, the intermediate frequency F1 is combined with the output frequency F4 of the local oscillator 4 to create the intermediate frequency F2, and the output frequency F5 of the local oscillator 5 is further combined with the signal in the frequency converter 2 to generate the transmission frequency F3. produce. As a frequency configuration generally used for communication, the intermediate frequency F1 is several tens to several hundreds MHz, the intermediate frequency F2 is several hundreds MHz, and the transmission frequency F3 is several GHz to several tens GHz.

  The output frequency F4 of the local oscillator 4 depends on several hundred MHz, and the output frequency F5 of the local oscillator 5 depends on the transmission frequency F3. The intermediate frequencies F1 and F2 are fixed, and the transmission frequency F3 is switched by changing the output frequency F5 of the local oscillator 5.

  The following Patent Document 1 shows a configuration example of a double conversion receiver (double conversion tuner).

  FIG. 8 shows a communication apparatus that includes a receiving unit 200 paired with the transmitting unit 100 shown in FIG. 7 and is connected to an antenna ANT. In the receiving unit 200, the frequency converter 6 combines the reception frequency F6 of the received signal from the antenna ANT with the output frequency F9 of the local oscillator 9 to create an intermediate frequency F7, and further outputs the output frequency of the local oscillator 10 to the signal. F10 is synthesized in the frequency converter 7 to produce an intermediate frequency F8.

  Also in the receiving unit 200, like the transmitting unit 100, as a commonly used frequency configuration, the receiving frequency F6 is several GHz to several tens GHz, the intermediate frequency F7 is several hundred MHz, and the intermediate frequency F8 is several tens of MHz to It is several hundred MHz. The output frequency F9 of the local oscillator 9 depends on the reception frequency F6, and the output frequency F10 of the local oscillator 10 is several hundred MHz. The intermediate frequencies F7 and F8 are fixed, and the reception frequency F6 is switched by changing the output frequency F9 of the local oscillator 9.

  In such a communication radio device, the local oscillators 5 and 9 in the double conversion method are required to have extremely low noise characteristics and high external fluctuation resistance against vibrations by increasing the radio frequency and multi-level modulation. Yes.

  In order to realize such a high-performance oscillator at a small size and at a low cost, the local oscillators 5 and 9 often use a multi-loop frequency synthesizer in which a plurality of frequency synthesizers are combined. A combined multiple loop frequency synthesizer is shown. A multi-loop frequency synthesizer using two frequency synthesizers as described above will be described using the local oscillator 5 as an example.

  In FIG. 9, the local oscillator 5 is configured by connecting two frequency synthesizers 51 and 52 in series. These two frequency synthesizers 51 and 52 are PLL circuits. In the frequency synthesizer 51, the reference signal from the reference signal generator 10 is divided by the frequency divider 11, the phase comparator 12, the loop filter 13, and the voltage. An output signal from the voltage controlled oscillator 14 is input to the frequency synthesizer 52, which is input to the first PLL loop including the controlled oscillator (VCO) 14 and the frequency divider 15.

  In the frequency synthesizer 52, the output signal from the frequency synthesizer 51 is divided by the frequency divider 27, and the frequency converter 21, the frequency divider 22, the phase comparator 23, the loop filter 24, the voltage controlled oscillator 25, and the frequency divider 1 is supplied to the frequency converter 2 shown in FIG. 1 as a signal of the output frequency F5 of the local oscillator 5.

  By using a multiple loop configuration as shown in FIG. 9, the total frequency division number in the frequency synthesizer can be reduced, the loop gain can be increased, and the frequency with low noise and high stability against disturbance can be achieved. A synthesizer can be realized.

Examples of the configuration of the multiple loop synthesizer are shown in Patent Document 2 and Patent Document 3 below, for example.
Japanese Patent Laid-Open No. 11-289268 JP 2004-32348 A JP 2000-261318 A

  Thus, the local oscillators 4 and 10 have conventionally used a single frequency synthesizer, and the local oscillators 5 and 9 have been used multiple loop synthesizers connected to multiple frequency synthesizers. In the communication wireless device adopting the above, since each of the transmission unit and the reception unit requires two local oscillators, the ratio of the cost, mounting area, power consumption, etc. occupied by the local oscillators is very large. Further, diversified frequency components generate unnecessary wave components due to complicated mixing or interference.

  Further, in each of the transmission unit and the reception unit, not only the double conversion method in which the frequency conversion is performed twice, but also the method in which the frequency conversion is performed three times or more similarly requires three or more local oscillators. Problems such as high cost and increased mounting area arise.

  In view of the above problems, an object of the present invention is to reduce the number of local oscillators in a communication device that performs frequency conversion a plurality of times.

In order to achieve the above object, the communication apparatus according to the present invention controls the frequency of the first output signal according to the phase difference between the reference signal and the first output signal fed back by the feedback loop. frequency of the first frequency synthesizer and, divided signal by the second output signal fed back by the first output signal and a feedback loop frequency divider for outputting a first output signal synchronized with the signal The frequency conversion signal by the converter, the signal obtained by dividing the frequency conversion signal by the frequency divider, and the signal obtained by dividing the first output signal by the frequency divider , according to the phase difference signal by the phase comparator . a second frequency synthesizer for outputting a second controlling the frequency of the output signal the output signal of said second synchronized with said first output signal, the first frequency signal first output signal input The first round which is converted to the second frequency signal according to the frequency and output The number converter, characterized by comprising a second frequency converter for transmitting by converting the frequency signals of the second to the third frequency signal according to the frequency of the second output signal.

  That is, the output signal of the first frequency synthesizer is given to the first frequency converter to create a second frequency signal from the input first frequency signal, and the output signal of the second frequency synthesizer is changed to the second frequency signal. Since the third frequency signal is generated from the second frequency signal by giving to the frequency converter and used as the transmission signal, the local oscillator for the first frequency converter (the local oscillator in the conventional example shown in FIG. 7) 4) is not required.

  A means for dividing or multiplying the frequency of the second output signal and inputting it to the second frequency converter may be further provided.

  Further, there may be further provided means for dividing, multiplying, or frequency-converting the frequency of the first output signal and giving the frequency to the first frequency converter.

Furthermore, in the communication device according to the present invention, in addition to the configuration of the transmission unit described above, a signal obtained by frequency-dividing the first output signal as a reception unit and the third output signal fed back by a feedback loop by a frequency divider, and According to the phase difference signal by the phase comparator between the frequency converted signal by the frequency converter and the signal obtained by dividing the frequency converted signal by the frequency divider and the signal obtained by dividing the first output signal by the frequency divider. third frequency synthesizer, the output of the third frequency signal of fourth received for outputting an output signal of said 3 to control the frequency of the output signal of said third synchronized with said first output signal A third frequency converter that converts and outputs a fifth frequency signal according to the frequency of the signal; and converts and outputs the fifth frequency signal to a sixth frequency signal according to the frequency of the first output signal. And a fourth frequency converter.

  Also in the case of this receiving unit, as in the case of the transmitting unit, a local oscillator for the third frequency converter (corresponding to the local oscillator 10 in the conventional example shown in FIG. 8) becomes unnecessary.

  Accordingly, one local oscillator is not required for each of the transmitter and the receiver.

  It is also possible to further comprise means for dividing or multiplying the frequency of the third output signal and supplying it to the third frequency converter.

  Furthermore, it is possible to further comprise means for dividing, multiplying, or frequency-converting the frequency of the first output signal and supplying it to the first frequency converter and the fourth frequency converter.

  ADVANTAGE OF THE INVENTION According to this invention, in the communication apparatus which performs several frequency conversion, the number of the local oscillators which supply the frequency signal for frequency conversion can be reduced, and cost, mounting area, power consumption, etc. are reduced significantly. be able to. Furthermore, generation of unnecessary wave components due to complicated mixing or interference can be reduced by diversifying frequency components.

Embodiments of the present invention will be described below with reference to the drawings. However, these examples do not limit the technical scope of the present invention.
Example of transmitter (1)
FIG. 1 shows an embodiment (1) of a transmitter, in particular, as a communication apparatus according to the present invention. The same elements as those in FIGS. 7 and 9 are given the same reference numerals. In this embodiment, when performing frequency conversion of the double conversion method, different frequency signals are supplied to the frequency converter 1 and the frequency converter 2 by one local oscillator 5.

  That is, the local oscillator 5 is a multi-loop frequency synthesizer, and a frequency synthesizer 51 that outputs a first frequency signal F4 synchronized with a reference signal and the first frequency signal F4 are input, and the first frequency signal And a second frequency synthesizer 52 that outputs a second frequency signal F5 synchronized with F4. Then, the first frequency signal F4 is input to the first-stage frequency converter 1, and the second frequency signal F5 is input to the second-stage frequency converter 2.

  Conventionally, a local oscillator consisting of a single-stage frequency synthesizer has been prepared separately for the first-stage frequency converter 1, and a local oscillator consisting of a multi-loop synthesizer has been prepared separately for the second-stage frequency converter 2. In the embodiment of the invention, the output signal from the first-stage frequency synthesizer of the multi-loop synthesizer is supplied to the first-stage frequency converter 1. As a result, the local oscillator of the first stage can be configured to be included in the local oscillator of the second stage, and two local oscillators are utilized by utilizing the combination of frequencies used in the multi-loop frequency synthesizer. The structure which loads both is adopted.

  Specifically, as the frequency signal to be supplied to the frequency converter 1, the first frequency signal F4 that is the output of the first-stage frequency synthesizer 51 in the local oscillator 5 is used as the frequency signal to be supplied to the frequency converter 1. The second frequency signal F5 from the second-stage frequency synthesizer 52 is used.

  In this way, by extracting the output signal of the frequency synthesizer at each stage from the local oscillator 5 configured by a multiple loop synthesizer and supplying each to the frequency converters 1 and 2, by one local oscillator, The necessary frequency signals can be supplied to the plurality of frequency converters. As a result, the number of components of the local oscillator can be reduced, and cost, mounting area, and power consumption can be reduced.

  Here, the operation of the local oscillator 5 will be described again. In the frequency synthesizer 51, the reference signal output from the reference signal generator 10 is frequency-divided by the frequency divider 11 and then input to the phase comparator 12. The phase comparator 12 performs a phase comparison between the reference signal and a signal obtained by dividing the output signal (first frequency signal F4) of the voltage controlled oscillator 14 by the frequency divider 15. The phase comparator 12 outputs a phase difference signal between the output signal from the frequency divider 15 and the reference signal from the frequency divider 11. The loop filter 13 composed of a low-pass filter or the like integrates the phase difference signal. The voltage controlled oscillator 14 outputs a frequency signal F4 corresponding to the output voltage from the loop filter 13. As a result, the frequency synthesizer 51 outputs a frequency signal F4 that is phase-synchronized with the reference signal. The frequency of the frequency signal F4 is several hundred MHz, for example.

  The frequency signal F4 from the frequency synthesizer 51 is frequency-divided by the frequency divider 27 as a reference signal of the frequency synthesizer 52 and input to the phase comparator 23 of the frequency synthesizer 52. The phase comparator 23 divides this signal and the output signal (second frequency signal F5) of the voltage controlled oscillator 25 by the frequency divider 26, further frequency-converts it by the frequency converter 21, and further frequency-divides 22 The phase comparison with the signal divided by is performed. The phase comparator 23 outputs a phase difference signal between the output signal from the frequency divider 22 and the reference signal from the frequency divider 27. Then, the loop filter 24 integrates the phase difference signal. The voltage controlled oscillator 25 outputs a frequency signal F5 corresponding to the output voltage from the loop filter 24. Thus, the frequency synthesizer 52 outputs the frequency signal F5 that is phase-synchronized with the frequency signal F4, that is, phase-synchronized with the reference signal. The frequency of the frequency signal F5 is, for example, several GHz, which is higher than that of the frequency signal F4.

  Then, the frequency signal F4 from the first-stage frequency synthesizer 51 is input to the first-stage frequency converter 1, and the frequency converter 1 converts the intermediate frequency signal F1 into the intermediate frequency signal F2 based on the frequency signal F4. . The frequency signal F5 from the second-stage frequency synthesizer 52 is input to the second-stage frequency converter 2, and the frequency converter 2 converts the intermediate frequency signal F2 into the transmission frequency signal F3 based on the frequency signal F5. Convert.

  In this case, as shown in the figure, the frequency signal F5 may be N times or 1 / N times (N is a natural number) by the multiplier or frequency divider 40 and input to the frequency converter 2. Thereby, a desired transmission frequency F3 can be obtained.

  The reason why the frequency signal F4 of the first-stage frequency synthesizer 51 is input to the first-stage frequency converter 1 and the frequency signal F5 of the second-stage frequency synthesizer 52 is input to the second-stage frequency converter 2 is as follows. by.

That is, the frequency signal F4 has a frequency of about several hundred MHz, for example, and the frequency signal F5 has a higher frequency, for example, a frequency of about several GHz. Therefore, when the frequency signal F5 is input to the first-stage frequency converter 1, the intermediate frequency signal F2 output from the frequency converter 1 has a high frequency of several GHz band. In general, the higher the frequency, the more complicated and expensive the signal processing circuit. Therefore, in order to transmit the intermediate frequency signal F2 transmitted between the frequency converter 1 and the frequency converter 2 at as low a cost as possible without deterioration, the frequency converter 1 uses a frequency signal F5 instead of frequency conversion. However, it is preferable to perform frequency conversion with a frequency signal F4 having a lower frequency than that.
Example of transmitter (2)
FIG. 2 shows an embodiment (2) of the transmission unit in the communication apparatus according to the present invention. This embodiment has substantially the same configuration as that of the embodiment (1) shown in FIG. 1 except that the frequency signal F4 from the frequency synthesizer 51 is multiplied by N times by a multiplier or a frequency divider 41. In this configuration, the frequency converter 1 is multiplied by 1 / N (N is a natural number). Thereby, a desired intermediate frequency F2 can be obtained. Therefore, frequency options can be further increased from the embodiment (1) of FIG.
Example of transmitter (3)
FIG. 3 shows an embodiment (3) of the transmission unit in the communication apparatus according to the present invention. This embodiment has substantially the same configuration as the embodiment (1) shown in FIG. 1 except that the frequency signal F4 from the frequency synthesizer 51 is frequency-converted by the frequency converter 42, This is a configuration given to the converter 1. Thereby, a desired intermediate frequency F2 can be obtained. For the frequency conversion in the frequency converter 42, the reference signal from the reference signal generator 10 is used. By synthesizing the frequency signal F4 and the reference signal by the frequency converter 42, a new frequency can be generated, and frequency options can be increased.

  In each of the above-described embodiments, the double conversion method in which frequency conversion is performed twice has been described as an example, but the present invention can also be applied to a method in which frequency conversion is performed three times or more. For example, when performing frequency conversion three times, it is configured to supply two frequency signals from a double loop synthesizer consisting of two frequency synthesizers to any two of the three frequency converters. Also good.

  Further, in each of the above-described embodiments, an example in which two frequency signals from a double loop synthesizer configured by two frequency synthesizers is supplied to the frequency converter has been described. However, a multiplexing with three or more frequency synthesizers connected is provided. A loop synthesizer may be used. For example, three frequency signals from a triple loop synthesizer to which three frequency synthesizers are connected may be supplied to three frequency converters, respectively (when performing frequency conversion three times).

Further, in each of the above-described embodiments, the transmission communication apparatus has been described. However, the transmission communication apparatus can be used in the same manner. This will be described below.
Example of transceiver (1)
FIG. 4 shows an embodiment (1) of the transmission / reception unit (transmission unit and reception unit) in the communication apparatus according to the present invention. The same elements as those in FIG. 1 are denoted by the same reference numerals. In this embodiment (1), a local oscillator 50 having a configuration including the local oscillators 4, 5, 9, and 10 in the conventional example shown in FIG. 8 for supplying frequency signals to the frequency converters 1, 2, 6, and 7 is provided. Used.

  That is, the local oscillator 50 receives a frequency synthesizer 51 that outputs a first frequency signal F4 (= F10) synchronized with a reference signal, and the first frequency signal F4 (= F10). A second frequency synthesizer 52 that outputs a second frequency signal F5 synchronized with the signal F4 (= F10), and a third frequency signal F9 that synchronizes with the first frequency signal F4 (= F10). Frequency synthesizer 53. Then, the first frequency signal F4 (= F10) is input to the frequency converters 1 and 7, the second frequency signal F5 is input to the frequency converter 2, and the third frequency signal F9 is input to the frequency converter 6. Connected to be input.

  Conventionally, as shown in FIG. 8, the frequency converters 1 and 7 are separately provided with local oscillators consisting of a single-stage frequency synthesizer, and the frequency converters 2 and 6 are separately provided with local oscillators consisting of multiple loop synthesizers. However, in this embodiment, the output signal from the first-stage frequency synthesizer 51 of the multi-loop synthesizer is supplied to the frequency converters 1 and 7.

  As a result, the local oscillator of the first stage can be configured to be included in the local oscillator of the second stage, and two local oscillators are utilized by utilizing the combination of frequencies used in the multi-loop frequency synthesizer. It consists of a structure that loads both. Further, the first-stage frequency synthesizer 51, which requires two systems for transmission and reception, is shared.

  Specifically, the first frequency signal F4 (= F10) that is the output of the first-stage frequency synthesizer 51 in the local oscillator 50 is used as the frequency signal supplied to the frequency converters 1 and 7, and the frequency converter 2 , 6 use the second and third frequency signals F5, F9 from the second and third stage frequency synthesizers 52, 53, respectively.

  In this way, by taking the output signal of the frequency synthesizer at each stage from the local oscillator 50 constituted by a multiple loop synthesizer and supplying each of the output signals to the frequency converters 1, 2, 6, 7, one The local oscillator makes it possible to supply a frequency signal necessary for a plurality of frequency converters. As a result, the number of frequency synthesizers can be reduced, and cost, mounting area, and power consumption can be reduced.

  Here, the operation of the local oscillator 50 will be described. In the frequency synthesizer 51, the reference signal output from the reference signal generator 10 is frequency-divided by the frequency divider 11 and then input to the phase comparator 12. The phase comparator 12 performs a phase comparison between the reference signal from the frequency divider 11 and a signal obtained by dividing the output signal of the voltage control oscillator 14 (first frequency signal F4 = F10) by the frequency divider 15, The phase difference signal is output. The loop filter 13 composed of a low-pass filter or the like integrates the phase difference signal. The voltage controlled oscillator 14 outputs a frequency signal F4 (= F10) corresponding to the output voltage from the loop filter 13. Thereby, the frequency synthesizer 51 outputs a frequency signal F4 (= F10) that is phase-synchronized with the reference signal. The frequency of the frequency signal F4 (= F10) is, for example, several hundred MHz.

  The frequency signal F4 (= F10) from the frequency synthesizer 51 is frequency-divided by the frequency divider 27 as a reference signal of the frequency synthesizer 52 and input to the phase comparator 23 of the frequency synthesizer 52. The phase comparator 23 divides the signal from the frequency divider 27 and the output signal (second frequency signal F5) of the voltage controlled oscillator 25 by the frequency divider 26, converts the frequency by the frequency converter 21, The phase comparison with the signal divided by the frequency divider 22 is performed and the phase difference signal is output. Then, the loop filter 24 integrates the phase difference signal. The voltage controlled oscillator 25 outputs a frequency signal F5 corresponding to the output voltage from the loop filter 24.

  The frequency signal F4 (= F10) from the frequency synthesizer 51 is frequency-divided by the frequency divider 37 as a reference signal of the frequency synthesizer 53, and is input to the phase comparator 33 of the frequency synthesizer 53. The phase comparator 33 divides the signal from the frequency divider 37 and the output signal (third frequency signal F9) of the voltage controlled oscillator 35 by the frequency divider 36, converts the frequency by the frequency converter 31, The phase of the signal divided by the frequency divider 32 is compared and the phase difference signal is output. Then, the loop filter 34 integrates the phase difference signal. The voltage controlled oscillator 35 outputs a frequency signal F9 corresponding to the output voltage from the loop filter 34.

  Thus, the frequency synthesizers 52 and 53 output frequency signals F5 and F9 that are phase-synchronized with the frequency signal F4 (= F10), that is, phase-synchronized with the reference signal. The frequency of the frequency signals F5 and F9 is, for example, several GHz, which is higher than that of the frequency signal F4 (= F10).

  In the transmission unit 100, the frequency signal F4 (= F10) from the first-stage frequency synthesizer 51 is input to the first-stage frequency converter 1, and based on this, the frequency converter 1 intermediates the intermediate frequency signal F1. Convert to frequency signal F2. Further, the frequency signal F5 from the second-stage frequency synthesizer 52 is input to the second-stage frequency converter 2, and based on this, the frequency converter 2 converts the intermediate frequency signal F2 into the transmission frequency signal F3.

  In the receiving unit 200, the frequency signal F9 from the third-stage frequency synthesizer 53 is input to the first-stage frequency converter 6, and based on this, the frequency converter 6 converts the received frequency signal F6 into the intermediate frequency signal F7. To do. Further, the frequency signal F4 (= F10) from the first-stage frequency synthesizer 51 is input to the second-stage frequency converter 7, and based on this, the frequency converter 7 converts the intermediate frequency signal F7 into the intermediate frequency signal F8. Convert.

  Further, as shown in the figure, the frequency signals F5 and F9 are multiplied by N or 1 / N times (N is a natural number) by the multipliers or dividers 40 and 41, respectively, and are given to the frequency converters 2 and 6, respectively. You may do it. Thereby, a desired transmission frequency F3 and intermediate frequency F7 can be obtained.

  Here, the frequency signal F4 (= F10) of the first-stage frequency synthesizer 51 is input to the frequency converters 1 and 7, and the frequency signals F5 and F9 of the second-stage and third-stage frequency synthesizers 52 and 53 are frequency-converted. The reason why the data is input to the devices 2 and 6 is as follows.

That is, the frequency signal F4 (= F10) has a frequency of about several hundred MHz, for example, and the frequency signals F5 and F9 have a higher frequency, for example, a frequency of about several GHz. Therefore, if the frequency signals F5 and F9 are input to the frequency converters 1 and 7, the intermediate frequency signals F2 and F7 have a high frequency of several GHz band. As described above, generally, the higher the frequency, the more complicated and expensive the signal processing circuit. Therefore, in order to transmit the intermediate frequency signals F2 and F7 transmitted between the frequency converters 1 and 2 and between the frequency converters 6 and 7 without degrading at the lowest possible cost, the frequency converters 1 and 7 It is preferable to perform frequency conversion with a frequency signal F4 having a lower frequency than frequency conversion with the frequency signals F5 and F9.
Example of transceiver (2)
FIG. 5 shows an embodiment (2) of the transmission / reception unit in the communication apparatus according to the present invention. This embodiment (2) has almost the same configuration as the embodiment (1) shown in FIG. 4, except that the frequency signal F4 (= F10) from the frequency synthesizer 51 is a multiplier or a divider. In this configuration, the signal is multiplied by N or 1 / N (N is a natural number) by the frequency multiplier 41 and input to the frequency converters 1 and 7. Thereby, desired intermediate frequencies F2 and F7 can be obtained. Therefore, it is possible to further increase the frequency options compared to the embodiment (1) shown in FIG.
Example of transceiver (3)
FIG. 6 shows an embodiment (3) of the transmission / reception unit in the communication apparatus according to the present invention. This embodiment (3) has substantially the same configuration as that of the embodiment (1) shown in FIG. 4 except that the frequency signal F4 (= F10) from the frequency synthesizer 51 is changed to the frequency converter 42. Thus, the frequency is converted and input to the frequency converters 1 and 7. Thereby, desired intermediate frequencies F2 and F7 can be obtained. For the frequency conversion in the frequency converter 42, the reference signal from the reference signal generator 10 is used. By synthesizing the frequency signal F4 (= F10) and the reference signal by the frequency converter 42, a new frequency can be generated, and frequency options can be increased.

  In each of the above-described embodiments, the double conversion method in which frequency conversion is performed twice has been described as an example, but the present invention can also be applied to a method in which frequency conversion is performed three times or more. For example, when frequency conversion is performed three times, it is composed of six frequency synthesizers, but four frequency signals from a double loop synthesizer with a common first stage are converted to any four of the six frequency converters. You may comprise so that it may supply.

  In each of the above-described embodiments, an example in which four frequency signals from a double loop synthesizer sharing the first-stage frequency synthesizer is supplied to the frequency converter has been described. However, three or more frequency synthesizers are connected. Multiple loop synthesizers may be used. For example, six frequency signals from a triple loop synthesizer sharing the first stage may be supplied to three frequency converters, respectively (when performing frequency conversion three times).

(Appendix 1)
A first output signal synchronized with the reference signal is output by controlling a frequency of the first output signal according to a phase difference between the reference signal and the first output signal fed back by the feedback loop. A frequency synthesizer,
The second output signal is synchronized with the first output signal by controlling the frequency of the second output signal according to the phase difference between the first output signal and the second output signal fed back by the feedback loop. A second frequency synthesizer that outputs an output signal;
A first frequency converter that converts the input first frequency signal into a second frequency signal according to the frequency of the first output signal and outputs the second frequency signal;
A second frequency converter that converts the second frequency signal into a third frequency signal according to the frequency of the second output signal and transmits the third frequency signal;
A communication apparatus comprising:
(Appendix 2) In Appendix 1,
A communication apparatus further comprising means for dividing or multiplying the second output signal and supplying the second output signal to the second frequency converter.
(Appendix 3) In Appendix 1,
A communication device further comprising means for dividing, multiplying or frequency-converting the frequency of the first output signal and supplying the frequency to the first frequency converter.
(Appendix 4) In Appendix 1, the first output signal is controlled by controlling the frequency of the third output signal in accordance with the phase difference between the first output signal and the third output signal fed back by the feedback loop. A third frequency synthesizer that outputs the third output signal in synchronization with
A third frequency converter that converts the received fourth frequency signal into a fifth frequency signal according to the frequency of the third output signal and outputs the fifth frequency signal;
A fourth frequency converter that converts the fifth frequency signal into a sixth frequency signal according to the frequency of the first output signal and outputs the sixth frequency signal;
A communication apparatus, further comprising:
(Supplementary note 5) The communication apparatus according to supplementary note 4, further comprising means for dividing or multiplying the frequency of the third output signal and supplying the frequency to the third frequency converter.
(Supplementary Note 6) In the supplementary note 4 or 5, further comprising means for dividing, multiplying, or frequency-converting the frequency of the first output signal and supplying the frequency to the first frequency converter and the fourth frequency converter A communication device characterized by the above.

FIG. 5 is a block diagram showing an embodiment (1) of a transmission unit in the communication device according to the present invention. FIG. 6 is a block diagram showing an embodiment (2) of a transmission unit in the communication device according to the present invention. FIG. 5 is a block diagram showing an embodiment (3) of a transmission unit in the communication device according to the present invention. It is the block diagram which showed the Example (1) of the transmission / reception part in the communication apparatus which concerns on this invention. It is the block diagram which showed the Example (2) of the transmission / reception part in the communication apparatus which concerns on this invention. It is the block diagram which showed the Example (3) of the transmission / reception part in the communication apparatus which concerns on this invention. It is the block diagram which showed the conventional communication apparatus (transmission part) using a double conversion system. It is the block diagram which showed the conventional communication apparatus (transmission / reception part) using the double conversion system. It is the block diagram which showed the conventional example of the local oscillator.

Explanation of symbols

1: frequency converter, 2: frequency converter, 4: local oscillator, 5: local oscillator,
6: Frequency converter, 7: Frequency converter, 9: Local oscillator,
10: Reference signal generator, local oscillator (double use),
11: Divider, 12: Phase comparator, 13: Loop filter, 14: Voltage controlled oscillator, 15: Divider, 21: Frequency converter, 22: Divider, 23: Phase comparator, 24: Loop Filter, 25: Voltage controlled oscillator, 26: Divider, 27: Divider, 31: Frequency converter, 32: Divider, 33: Phase comparator, 34: Loop filter, 35: Voltage controlled oscillator, 36 : Divider, 37: divider, 40: multiplier / divider, 41: multiplier / divider, 42: frequency converter, 43: multiplier / divider, 50: local oscillator, 51 : Frequency synthesizer, 52: Frequency synthesizer, 53: Frequency synthesizer In the figure, the same reference numerals indicate the same or corresponding parts.

Claims (5)

A first output signal synchronized with the reference signal is output by controlling a frequency of the first output signal according to a phase difference between the reference signal and the first output signal fed back by the feedback loop. A frequency synthesizer,
A frequency converted signal by a frequency converter between the first output signal and a signal obtained by dividing the second output signal fed back by a feedback loop by a frequency divider, and a signal obtained by dividing the frequency converted signal by the frequency divider and controlling the frequency of the second output signal in response to the phase difference signal by the phase comparator with the divided signal by the frequency divider to said first output signal said in synchronization with the first output signal A second frequency synthesizer that outputs two output signals;
A first frequency converter that converts the input first frequency signal into a second frequency signal according to the frequency of the first output signal and outputs the second frequency signal;
A second frequency converter that converts the second frequency signal into a third frequency signal according to the frequency of the second output signal and transmits the third frequency signal;
A communication apparatus comprising: In claim 1,
A communication device further comprising means for dividing or multiplying the second output signal and supplying the second output signal to the second frequency converter. In claim 1,
A communication apparatus, further comprising means for dividing, multiplying or frequency-converting the frequency of the first output signal and supplying the frequency to the first frequency converter. In Claim 1, The frequency conversion signal by a frequency converter of this 1st output signal and the signal which frequency-divided the 3rd output signal fed back by the feedback loop by a frequency divider, and this frequency conversion signal by a frequency divider divided signal and said first output signal to control the frequency of the output signal of the third according to the phase difference signal by the phase comparator divided signal and by the first output signal divider and A third frequency synthesizer that outputs the synchronized third output signal;
A third frequency converter that converts the received fourth frequency signal into a fifth frequency signal according to the frequency of the third output signal, and outputs the fifth frequency signal;
A fourth frequency converter that converts the fifth frequency signal into a sixth frequency signal according to the frequency of the first output signal and outputs the sixth frequency signal;
A communication apparatus, further comprising: 5. The communication apparatus according to claim 4, further comprising means for dividing or multiplying the frequency of the third output signal and supplying the frequency to the third frequency converter.

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