JP2000324033A - Method and device for repeating identical frequency - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make small the reception level of an unnecessary wave due to the sneaking of a transmit wave and to prevent oscillation in a repeater station by adjusting and optimizing the excitation of the amplitude and phase of element antennas constituting an array antenna system receiving a sneaking wave of the transmit wave and forming a reception array pattern null in the direction of the transmitting antenna of this repeater station. SOLUTION: A repeater station receiving antenna 3b can be adjusted in excitation amplitude (a2) and phase (ϕ2) by using a reception module 7 and a phase shifter 8. One repeater station receiving antenna 3b is added to a repeater station receiving antenna 3a, and the reception array pattern null is formed in the direction of the transmitting antenna of this station by suitably adjusting the excitation of the amplitude and phase of the added repeater station receiving antenna 3b according to a predetermined evaluation function to lower the reception level of a sneaking wave 5 of the transmit wave of this station, thereby obtaining the method and device for identical frequency repeating which can prevent oscillation in the repeater station.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a system for digitally transmitting terrestrial waves such as television broadcasts, for example, SFN (Single Frequency Net)
TECHNICAL FIELD The present invention relates to a method and apparatus for repeating the same frequency that removes a loop wave from a transmission antenna at a relay station in a system adopting a work (work) method.

[0002]

2. Description of the Related Art FIG. 10 is a conceptual diagram of an SFN terrestrial wave transmission system to which a conventional same frequency relay method using the same frequency f1 for transmission and reception is applied, where 1 is a master station, 4 is a user station, 13 indicates a relay station, and 14 indicates a service area of each relay station.

FIG. 11 is a block diagram showing the configuration of a relay station 13 between a master station 1 and a user station 4. In FIG. 11, reference numeral 2 denotes a relay station transmitting antenna, 3 denotes a relay station receiving antenna, and 5 denotes a relay station receiving antenna.
Is a loop-back wave wrapping around from the relay station transmitting antenna 2 to the relay station receiving antenna 3, 6 is a digital relay amplifier, and 7 is a receiving module.

Next, the operation will be described. In such a conventional analog broadcast relay system, different channels are used to avoid co-channel interference. In a digital broadcasting relay system, the same program is relay-transmitted at the same frequency or simultaneously broadcast by a plurality of stations. Such technology is referred to as SFN (Single Frequency)
This is a network that can cover a wide range with one frequency channel as shown in FIG. 10 and broadcasts the same program, that is, the same modulation content from a plurality of broadcast stations at the same transmission frequency.

In this case, mutual interference in adjacent areas poses a problem. However, when the same program broadcast transmitted from a plurality of stations is regarded as a signal from a multipath transmission line during demodulation, the delay time of each received signal is within an allowable range. If so, the reception strength can be increased as it is. Each relay station 13 amplifies a signal received from the master station 1 and transmits the amplified signal to the user station 4 located in each service area 14.

[0006]

Since the conventional method and apparatus for relaying the same frequency are configured as described above, the relay station 13 uses the same frequency for transmission and reception.
As shown in FIG. 11, there is a problem that a transmission wave at the relay station 13 wraps around, couples to the relay station reception antenna 3, and oscillates in a loop within the relay station 13. In order to prevent such a transmission wave from oscillating from the transmitting antenna to the receiving antenna and oscillating, it is necessary that the radio wave wrapping around the amplifier has a larger attenuation than the amplification factor of the relay station amplifier. That is, it is necessary to make the loop gain 15 shown in FIG. 11 negative, such that loop gain = G (gain of the relay station amplifier) + C (coupling amount of the reentrant wave of the transmission wave) <0.

For this reason, a method of sufficiently increasing the distance between the transmitting and receiving antennas of the relay station receiving antenna 3 and the relay station transmitting antenna 2 has been studied. However, such a method has a problem that the distance between the transmitting and receiving antennas of the relay station is increased, and a large relay base station is required for the SFN relay system.

[0008] Further, as disclosed in, for example, "Interference Wave Elimination Device and Level / Phase Adjustment Circuit Using Quadrature Antenna System" disclosed in JP-A-9-18230, two reception antennas are set, and An interfering wave removing method using a quadrature antenna system that removes an interfering wave by adjusting the voltage level and phase of the interfering wave voltage induced in the two antennas has been considered. In this method, optimal values of the voltage level and the phase are determined. There is a problem that it has to be obtained while adjusting the hardware, which takes time and effort.

In addition, since the two element antennas cannot receive the signal from the master station 1 and the interference wave caused by the sneak path from the own station completely separated from each other, there has been a problem that the error generated becomes large.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and employs a plurality of antennas as receiving antennas, and obtains an optimum value of the excitation amplitude and phase value to form an antenna pattern null. Accordingly, it is an object of the present invention to provide a same-frequency relay method and apparatus which can reduce the reception level of an unnecessary wave due to a transmission wave and prevent oscillation in a relay station.

[0011]

The same frequency relay method according to the present invention receives a transmission wave from a master station and a loop wave of the transmission wave to the master station transmitted from a transmission antenna of the own relay station. Adjusting and optimizing the amplitude and phase excitation of the element antennas constituting the array antenna system, forming a receiving array pattern in the direction of the transmitting antenna of the own relay station, and receiving the loopback wave at the own relay station The level is reduced.

In the same frequency relay method according to the present invention, a transmission wave from a master station and a loopback wave of a transmission wave to the master station transmitted from a transmission antenna of its own relay station are received.
The amplitude and phase excitation of one element antenna of an array antenna system composed of two element antennas is adjusted to form a reception array pattern in the direction of the transmitting antenna of the own relay station, and the loopback wave at the own relay station is adjusted. Is reduced.

In the same frequency relay method according to the present invention, a transmission wave from a master station and a loop wave of the transmission wave to the master station transmitted from a transmission antenna of the own relay station are received.
Excitation of amplitude and phase of other element antennas except one element antenna of an array antenna system composed of one or more element antennas is adjusted to form a reception array pattern in the direction of the transmission antenna of the own relay station. , The reception level of the loopback wave at the own relay station is reduced.

In the same frequency relay method according to the present invention, a transmission wave from a master station and a loopback wave of the transmission wave to the master station transmitted from a transmission antenna of the own relay station are received.
Adjust the amplitude and phase excitation of all element antennas of the array antenna system composed of one or more element antennas,
A receiving array pattern null is formed in the direction of the transmitting antenna of the own relay station so as to reduce the reception level of the loop interference wave at the own relay station.

In the same frequency relay method according to the present invention, the excitation of the amplitude and phase of the element antenna of the array antenna system is adjusted, and the antenna is located within an arbitrary area centered on the direction of the transmitting antenna of the own relay station. A pattern null is formed to reduce the reception level of the loop interference wave at the own relay station.

In the same frequency relay method according to the present invention, the excitation of the amplitude and the phase of each of the element antennas of the array antenna system different from each other are adjusted to form a receiving array pattern null in the direction of the transmitting antenna of the own relay station. , To reduce the reception level of the loop interference wave at the own relay station.

In the same frequency relay method according to the present invention, each received signal of an element antenna constituting an array antenna system is converted into a digital signal, adaptive signal processing is performed using the conversion result, and an optimum signal given to the element antenna is provided. The weight is determined, and the determined weight is used for the excitation distribution to reduce the reception level of the wraparound wave.

In the same frequency relay method according to the present invention, a frequency of a signal received by an element antenna constituting an array antenna system is converted into an intermediate frequency, and an excitation distribution of the element antenna is determined in the intermediate frequency band. This is to reduce the reception level of the loop wave.

The same frequency relay method according to the present invention is a virtual element for receiving a transmission wave to the master station using signal information of a transmission wave to the master station transmitted from the transmission antenna of the own relay station. Adding an antenna, combining the output of the virtual element antenna and the output of the element antenna receiving the transmission wave from the master station, adjusting the amplitude and phase excitation of the element antenna, optimizing, wrapping around The wave reception level is reduced.

The same-frequency repeater according to the present invention constitutes an array antenna system for receiving a transmission wave from the master station and a loop-back wave of the transmission wave to the master station transmitted from the transmission antenna of the own relay station. Optimizing the excitation of the element antenna and the amplitude and phase of the element antenna for forming a reception array pattern null in the direction of the transmission antenna of the own relay station, and adjusting the excitation of the amplitude and phase of the element antenna And an optimizing means for performing the following.

[0021]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below. Embodiment 1 FIG. FIG. 1 is a relay station configuration diagram showing a relay station antenna system to which the same frequency relay method of the first embodiment is applied. In the figure, 1 is a master station, and 2 is a relay station transmission antenna (transmission antenna). Reference numerals 3a and 3b denote relay station receiving antennas (element antennas). The relay station receiving antenna 3a and the relay station receiving antenna 3b have a two-element array antenna configuration. 4 is a user station, 5 is a loop wave,
6 is a digital repeater amplifier, 7 is a receiving module, 8 is a phase shifter, 9 is an amplitude / phase control circuit (optimizing means), and 11 is a multiplexer. Reference numeral 13 denotes a relay station including the relay station transmitting antenna 2, the relay station receiving antennas 3a and 3b, the digital relay amplifier 6, the receiving module 7, the phase shifter 8, the amplitude phase control circuit 9, and the like.

Next, the operation will be described. In the relay station receiving antennas 3a and 3b in FIG. 1, the electric field of each antenna in the direction of the master station is E _1m , and the electric field of the own station in the direction of the relay station transmitting antenna 2 is E _2m . Regarding the relay station receiving antenna 3b,
It is possible to adjust the excitation amplitude a ₂ and the phase φ ₂ by using the receiving module 7 and the phase shifter 8. here,
An evaluation function F as shown in the following equation (1) is set.

[0023]

(Equation 1)

In the above equation (1), the first term on the right side is the self-station so that the combined power of the two element antennas of the receiving antenna 3b of the relay station toward the master station 1 is at a desired level G _0. , So that the combined power of the receiving antennas becomes zero in the direction of the transmitting antenna 2 of the relay station. Actually, the second term does not become zero, but the excitation amplitude a ₂ and the phase φ ₂ of the relay station receiving antenna 3b are optimized so as to approach zero. Here, optimal values of the excitation amplitude a ₂ and the phase φ ₂ are obtained by using an optimization method such as the steepest descent method using a ₂ and φ ₂ as variables. At this time, since the relay station receiving antenna 3a does not excite, the excitation amplitude a ₁ has a value of 1 and the phase φ ₁ has a value of 0 degree. By giving the excitation amplitude a ₂ and the phase φ ₂ determined in this way to the relay station receiving antenna 3b, a null point of the combined pattern of the receiving antennas is formed in the direction of the transmitting antenna of the own station, and the wraparound arriving from this direction is formed. The reception level of wave 5 is reduced.

As described above, according to the first embodiment, one relay station receiving antenna 3b is added to the conventional relay station receiving antenna 3a, and the added relay station receiving antenna 3b is added.
Is adjusted optimally based on the evaluation function of the above formula (1) to form a receiving array pattern null in the direction of the transmitting antenna of the own station, and to adjust the reception level of the wraparound wave 5 of the transmitting wave of the own station. There is an effect that the same frequency relay method and apparatus that can prevent oscillation in the relay station by reducing the frequency can be obtained.

Embodiment 2 FIG. FIG. 2 is a block diagram showing a relay station antenna system to which the same frequency relay method according to the second embodiment is applied. 2, the same or corresponding parts as those in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted. In FIG. 2, 3c is a plurality of relay station receiving antennas (element antennas), 7a is a receiving module of one of the plurality of relay station receiving antennas 3c, and 8a is a transfer module of the relay station receiving antenna 3c. It is a phaser. 7b is a receiving module of another one of the plurality of relay station receiving antennas 3c, and 8b is a phase shifter of the relay station receiving antenna 3c. 13a is a relay station transmitting antenna 2, relay station receiving antennas 3a and 3c,
Digital relay amplifier 6, receiving modules 7a and 7b,
The relay station includes phase shifters 8a and 8b, an amplitude / phase control circuit 9, a multiplexer 11, and the like.

In the second embodiment, as shown in FIG. 2, in addition to the conventional relay station receiving antenna 3a, a plurality of relay station receiving antennas 3c are newly added, and an array of three or more elements is provided. An antenna configuration is used.

Next, the operation will be described. In the relay station receiving antenna of FIG. 2, the master station 1 of each relay station receiving antenna
The electric field in the direction is E _1m , and the electric field in the direction of the relay station transmitting antenna 2 is E _2m . Here, the total number of relay station receiving antennas is M. The relay station receiving antenna 3c is a receiving module 7
The excitation amplitude a _M and the phase φ _M can be adjusted by using the phase shifters 8 a and 8 b and the phase shifters 8 a and 8 b. here,
The evaluation function F of the second embodiment corresponding to the above equation (1) is set as shown in the following equation (2). Here, the elements of the vector X are the excitation amplitude a _m and the phase φ _m of each element antenna.

[0029]

(Equation 2)

In the equation (2), as in the equation (1), the first term on the right-hand side is such that the combined power of the receiving antenna toward the master station 1 is at a desired level G _0, and the second term is that of the own station. It works so that the combined power of the receiving antennas in the direction of the relay station transmitting antenna 2 becomes zero. Actually, the second term does not become zero, and the excitation amplitude a _m and the phase φ _m (m ≠ 1) of the relay station receiving antenna 3c become variables and are optimized so as to approach zero. At this time,
The excitation amplitude a ₁ and phase φ ₁ of the relay station receiving antenna 3a have constant values.

Using the steepest descent optimization method similar to that of the first embodiment, the variables in the evaluation function of the equation (2) are optimized, and the excitation amplitude a _m and the phase φ _m determined in this manner are determined.
Is given to all the element antennas of the relay station receiving antenna 3c, so that the null point of the combined pattern of the relay station receiving antennas is formed in the direction of the relay station transmitting antenna 2 of the own station, and the reception of the loop interference 5 arriving from this direction is performed. Decrease the level.

FIG. 3 is a flowchart showing the operation in the case where the excitation amplitude and phase of the relay station receiving antenna 3b are optimized by using the steepest descent optimization method. This flowchart shows a general procedure of the steepest descent optimization method, and therefore will not be described in detail.

As described above, according to the second embodiment, a plurality of relay station receiving antennas are added to the conventional relay station receiving antenna, and the added relay station receiving antenna 3c is formed as an array antenna configuration of three or more elements. By optimally adjusting the excitation of the amplitude and the phase of the plurality of element antennas constituting the above based on the evaluation function of Equation (2), a reception array pattern null is formed in the direction of the relay station transmitting antenna 2 of the own station. The reception level of the loop wave 5 of the transmission wave of the own station is reduced, and the oscillation in the relay station 13a is prevented.

At the same time, since the excitation of a plurality of element antennas constituting the relay station receiving antenna 3c can be controlled, the degree of freedom is increased as compared with the first embodiment. This has the effect of realizing a method and apparatus for relaying the same frequency that can direct the beam peak with high accuracy.

Embodiment 3 FIG. FIG. 4 is a block diagram showing a relay station antenna system to which the same frequency relay method according to the third embodiment is applied. 4, parts that are the same as or correspond to those in FIG. 2 are given the same reference numerals, and descriptions thereof will be omitted. In FIG. 4, reference numeral 3b denotes a plurality of element antennas having two or more elements, and is a relay station receiving antenna having an array antenna configuration.

Next, the operation will be described. Figure in the relay station receiving antenna 3b of 4, electric field E _{1 m} of the master station direction of each antenna, the electric field of the relay station transmitting antenna 2 direction of the station E
_2m . Each relay station receiving antenna 3b is possible to adjust the excitation amplitude phase a _m, φ _m with receiving module 7a and the phase shifter 8a, the receiving module 7b and the phase shifter 8b. In the third embodiment, the number of elements of the relay station receiving antenna 3b is M, and m = 1 to M. Here, similarly to the second embodiment, an evaluation function F as shown in the above equation (2) is set. 13b is a relay station.

In the above equation (2), in the third embodiment,
Is the excitation amplitude a of the relay station receiving antenna _m, Phase φ_mIs all
Variable, which is a variable of the first and second embodiments.
Like the additive element antennas 3b and 3c, they are subject to optimization.
The excitation amplitude a determined in this way_m, Phase φ_mIn
By giving it to the relay station receiving antenna 3b, the receiving antenna
The null point of the combined pattern of the teners is
Loop 2 that is formed in the direction of
5 is reduced.

As described above, according to the third embodiment, a plurality of element antennas are used for the relay station receiving antenna,
Excitation of amplitude and phase of all element antennas is expressed by equation (2).
, The reception pattern is formed in the direction of the relay station transmitting antenna 2 of the own station with a small number of elements, and the reception level of the wraparound wave 5 of the transmitting wave of the own station is reduced. This has the effect of realizing the same frequency relay method and apparatus that can prevent oscillation in the relay station.

Embodiment 4 In the first to third embodiments, the reception radiation pattern null is formed in a specific direction. In the fourth embodiment, the reception radiation pattern null is formed in a range having a certain area. Form a radiation pattern null.

FIG. 5 is a block diagram showing a relay station antenna system to which the same frequency relay method according to the fourth embodiment is applied. In FIG. 5, the same or corresponding parts as those in FIG. 2 are denoted by the same reference numerals, and description thereof will be omitted. In the figure,
The relay station receiving antenna 3c can adopt the array antenna configuration of the first to third embodiments. 13c is a relay station.

Next, the operation will be described. The loop wave from the relay station transmission antenna actually arrives not only in one specific direction as shown in FIG. 5 but also over a certain range centered on the transmission antenna direction. Here, assuming that the electric field vector of each element antenna in any of a plurality of directions n (n = 2 to N: n = 1 is the master station) within the above range is E _nm , the evaluation function of this embodiment is It can be set as shown in (3).

[0042]

(Equation 3)

The evaluation function of the above equation (3) is optimized in the same manner as in the first to third embodiments, and the excitation amplitude a _m and the phase φ _m determined in this way are determined by using the relay station receiving antenna. By giving the antenna 3c to the element antenna, the null point of the combined pattern of the receiving antennas is formed in an arbitrary range centered on the transmitting antenna direction of the own station, and the reception level of the wraparound wave arriving from these directions is reduced.

As described above, in the fourth embodiment, the evaluation function is set for a plurality of points within a certain area in the direction of the transmitting antenna of the own station, and the excitation of the amplitude and phase of the plurality of receiving element antennas is performed. By optimally adjusting the plurality of points, a receiving array pattern null is formed in a certain area having a certain spread in the direction of the transmitting antenna of the own station, and the reception level of the wraparound wave of the transmitting wave of the own station is reduced. This has the effect of realizing a method and apparatus for repeating the same frequency that can prevent oscillation in the relay station 13c.

The formation of the reception array pattern null of the fourth embodiment described above can be applied to the configuration of the relay station described in the first to third embodiments.
Similar effects can be expected.

Embodiment 5 FIG. In each of the embodiments described above, optimization is performed using a plurality of element antennas of the same type. In Embodiment 5, optimization is performed efficiently using two different types of element antennas.

FIG. 6 is a block diagram of a relay station showing a relay station antenna system to which the same frequency relay method of the fifth embodiment is applied. 6, the same or corresponding parts as those in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted. In the figure,
3b is an element antenna pointing in the direction of the master station. 3d
Is an element antenna pointing in the direction of its own transmitting antenna, which is different from the element antenna 3b. 13d is a relay station.

Next, the operation will be described. As shown in Embodiments 1 to 4, two types of plural element antennas as shown in FIG. 6 are provided as relay station receiving antennas. In the fifth embodiment, different types of element antennas 3b and 3d are used for the plurality of element antennas, and the evaluation function is optimized as in the first to fourth embodiments.

From the directional characteristics of each element antenna,
In the equation (2) or (3), the element antenna 3b
Represents the first term on the right side, and the element antenna 3d largely acts on the second term on the right side. Therefore, two different types of element antennas can be used as reception antennas, and the element antenna 3b can be preferentially controlled to maintain the level in the direction of the master station and the element antenna 3d can be used to suppress the wraparound wave from the direction of the transmission antenna of the own station. .

As described above, according to the fifth embodiment, the respective excitations are optimized by using the two types of element antennas 3b and 3d for directing the transmitting antenna directions of the master station and the own station independently. Therefore, the same frequency relay method and apparatus capable of separating the loop wave from the transmitting antenna of the own station from the received wave from the master station, efficiently reducing the reception level of the loop wave, and preventing transmission in the relay station are provided. There are effects that can be realized.

Embodiment 6 FIG. In each of the embodiments described above, the control configuration is based on the assumption that there is almost no change in the surrounding environment of the relay station or the arrival state of the radio wave. In some cases, the excitation of each antenna is automatically controlled in accordance with the change, and optimization is performed in accordance with the changed environment.

FIG. 7 is a block diagram showing a relay station antenna system to which the same frequency relay method according to the sixth embodiment is applied. 7, parts that are the same as or correspond to those in FIG. 6 are given the same reference numerals, and descriptions thereof will be omitted. 7, 13e is a relay station, 21 and 22 are A / D converters,
Reference numeral 23 performs adaptive signal processing using the received digital signals of the element antennas 3b and 3d output from the A / D converters 21 and 22, and determines the optimum weight given to each of the element antennas 3b and 3d according to the fluctuation of the received signal. A signal processing unit (optimizing means) that obtains only the received signal from the master station by removing the signal caused by the loop interference from the relay station transmitting antenna 2 by calculating and calculating the combined power using the optimum weight. .

Next, the operation will be described. In the sixth embodiment, as in the first to fifth embodiments, a plurality of receiving element antennas 3 are used as relay station receiving antennas.
b, 3d, and the plurality of element antennas 3b, 3d
Fetches the received signals converted into digital signals through A / D converters 21 and 22 independently of each other. Then, each element antenna 3b converted into a digital signal,
The signal processing unit 23 performs adaptive signal processing using the received signal of 3d, and calculates an optimum weight to be given to each of the element antennas 3b and 3d in accordance with the fluctuation of the received signal. By calculating the combined power using this optimum weight, it is possible to obtain a signal of only the reception signal from the master station, from which the signal of the sneak wave from the relay station transmission antenna 2 of the own station has been removed.

As described above, according to the sixth embodiment, the signals from the plurality of element antennas 3b and 3d are independently captured as digital signals, and adaptive processing is performed, thereby allowing the passage of an aircraft or the construction of a building. By optimizing the excitation of each element antenna in response to changes in the surrounding environment, such as changes in the power of the master station transmission wave, etc., the reception level of the sneak wave can be reduced and oscillation in the relay station 13e can be prevented. There is an effect that the frequency relay method and apparatus can be realized.

Embodiment 7 FIG. In each of the embodiments described above, the composition and the optimization of the antenna are performed in the RF frequency band. In the seventh embodiment, however, the antenna is converted to the IF frequency so that it can be easily added to the existing repeater system. The above optimization will be performed later.

FIG. 8 is a block diagram showing a relay station antenna system to which the same frequency relay method according to the seventh embodiment is applied. 8, parts that are the same as or correspond to those in FIG. 6 are given the same reference numerals, and descriptions thereof will be omitted. 8, 10a is a low noise amplifier circuit, 10b is a mixer, 10c
Denotes a local signal processing unit, and 10d denotes an IF processing unit. 1
Reference numeral 0 denotes a receiving unit including a low-noise amplifier circuit 10a, a mixer 10b, a local signal processing unit 10c, an IF processing unit 10d, and the like. 13f is a relay station.

In the seventh embodiment, the first embodiment is used.
Thus, a plurality of element antennas 3b and 3d as shown in FIG. Then, the signals fetched from the plurality of element antennas 3b and 3d are converted into IF frequencies in the receiving unit 10, and then excitation distribution is given to each of them to perform synthesis. The principle of optimization is the same as for RF frequencies.

As described above, according to the seventh embodiment, the signal waves received from element antennas 3b and 3d are
After the conversion into the frequency, the excitation distribution is optimized and synthesized, and the optimization method can be added to the existing repeater system and applied to the IF frequency. There is an effect that the same frequency relay method and apparatus that can be easily applied, reduce the reception level of the loopback wave, and prevent transmission in the relay station can be realized.

The formation of the reception array pattern null of the seventh embodiment described above can be applied to the configuration of the relay station described in the first to third embodiments.
Similar effects can be expected.

Embodiment 8 FIG. In each of the embodiments described above, a plurality of element antennas are actually installed as reception antennas, and the excitation of each element is optimized to reduce the wraparound of the transmission wave of the own station. In step 8, the optimization is performed without increasing the number of receiving antennas so as to easily cope with the existing repeater system.

FIG. 9 is a block diagram showing a relay station antenna system to which the same frequency relay method of the eighth embodiment is applied. In FIG. 9, the same or corresponding parts as those in FIG. 8 are denoted by the same reference numerals, and description thereof will be omitted. In FIG. 9, reference numeral 14 denotes a feedback loop, which is a virtual path for taking in information of a transmission wave of the own station, 12 denotes a virtual signal processing system,
3g is a relay station.

In the eighth embodiment, the information of the transmission wave of the own station is transmitted via the feedback loop 14 to the virtual signal processing system 1.
2 and a virtual element antenna for receiving the own station transmission wave is added using this information. The reception signal of the assumed element antenna is composed entirely of information of the transmission wave of the own station. Information on the added virtual element antenna,
The information from the receiving antenna oriented in the direction of the master station is synthesized, and the excitation distribution is determined and synthesized by the above-mentioned optimization method.

As described above, according to the eighth embodiment, a plurality of reception antennas are virtually assumed without actually adding reception antennas, and the information of the own-station transmission wave is used. The same frequency relay method and apparatus that can remove the influence of the loop wave of the own station transmission wave with high accuracy and prevent oscillation in the relay station 13g can be realized.

[0064]

As described above, according to the present invention, in order to reduce the reception level of the loopback wave at the own relay station, the transmission wave from the master station and the transmission wave from the transmission antenna of the own relay station are used. Adjusting and optimizing the amplitude and phase excitation of the element antennas that constitute the array antenna system that receives the loop wave of the transmission wave to the master station, optimizes the reception array pattern in the direction of the transmission antenna of the own relay station. Since it is formed, there is an effect that the reception level of an unnecessary wave due to the transmission of the transmission wave from the transmission antenna of the own relay station to the master station is reduced to prevent oscillation in the relay station.

According to the present invention, the transmission wave from the master station and the transmission wave to the master station transmitted from the transmission antenna of the self-relay station are reduced in order to reduce the reception level of the wraparound wave in the own relay station. The amplitude and phase excitation of one element antenna of an array antenna system composed of two element antennas for receiving the loop interference wave is adjusted to form a reception array pattern null in the direction of the transmission antenna of the own relay station. As a result, there is an effect that the reception level of the unnecessary wave due to the transmission of the transmission wave transmitted from the transmission antenna of the own relay station to the master station can be reduced with high accuracy, and the oscillation in the relay station can be prevented.

According to the present invention, the transmission wave from the master station and the transmission wave to the master station transmitted from the transmission antenna of the own relay station are used to reduce the reception level of the loop wave at the own relay station. The amplitude and phase of the other element antennas except one element antenna of the array antenna system composed of three or more element antennas that receive the loop interference wave are adjusted, and the direction of the transmission antenna of the own relay station is adjusted. The receiver array pattern is formed at
There is an effect that the reception level of the unnecessary wave due to the transmission of the transmission wave to the master station transmitted from the transmission antenna of the own relay station to the master station can be reduced with higher accuracy to prevent oscillation in the relay station.

According to the present invention, the transmission wave from the master station and the transmission wave to the master station transmitted from the transmission antenna of the self-relay station are reduced in order to reduce the reception level of the loop wave at the own relay station. Adjust the excitation of the amplitude and phase of all the element antennas of the array antenna system composed of two or more element antennas that receive the loop interference wave, and adjust the reception array pattern in the direction of the transmission antenna of the own relay station. Since it is formed, the reception level of unnecessary waves due to the transmission of the transmission wave from the transmission antenna of the local relay station to the master station can be reduced with higher accuracy to prevent oscillation in the relay station. There is.

According to the present invention, the amplitude and phase excitation of the element antenna of the array antenna system are adjusted to reduce the reception level of the loop wave at the own relay station, and the direction of the transmitting antenna of the own relay station is changed. Since the antenna pattern null is formed in a range having an arbitrary area at the center, the reception level of the unnecessary wave due to the wraparound of the transmission wave transmitted from the transmission antenna of the own relay station to the master station is improved. There is an effect that oscillation in the relay station can be prevented by reducing the size over a wide range.

According to the present invention, in order to reduce the reception level of the loop interference wave at the own relay station, the excitation of the amplitude and phase of each of the element antennas of the array antenna system having different forms is adjusted, and Since the receiving array pattern null is formed in the direction of the transmitting antenna, the wraparound wave from the transmission antenna of the own relay station is separated from the reception wave from the master station, and the reception level of the wraparound wave is efficiently reduced. However, there is an effect that transmission in the relay station can be prevented.

According to the present invention, each received signal of an element antenna constituting the array antenna system is converted into a digital signal in order to reduce the reception level of the loop interference wave in the own relay station, and the adaptive result is obtained using the conversion result. The signal processing is performed to determine an optimum weight to be given to the element antenna, and the determined weight is used for the excitation distribution to reduce the reception level of the wraparound wave. Excitation of each element antenna can be optimized according to a power change and the like, and the reception level of a wraparound wave can be flexibly reduced according to the situation, and there is an effect that oscillation in a relay station can be prevented.

According to the present invention, the frequency of a signal received by an element antenna constituting an array antenna system is converted to an intermediate frequency in order to reduce the reception level of a loop interference wave at the relay station. In the above, the excitation distribution of the element antenna is determined and the reception level of the loopback wave is reduced, so that it can be easily applied to an existing repeater system, and the reception level of the loopback wave is reduced to prevent transmission in the relay station. There is an effect that can be done.

According to the present invention, in order to reduce the reception level of the loopback wave at the own relay station, the signal information of the transmission wave to the master station transmitted from the transmission antenna of the own relay station is used. A virtual element antenna for receiving a transmission wave to a station is added, and the output of the virtual element antenna and the output of the element antenna for receiving the transmission wave from the master station are combined, and the amplitude of the element antenna And adjusting the phase excitation, optimizing, and reducing the reception level of the wraparound wave, the information of the transmission wave of the own relay station can be obtained by a virtual reception antenna without actually adding a reception antenna. Is used, the effect of the loop wave of the transmission wave of the own relay station can be removed with high accuracy, and there is an effect that oscillation in the relay station can be prevented.

According to the present invention, an element antenna constituting an array antenna system for receiving a transmission wave from a master station and a loop wave of a transmission wave to the master station transmitted from a transmission antenna of the own relay station, Optimizing the amplitude and phase excitation of the element antenna to form a reception array pattern null in the direction of the transmission antenna of the own relay station, and adjusting the amplitude and phase excitation of the element antenna Means, the reception level of unnecessary waves due to the transmission of the transmission wave transmitted from the transmission antenna of the own relay station to the master station is reduced, so that the oscillation in the relay station can be prevented. There is.

[Brief description of the drawings]

FIG. 1 is a relay station configuration diagram showing a relay station antenna system to which the same frequency relay method according to Embodiment 1 of the present invention is applied.

FIG. 2 is a configuration diagram of a relay station showing a relay station antenna system to which the same frequency relay method according to Embodiment 2 of the present invention is applied;

FIG. 3 is a flowchart showing an operation when optimizing the excitation amplitude and phase of the relay station receiving antenna using the steepest descent optimization method;

FIG. 4 is a configuration diagram of a relay station showing a relay station antenna system to which the same frequency relay method according to Embodiment 3 of the present invention is applied.

FIG. 5 is a relay station configuration diagram showing a relay station antenna system to which the same frequency relay method according to Embodiment 4 of the present invention is applied.

FIG. 6 is a relay station configuration diagram showing a relay station antenna system to which the same frequency relay method according to Embodiment 5 of the present invention is applied.

FIG. 7 is a relay station configuration diagram showing a relay station antenna system to which the same frequency relay method according to Embodiment 6 of the present invention is applied.

FIG. 8 is a relay station configuration diagram showing a relay station antenna system to which the same frequency relay method according to Embodiment 7 of the present invention is applied.

FIG. 9 is a configuration diagram of a relay station showing a relay station antenna system to which the same frequency relay method according to Embodiment 8 of the present invention is applied.

FIG. 10 shows the S to which the conventional same frequency relay method is applied.
FIG. 1 is a conceptual diagram of an FN terrestrial transmission system.

FIG. 11 is a block diagram showing a configuration of a relay station to which a conventional same frequency relay method is applied.

[Explanation of symbols]

1 master station, 2 relay station transmission antenna (transmission antenna),
3a, 3b, 3c Relay station receiving antenna (element antenna), 3d element antenna, 4 user station, 9 amplitude / phase control circuit (optimizing means), 13, 13a, 13b, 13
c, 13d, 13e, 13f, 13g relay station, 21,
22 A / D converter, 23 signal processing unit (optimizing means).

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Junya Koyama 2-3-2 Marunouchi, Chiyoda-ku, Tokyo Mitsui Electric Co., Ltd. (72) Shigemitsu Mizukawa 2-3-2 Marunouchi, Chiyoda-ku, Tokyo (72) Inventor Hideyo Ono 2-3-2 Marunouchi, Chiyoda-ku, Tokyo F-term (reference) 5J021 AA02 AA05 AA07 CA06 DB02 DB03 EA04 FA06 FA20 FA26 FA32 GA06 HA05 HA10 5K052 AA01 BB01 DD04 EE12 EE26 FF32 GG12 GG26 GG41 GG57 5K072 AA04 BB25 BB27 CC33 DD16 DD17 EE33 GG02 GG10 GG14 GG22 GG31

Claims (10)

[Claims] 1. A method of relaying a same-frequency digital terrestrial transmission wave of the same frequency transmitted and received between a master station and a user station, the method comprising: a transmission wave from the master station; Adjusting and optimizing the amplitude and phase excitation of the element antennas constituting the array antenna system that receives the loop wave of the transmission wave transmitted from the transmission antenna to the master station, and optimizing the direction of the transmission antenna of the own relay station To form a receiving array pattern null,
The same-frequency relay method, wherein a reception level of the loopback wave in the own relay station is reduced. 2. An array antenna system comprising one of two element antennas for receiving a transmission wave from a master station and a loop wave of a transmission wave to the master station transmitted from a transmission antenna of the own relay station. Adjusting the amplitude and phase excitation of the element antenna, forming a receiving array pattern null in the direction of the transmitting antenna of the own relay station, and reducing the reception level of the loop interference wave in the own relay station. 2. The same frequency relay method according to 1. 3. An array antenna system comprising three or more element antennas for receiving a transmission wave from a master station and a loop wave of a transmission wave to the master station transmitted from a transmission antenna of the relay station. Excitation of amplitude and phase of other element antennas except one element antenna is adjusted, a reception array pattern null is formed in the direction of the transmission antenna of the own relay station, and the reception level of the loop interference wave at the own relay station is reduced. The same frequency relay method according to claim 1, wherein: 4. An array antenna system comprising two or more element antennas for receiving a transmission wave from a master station and a loop wave of a transmission wave to the master station transmitted from a transmission antenna of the own relay station. Adjusting the amplitude and phase of each element antenna to zero advancement, forming a receiving array pattern null in the direction of the transmitting antenna of the own relay station, and reducing the reception level of the loop interference wave in the own relay station. 2. The same frequency relay method according to claim 1, wherein: 5. An antenna pattern null is formed in a range having an arbitrary area centered on a direction of a transmitting antenna of a local relay station by adjusting excitation of amplitude and phase of an element antenna of an array antenna system. The same frequency relay method according to any one of claims 1 to 4, wherein the reception level of the loop interference wave at the station is reduced. 6. The excitation of the amplitude and the phase of each of the element antennas having different forms in the array antenna system is adjusted to form a reception array pattern in the direction of the transmission antenna of the own relay station, and the wraparound wave of the wraparound wave in the own relay station is adjusted. The method of claim 1, wherein the reception level is reduced. 7. Converting each received signal of an element antenna constituting an array antenna system into a digital signal, performing adaptive signal processing using the conversion result, determining an optimum weight to be given to the element antenna, 7. The same-frequency relay method according to claim 6, wherein the received weight is used for the excitation distribution to reduce the reception level of the wraparound wave. 8. A frequency of a signal received by an element antenna constituting an array antenna system is converted into an intermediate frequency, an excitation distribution of the element antenna is determined in the intermediate frequency band, and a reception level of a loop wave is reduced. The same frequency relay method according to any one of claims 1 to 7, wherein: 9. A virtual element antenna for receiving a transmission wave to the master station by using signal information of a transmission wave to the master station transmitted from a transmission antenna of the own relay station, and Combining the output of the element antenna and the output of the element antenna receiving the transmission wave from the master station, adjusting and optimizing the amplitude and phase excitation of the element antenna, and reducing the reception level of the sneak wave. The same frequency relay method according to claim 1, wherein: 10. A same-frequency repeater for relaying a terrestrial digital transmission wave of the same frequency transmitted and received between a master station and a user station, comprising: a transmission wave from the master station; and a transmission antenna of the own relay station. An element antenna forming an array antenna system for receiving a loop wave of a transmission wave to the master station transmitted from the base station; and the element antenna for forming a reception array pattern in the direction of the transmission antenna of the own relay station. Optimizing means for optimizing the amplitude and phase excitation of the element antenna and adjusting the amplitude and phase excitation of the element antenna.