JPH0955692A - Frequency diversity radio communication method, frequency diversity radio transmitter and frequency diversity ratio receiver, and frequency diversity radio communication equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To conduct frequency diversity radio communication economically with a high frequency utilizing efficiency. SOLUTION: A data modulation section 2 at a transmitter side modulates a main transmission carrier f. from a carrier oscillator 3 and its harmonics f2 (=2f1 ) by an external modulation signal and the modulated signal is sent from a transmission antenna 7 via a frequency conversion section 4 and a high frequency section 6. Any modulated wave with stronger reception power among received modulation waves is selected properly at the receiver side and demodulated to increase the frequency utility efficiency and the original transmission data are reproduced economically.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to mobile radio communication mainly used for car phones, mobile phones, etc., and particularly to a frequency diversity radio communication method with high frequency utilization efficiency and capable of economical radio communication. Furthermore, the present invention relates to a frequency diversity wireless transmission device and a frequency diversity wireless reception device which are required for the implementation of the wireless communication method, and further to a transmission frequency diversity wireless communication device provided with a frequency diversity wireless transmission / reception function. Is.

[0002]

2. Description of the Related Art FIG. 4 and FIG. 5 show block configuration concepts of an example of each of a frequency diversity radio transmitting apparatus and a frequency diversity radio receiving apparatus which are currently in practical use. In this case, as shown in FIG. 4, on the transmission device side, the transmission data from the outside is converted into a required format by the data interface unit 1 and is simultaneously input to each of the transmitters 21 and 22 as a modulation signal. It has become a thing. In the transmitter 21, the main transmission carrier wave is modulated by the signal, and at the same time, in the transmitter 22, the transmission carrier wave (the frequency of this transmission carrier wave is separated by a certain frequency from that of the main transmission carrier wave) by the signal. ing)
Is to be modulated. Then transmitter 2
From each of 1 and 22, two kinds of modulated waves modulated by the same transmission data are simultaneously obtained. These modulated waves are
After that, after being combined as a transmission signal by the transmission signal combiner 23, it is wirelessly transmitted in the air from the transmission antenna 7.

On the other hand, as shown in FIG. 5, on the receiving device side, the transmission signal from the transmitting device side is received by the receiving antenna 8
The first two types of modulated waves are regenerated from the reception RF sections 24 and 25, respectively, and the signal levels of these modulated waves are detected by the level detectors 26 and 27, respectively. It has become one. Generally, it is undeniable that these signal levels may change from moment to moment due to fading or the like. Therefore, in the case where a modulated wave having a high signal level is appropriately selected by the reception wave switch 17 among these signal levels and then demodulated by the data demodulation unit 18, the original modulated signal is reproduced, It is possible to perform wireless communication in a state in which a momentary interruption in communication due to fading or the like is reduced. In addition, as a technology related to frequency diversity,
For example, "Digital Radio Communication" (Sangyo Tosho Co., Ltd., issued May 25, 1989, pages 150-152) can be mentioned.

[0004]

However, as can be seen from the above, the frequency diversity technique generally requires two or more wave transmission paths for transmitting one data, and therefore, a radio wave of UHF band or less is required. In the communication device, the transmission bandwidth is limited, so that deterioration of frequency utilization efficiency cannot be denied. Therefore, in general, as a countermeasure against fading, instead of the frequency diversity technique having poor frequency efficiency, a single transmitter that has good frequency utilization efficiency and uses two signal components with different propagation paths is used. -Currently, the diversity technology is the mainstream. However, in the case of using the space diversity technique, new problems also occur. This is because not only two antennas are required to receive two signals having different propagation paths, but also the antennas need to be installed with a sufficient space therebetween. In this regard, since the antenna installation interval can be sufficiently secured in the automobile wireless communication device and the like, even if the space diversity effect can be expected sufficiently, the antenna installation interval is secured in the small mobile terminal and the like. It is generally difficult to do so, and a sufficient space diversity effect cannot be exerted.

It is a first object of the present invention to provide a frequency diversity radio communication method which enables radio communication with high frequency utilization efficiency and economically. A second object of the present invention is to provide a frequency diversity wireless transmission device which is required for implementing the wireless communication method. A third object of the present invention is to provide a frequency diversity radio receiver which is also required for implementing the radio communication method. A fourth object of the present invention is to provide a frequency diversity wireless communication device equipped with a wireless transmission / reception function which is also required for implementing the wireless communication method.

[0006]

On the transmitting side, the main transmission carrier component and the harmonic components generated accompanying the main transmission carrier component are used as carriers, and each of the carriers is After being simultaneously modulated by the same modulation signal, it is wirelessly transmitted by radio waves as a transmission signal in the state where the frequency is converted by the single local oscillation frequency, while at the receiving side, the received transmission signal is frequency converted. By the above, the modulated wave corresponding to the main transmission carrier component and the harmonic component is regenerated, and the level detection is performed in the separated and extracted state. With the level being obtained, of the signal levels, a modulated wave with a high signal level is appropriately selected and demodulated, or a single wave is transmitted at the transmission side. After the transmission wave is modulated by the modulation signal, it is wirelessly transmitted by radio waves as a transmission signal in the state where the frequency is converted by the local oscillation frequency including the harmonic component, while the reception signal is frequency converted on the receiving side. By doing so, the two types of modulated waves are reproduced, and the level detection is performed in the state of being separated and extracted, so that the signal level of the modulated waves is obtained corresponding to the two types of modulated waves. This is achieved by appropriately selecting and demodulating a modulated wave having a high signal level among the signal levels.

A second object of the present invention is to provide a carrier oscillator for generating a main transmission carrier component with a harmonic component attached,
A modulator that modulates each of the main transmission carrier components and harmonic components from the carrier oscillator with the same modulation signal, a local oscillator that oscillates a single local frequency, and a single oscillator from the local oscillator. A frequency converter for frequency-converting the modulated wave from the modulator with one local frequency, or
Alternatively, a carrier wave oscillator that generates a single carrier wave, a modulator that modulates a carrier wave from the carrier wave oscillator with a modulation signal, a local oscillator that oscillates a local oscillation frequency including a harmonic component, and a harmonic wave from the local oscillator. It is achieved by including at least a frequency converter that frequency-converts the modulated wave from the modulator with a local frequency including a wave component.

The third object is to provide a local oscillator that oscillates a single local frequency, and frequency-convert the received transmission signal based on the single local frequency from the local oscillator to obtain the original main transmission carrier wave. Frequency converter for reproducing a modulated wave corresponding to a component and a harmonic component, a filter for separating and extracting the modulated wave from the frequency converter corresponding to the original main transmission carrier component and a harmonic component, and a main filter from each of the filters. A level detector that level-detects a modulated wave corresponding to a transmission carrier component and a harmonic component; a reception wave switch that appropriately selects a modulated wave having a high signal level from the signal levels from each of the level detectors; This is achieved by including at least a demodulator that demodulates the modulated wave that is selectively output from the received wave switch.

A fourth object of the present invention is to provide a carrier oscillator for generating a main transmission carrier component with a harmonic component attached,
A modulator that modulates each of the main transmission carrier components and harmonic components from the carrier oscillator with the same modulation signal, a local oscillator that oscillates a single local frequency, and a single oscillator from the local oscillator. A radio transmission function including at least a frequency converter that frequency-converts the modulated wave from the modulator with one local frequency,
A local oscillator that oscillates a single local frequency, and based on the single local frequency from the local oscillator, by frequency-converting the received transmission signal, the original main transmission carrier component, the modulated wave corresponding to the harmonic component is generated. A frequency converter for reproduction, a filter for separating and extracting the modulated wave from the frequency converter corresponding to the original main transmission carrier component and harmonic component, and a modulation corresponding to the main transmission carrier component and harmonic component from each of the filters. Level detector for detecting the level of a wave, a reception wave switch for appropriately selecting a modulated wave having a high signal level from the signal levels from each of the level detectors, and a modulation selectively output from the reception wave switch Or a radio receiving function including at least a demodulator for demodulating a wave, or a carrier wave oscillator for generating a single carrier wave, and a carrier wave from the carrier wave oscillator by a modulation signal. A modulator for modulating, a local oscillator for oscillating a local oscillation frequency including a harmonic component, and a frequency converter for frequency-converting the modulated wave from the modulator by the local frequency including the harmonic component from the local oscillator. And a local oscillator that oscillates a single local frequency, and frequency-converts the received transmission signal based on the single local frequency from the local oscillator to reproduce two types of modulated waves. Frequency converter, a filter that separates and extracts two types of modulated waves from the frequency converter, a level detector that level-detects the modulated wave from each of the filters, and a signal level from each of the level detectors Out of the above, a received wave switch that appropriately selects a modulated wave with a high signal level, and a demodulator that demodulates the modulated wave that is selectively output from the received wave switch. The vessel is achieved by configuring the at least includes radio receiving function.

[0010]

From the transmitting side, the main transmission carrier component and the harmonic components generated in association with the main transmission carrier component are used as carriers, and these carriers are simultaneously modulated by the same modulation signal, and then a single signal is generated. The signal is wirelessly transmitted as a transmission signal that is frequency-converted by the local oscillation frequency, or as a transmission signal that is frequency-converted by the local oscillation frequency that contains harmonic components after a single carrier wave is modulated by the modulation signal. In this case, the wireless communication can be economically performed by simplifying the configuration on the transmission function and by using the frequency diversity effect.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to FIGS. First, the frequency diversity wireless transmission apparatus according to the present invention will be described. FIG. 1 shows a block configuration as an example. In this case, the data transmitted from the outside is converted into a required format in the data interface unit 1, and then, as the modulation signal, in the data modulation unit 2, the main transmission carrier f ₁ from the diversity carrier oscillator 3 and its The harmonic f ₂ (= 2f ₁ ) is modulated. A main modulated wave and a higher-order modulated wave are generated by this modulation, and these modulated waves are multiplied by the single local frequency f _LO from the local oscillator 5 in the frequency conversion section 4 and then the high frequency section. 6 required transmission frequency f _LO + f ₁ , f
_{As LO} + f ₂ and the state converted to the transmission level,
It is transmitted from the transmitting antenna 7.

On the radio wave propagation path, the transmission signal from the frequency diversity radio transmitting apparatus is attenuated by the effect of fading, but the attenuation characteristic changes depending on the transmission frequency and the distance. In other words, the main modulated wave and the higher-order modulated wave, which are transmission signals from the frequency diversity radio transmitter, have different center frequencies, so that the effects of fading are also different. . Therefore, in the frequency diversity radio receiving device, when the main modulation wave and the high-order modulation wave from the frequency diversity radio transmission device are received, after the signal levels of these modulation waves are detected and compared,
It suffices that a modulated wave having a high signal level is appropriately selected.

That is, FIG. 2 shows a block configuration of an example of the frequency diversity radio receiving apparatus according to the present invention. In this case, in the frequency diversity radio receiving apparatus, the main antenna received by the receiving antenna 8 is received. Modulation wave (f
_{The LO} + f ₁ ) and the higher-order modulated wave (fL _O + f ₂ ) are passed through the reception high frequency section 9 and the reception filter section 10, and then the local oscillator 12
The frequency conversion unit 11 performs frequency conversion up to the intermediate frequency band or the base band band by the local frequency from _{1 to} , so that the modulated wave corresponding to the main transmission carrier wave f ₁ and the harmonic wave f ₂ is reproduced. . These modulated waves are then separated and extracted from each other by the main transmission carrier filter 13 and the diversity filter 14, respectively, and are then respectively extracted by the main transmission carrier level detector 15 and the diversity level detector 16. The received power has been detected. Therefore, in the case where one of the modulated waves with strong received power is appropriately selected and output from the received wave switch 17 and the transmission data is reproduced by the data demodulator 18, The transmission data can be reproduced with the influence of the level fluctuation due to fading removed or reduced.

FIG. 3 is a block diagram showing another example of the frequency diversity radio transmitter according to the present invention. As shown, the substantial difference from that shown in FIG. 1 is that the harmonic components are generated by the local oscillator 20. That is, the single carrier wave f _LO1 from the carrier wave oscillator 19 is modulated by the transmission data from the data interface section 1 in the data modulating section 2 and the harmonic component f _C2 from the local oscillator 20 in the frequency converting section 4. The frequency is converted by the included local frequency f _C1 . As a result, as in the case of FIG. 1, a main modulated wave and a higher-order modulated wave are generated.
The signal is transmitted from the transmitting antenna 7 in a state in which it is converted to the required transmission frequency and its transmission level via.

Therefore, in the frequency diversity radio receiving apparatus, it suffices that the modulated waves are received and processed as in the case of FIG.

In the radio transmitter according to the prior art, the harmonic component from the local oscillator 20 had to be removed as an unnecessary component, but due to the widening of the transmission signal band accompanying the high frequency region of the transmission frequency, If the unnecessary harmonic component is positively used as a signal for frequency diversity, the circuit configuration on the wireless transmitter can be simplified. The present invention is as described above. However, when frequency diversity wireless communication is performed bidirectionally, both devices may be provided with a wireless transmission / reception function.

[0017]

As described above, according to the first and fifth aspects, the frequency diversity radio communication method which can perform radio communication economically with high frequency utilization efficiency is also provided. According to claim 3, the frequency diversity wireless transmission device required for the implementation of the wireless communication method further has the frequency diversity wireless reception required for the implementation of the wireless communication method. Further, in the case of the apparatus according to claims 4 and 7, the frequency diversity wireless communication apparatus including the wireless transmission / reception function required for implementing the wireless communication method is obtained. .

[Brief description of drawings]

FIG. 1 is a diagram showing a block configuration of an example of a frequency diversity wireless transmission device according to the present invention.

FIG. 2 is a diagram showing a block configuration of an example of a frequency diversity radio receiving apparatus according to the present invention.

FIG. 3 is a diagram showing a block configuration of another example of the frequency diversity wireless transmission device according to the present invention.

FIG. 4 is a diagram showing a block configuration concept in an example of a frequency diversity wireless transmission device according to a conventional technique.

FIG. 5 is a diagram showing a block configuration concept in an example of a frequency diversity radio receiving apparatus according to the related art.

[Explanation of symbols]

1 ... Data interface section, 2 ... Data demodulation section, 3
... Diversity carrier oscillator, 4 ... Frequency converter, 5
... local oscillator, 6 ... high frequency part, 7 ... transmission antenna,
8 ... Receiving antenna, 9 ... Receiving high frequency part, 10 ... Receiving filter part, 11 ... Frequency converting part, 12 ... Local oscillator, 13
... Main transmission carrier filter, 14 ... Diversity filter, 15 ... Main transmission carrier level detector, 16 ... Diversity level detector, 17 ... Reception wave switching device, 18 ...
Data demodulator, 19 ... Carrier oscillator, 20 ... Local oscillator

Claims (7)

[Claims] 1. A frequency diversity wireless communication method when radio communication is performed by radio waves, wherein any one of the transmission frequencies of two or more waves is appropriately selected as a reception frequency, and the frequency diversity radio communication method is used. A state in which a transmission carrier component and a harmonic component generated along with the main transmission carrier component are used as carriers, and the carriers are simultaneously modulated by the same modulation signal and then frequency-converted by a single local oscillation frequency. On the receiving side, the received transmission signal is frequency-converted to reproduce the modulated waves corresponding to the main transmission carrier component and the harmonic component, and then separate them. The signal level of the modulated wave corresponding to the original main transmission carrier component and harmonic components is obtained by level detection in the extracted state In the frequency diversity wireless communication method, a modulated wave having a higher signal level is appropriately selected from the signal levels and demodulated. 2. A frequency diversity wireless transmission apparatus as a transmission side apparatus when frequency diversity wireless communication by radio waves is performed while any one is appropriately selected as a reception frequency from transmission frequencies of two or more waves. A carrier oscillator that generates a main transmission carrier component with a harmonic component attached, and the main transmission carrier component and the harmonic component from the carrier oscillator are used as carriers, and each carrier is modulated by the same modulation signal. Frequency diversity radio transmitting apparatus including at least a modulator for oscillating, a local oscillator for oscillating a single local frequency, and a frequency converter for frequency-converting a modulated wave from the modulator by the single local frequency from the local oscillator. . 3. A frequency diversity wireless receiving device as a receiving side device when performing frequency diversity wireless communication by radio waves, while appropriately selecting any one of two or more transmission frequencies as a receiving frequency. A local oscillator that oscillates a single local frequency, and based on the single local frequency from the local oscillator, by performing frequency conversion of the received transmission signal, the original main transmission carrier component,
A frequency converter that reproduces a modulated wave corresponding to a harmonic component, a filter that separates and extracts the modulated wave from the frequency converter according to the original main transmission carrier component and harmonic component, and a main transmission carrier from each of the filters Component, a level detector that detects the level of a modulated wave corresponding to a harmonic component, a reception wave switch that appropriately selects a modulation wave with a high signal level from the signal levels from each of the level detectors, and the reception wave A frequency diversity radio receiver including at least a demodulator for demodulating a modulated wave selectively output from a switch. 4. A frequency diversity wireless communication device when bidirectional frequency diversity wireless communication is performed while appropriately selecting any one of two or more transmission frequencies as a reception frequency. A carrier oscillator that generates a main transmission carrier component with a wave component attached thereto, and a modulator that modulates each of the main carriers with the same modulation signal, using the main transmission carrier component and the harmonic component from the carrier oscillator as carriers. A wireless transmission function including at least a local oscillator that oscillates a single local frequency and a frequency converter that frequency-converts the modulated wave from the modulator by the single local frequency from the local oscillator; and a single local frequency. Frequency conversion of the received transmission signal based on a local oscillator that oscillates and a single local frequency from the local oscillator. By doing so, the frequency converter that reproduces the modulated wave corresponding to the original main transmission carrier component and the harmonic component, and the modulated wave from the frequency converter is separated and extracted corresponding to the original main transmission carrier component and the harmonic component. A filter, a level detector for level-detecting a modulated wave corresponding to a main transmission carrier component and a harmonic component from each of the filters, and a modulated wave with a high signal level among the signal levels from each of the level detectors are appropriately selected. A frequency diversity wireless communication device comprising: a reception wave switch to be selected; and a wireless reception function including at least a demodulator that demodulates a modulated wave selectively output from the reception wave switch. 5. A frequency diversity radio communication method when radio communication is performed by radio waves, while any one of the transmission frequencies of two or more waves is appropriately selected as a reception frequency. After one carrier wave is modulated by the modulation signal, it is wirelessly transmitted by radio waves as a transmission signal in the state where the frequency is converted by the local oscillation frequency including the harmonic component, while at the receiving side, the received transmission signal is A state in which a signal level of the modulated wave is obtained corresponding to the two types of modulated waves by performing level conversion in a state where the two types of modulated waves are reproduced by being converted and are separated and extracted. In the frequency diversity wireless communication method, a modulated wave having a higher signal level is appropriately selected from the signal levels and demodulated. 6. A frequency diversity wireless transmission device as a transmission side device when frequency diversity wireless communication by radio waves is performed while any one is appropriately selected from two or more transmission frequencies as a reception frequency. A carrier wave oscillator that generates a single carrier wave, a modulator that modulates a carrier wave from the carrier wave oscillator with a modulation signal, a local oscillator that oscillates a local oscillation frequency including a harmonic component, and a harmonic wave from the local oscillator. A frequency diversity radio transmitting apparatus including at least a frequency converter that frequency-converts a modulated wave from the modulator with a local frequency including a wave component. 7. A frequency diversity wireless communication device for performing frequency diversity wireless communication by radio waves in both directions while appropriately selecting any one of two or more transmission frequencies as a reception frequency. A carrier wave oscillator that generates one carrier wave, a modulator that modulates a carrier wave from the carrier wave oscillator with a modulation signal, a local oscillator that oscillates a local oscillation frequency including a harmonic component, and a harmonic wave component from the local oscillator. A radio transmission function including at least a frequency converter that frequency-modulates a modulated wave from the modulator with a local frequency that includes a local oscillator that oscillates a single local frequency, and based on the single local frequency from the local oscillator, A frequency converter that reproduces two types of modulated waves by frequency-converting the received transmission signal, and the frequency converter. A high signal level is selected from a filter that separates and extracts two types of modulated waves from the converter, a level detector that level-detects the modulated waves from each of the filters, and a signal level from each of the level detectors. A frequency diversity wireless communication device comprising: a reception wave switch that appropriately selects a modulation wave; and a wireless reception function that includes at least a demodulator that demodulates a modulation wave that is selectively output from the reception wave switch.