KR940008773B1 - Wireless repeater - Google Patents

Abstract

The system for relaying the communication or broadcasting signal comprises a main transmitter (1) modulating the transmission signal to a first frequency (F1), first relay stations (2,2A,2B...) generating a second frequency (F2) synchronized to the received first frequency, and second relay stations (3,3A,3B,...)generating the first frequency (f1) synchronized to the received second frequency (F2). Then the frequency usage for relay could be reduced because the even and odd relay stations use the same relay frequency.

Description

Wireless repeater

1 is a view showing the overall overview of the wireless relay device of the present invention.

2 is a block diagram showing the configuration of a receiver of a frequency modulation repeater in the wireless repeater of the present invention.

(A)-(h) of FIG. 3 are operation waveforms of each part of FIG.

Figure 4 is a block diagram showing the configuration of the receiver of the repeater of the amplitude and sideband modulation method in the wireless repeater of the present invention.

(A)-(j) of FIG. 5 are operational waveform diagrams of each part of FIG.

* Explanation of symbols for main parts of the drawings

1: mother station transmitter 2, 2a, 2b: first repeater

3, 3a, 3b: second repeater 11, 31: pepper wave amplifier

12, 32: frequency converter 13, 33: intermediate frequency amplifier

14, 34: detector 15, 37: limiting amplifier

16, 38: intermediate frequency divider 17, 39: reference oscillator

18, 40: fixed divider 19, 41: variable divider

20, 42: phase comparator 21, 43: low pass filter

22, 44: PLL type oscillator 23, 45: PLL type oscillator

35: Inverter 36: Mixer

ANT11, ANT31: Antenna

The present invention relates to a wireless repeater for relaying wireless communication and broadcasting signals to a hearing loss area and a remote area, and in particular, to synchronize the oscillation frequency of a repeater with the oscillation frequency of a home transceiver so that multi-stage wireless relay can be performed with two carrier frequencies. It relates to a wireless relay device.

Conventionally, when receiving a signal transmitted from the repeater and relaying it, if the transmitting frequency of the mother transmitter and the repeating frequency of the repeater are the same, interference, intermodulation, and beat sounds may occur due to the phase difference between the two transmitting frequencies. Therefore, it is necessary to make the transmission frequency of the mother station transmitter and the transmitter frequency different from each other.

Therefore, there was a lot of waste of frequency, and because of the limited frequency, it was not only limited to the installation of the repeater but also caused the problem of lack of frequency, limiting the number of radio relaying areas.

In addition, since a separate oscillator is configured at the transmitter and the receiver of each repeater, and an oscillation frequency of these oscillators must be installed, an automatic frequency regulator and a thermostat need to be installed, which causes a lot of installation and maintenance costs of the repeater.

The present invention was devised to solve the above-mentioned problems, and by adjusting the oscillation frequency of the oscillator in synchronization with the reception signal frequency of each relay, it is excellent by synchronizing the oscillation frequencies of all the repeaters with the oscillation frequency of the mother transmitter. The second and the radix repeaters can transmit at the same frequency to reduce the use of frequency, and to provide a wireless repeater to stabilize the oscillation frequency without installing a separate automatic frequency regulator and thermostat in the repeater. The purpose thereof is described in detail with reference to the accompanying drawings.

1 is a view showing the overall overview of the wireless relay device of the present invention.

As shown in the drawing, in the present invention, the mother station transmitter 1 modulates and transmits a signal to be transmitted at a first frequency F1, and relays the transmission signal of the mother station transmitter 1 to the first repeaters 2, 2A, 2B .....) receives the signal of the first frequency (F1) transmitted by the mother station transmitter (1), modulates the signal to the second frequency (F2), and transmits the second repeater (3, 3A, 3B ..). .) Receives the signal of the second frequency (F2) transmitted by the first repeaters (2, 2A, 2B ....) and modulates and transmits to the first frequency (F1) F in the same manner as the mother station (1). do.

Here, the present invention allows the oscillation frequency of the oscillator of the mother station transmitter (1) to stably generate the first frequency (F1) using an automatic frequency regulator and a thermostat, and the first repeater (2, 2A, 2B, .. .) Causes the oscillator to oscillate in synchronism with the first frequency F1 transmitted by the mother station transmitter 1 to generate the second frequency F2, and the second repeaters 3, 3A, 3B, ... The oscillator oscillates in synchronization with the second frequency F2 transmitted by the first repeaters 2, 2A, 2B, ... to generate the first frequency F1.

Therefore, according to the present invention, the signal of the first frequency F1 outputted by the mother station transmitter 1, the signal of the second frequency F2 outputted by the first repeaters 2, 2A, 2B, ... The transmitter 1 and the second repeater 3 are all synchronized with the oscillation frequency of the oscillator of the home transceiver 1 by the signals of the first frequency F1 output by the repeaters 3, 3A, 3B, ... (3A, 3B, ....) (where, in the case of relaying in multiple stages, the signals of the first frequency F1 output by the first even frequency repeater transmitting the first frequency F1) coincide with each other. No intermodulation, beats, etc. occur, and the first repeaters (2, 2A, 2B, ...) (where every second repeater transmits a second frequency (F2) when relaying in multiple stages. Signal of the second frequency (F2) outputted by) also does not coincide with each other.

When the reception frequency and the transmission frequency of the first repeaters 2, 2A, 2B, ... and the second repeaters 3, 3A, 3B, ... are the same, the repeaters 2, 2A, 2B, Each repeater (2,2A, 2B, ....) receives a signal transmitted by (3,3A, 3B, ....) and generates intermodulation and beat. Set the transmission frequency and reception frequency of (3,3A, 3B, ...) differently.

Therefore, according to the wireless repeater of the present invention, even if a plurality of repeaters are used and relay transmission is performed through several repeaters, only two frequencies, that is, the first frequency F1 and the second frequency F2, are transmitted. Can be used as a signal relay transmission

FIG. 2 is a block diagram showing the configuration of a receiver when the first repeaters 2, 2A, 2B, ..., and the second repeaters 3, 3A, 3B, ... are frequency modulated. As shown, a high frequency amplifier 11 for amplifying the received signal of the antenna ANT11, a frequency converter 12 for converting a local oscillation signal into an output signal of the high frequency amplifier 11 and converting it into an intermediate frequency signal; An intermediate frequency amplifier 13 for amplifying the output signal of the frequency converter 12, a detector 14 for detecting a transmission signal from the output signal of the intermediate frequency amplifier 13, and outputting it to a transmitter; A limiting amplifier 15 that amplifies the output signal of the intermediate frequency amplifier 13, an intermediate frequency divider 16 which divides the output signal of the limiting amplifier 15 to generate a pulse signal at a predetermined period, and a reference oscillator ( A reference oscillator 17 for oscillating 17A and generating a reference signal, and the reference oscillator 1 The frequency divider 18 divides the oscillation signal of 7) and the output signal of the fixed frequency divider 18 in a variable manner according to the broadcasting method to match the frequency of the output signal of the intermediate frequency divider 16. The phase comparator 20 for comparing the phases of the variable divider 19, the output signals of the intermediate frequency divider 16 and the variable divider 19, and the phase difference signals of the phase comparator 20 are filtered out. The local oscillation signal is synchronously generated and applied to the frequency converter 12 by using the low pass filter 21 for adjusting the oscillation signal of the mood oscillator 17 and the oscillation signal of the reference oscillator 17 as a reference signal. A PLL (Phase Locked Loop) type local oscillator 22 and a PLL transmission oscillator 23 which generate a transmission oscillation signal synchronously using the oscillation signal of the reference oscillator 17 as a reference signal.

The PLL type local oscillator 22 and the PLL type oscillator 23 are a PLL furnace composed of an oscillator, a divider, a phase comparator, a low pass filter, and the like, and use the oscillation signal of the reference oscillator 17 as a reference frequency. Outputs the oscillation signal of.

According to the present invention configured as described above, the high frequency amplifier 11 selects and amplifies one signal from the received signal of the antenna ANT11 and inputs it to the frequency transformer 12.

The PLL type local oscillator 22 generates a local oscillation signal having a frequency lower than that of the received signal of the high frequency amplifier 11 by the frequency of the intermediate frequency signal and inputs it to the frequency converter 12, so that the frequency converter 12 has a high frequency. The output signals of the amplifier 11 and the local oscillator 22 are mixed and converted into intermediate frequency signals as shown in FIG.

After the intermediate frequency signal output from the frequency converter 12 is amplified by the intermediate frequency amplifier 13, the detector 14 detects the transmission signal as shown in FIG. In the amplifier 15, the level is limited amplified as shown in FIG. 3C, and the intermediate frequency divider 16 is divided by a predetermined value as shown in FIG. 3D. 20).

The reference oscillator 17A of the reference oscillator 17 oscillates to output an oscillation signal, and the fixed oscillator 18 divides the output oscillation signal as shown in FIG. As shown in (f) of FIG. 3, (19) divides, outputs a signal having the same frequency as that of the output signal of the intermediate frequency divider 16, and is input to the phase comparator 20. FIG.

Then, the phase comparator 20 compares the phases of the output signals of the intermediate frequency divider 16 and the variable divider 19 to output a phase difference signal, and the output phase difference signal is converted into a DC level by the low pass filter 21. And input to the reference oscillator 17.

When the phase of the output signal of the intermediate frequency divider 16 is faster than the phase of the output signal of the variable frequency divider 19, it means that the oscillation frequency of the reference oscillator 17 is low. As shown in (g) of FIG. 3, a phase difference signal having a positive pulse width is output in proportion to the phase difference between the two signals, and the output phase difference signal is input to the reference oscillator 17 through the low pass filter 21, and then the reference oscillator. When the oscillation frequency of (17) is increased and the phase is quickly adjusted, and the phase of the output signal of the intermediate frequency divider 16 is slower than the phase of the output signal of the variable frequency divider 19, the oscillation of the reference oscillator 17 is performed. The phase comparator 20 outputs a phase difference signal having a negative pulse width in proportion to the phase difference between the two signals as shown in (h) of FIG. 3, and the output phase difference signal is a low frequency filter. The received signal received by the high frequency amplifier 11 to receive the oscillation signal of the reference oscillator 17 by reducing the phase of the oscillation frequency of the reference oscillator 17 and slowly adjusting the phase of the reference oscillator 17 through the reference oscillator 17. It is synchronized to the frequency of.

In this way, the PLL-type local oscillator 22 uses the oscillation signal of the reference oscillator 17 oscillated in synchronization with the frequency of the reception signal as a reference signal to generate a local oscillation signal of a predetermined frequency synchronized with the frequency of the reception signal. The generated local oscillation signal is input to the frequency converter 12 and used to convert the received signal of the high frequency amplifier 11 into an intermediate frequency signal as described above, and also converts the oscillation signal of the reference oscillator 17 into a PLL transmission oscillator ( 23) is used as a reference signal to generate a transmission oscillation signal of a predetermined frequency synchronized with the reception signal, and the transmission unit generates a transmission carrier signal and modulates the transmission signal in synchronization with the generated transmission oscillation signal.

Here, the frequency modulation method uses a frequency shift, and the frequency of the output signal of the intermediate frequency amplifier 13 is varied at a constant frequency shift value.

Therefore, in the present invention, the frequency shift value of the intermediate frequency divider 16 is equal to or greater than the frequency shift value, and the frequency shift is removed by setting the common frequency and the common multiple of the oscillation frequency of the intermediate frequency and the reference oscillator 17.

3 shows the configuration of a receiver when the first repeaters 2, 2A, 2B, ... and the second repeaters 3, 3A, 3B, ... are amplitude and sideband modulation. As shown here as a block diagram, a high frequency amplifier 31 for amplifying a received signal of the antenna ANT31 and a frequency converter for mixing a local oscillation signal with an output signal of the high frequency amplifier 31 and converting it into an intermediate frequency signal. (32), an intermediate frequency amplifier (33) for intermediate frequency amplification of the output signal of the frequency converter (32), and a detector (34) for detecting a transmission signal from the output signal of the intermediate frequency amplifier (33) and outputting it to a transmitter. ), A mixer for inverting the detection signal of the detector 34, and a mixer for removing an audio signal by mixing the output signal of the inverter 35 and the output signal of the intermediate frequency amplifier 33. (36), a limiting amplifier (37) for amplifying the output signal of the mixer (36), and the limiting amplifier An intermediate frequency divider 38 for dividing the output signal of (37), a reference oscillator 39 for generating a reference signal by oscillating the reference oscillator 39A, and for dividing an oscillation signal of the reference oscillator 39; A fixed divider 40 and a variable divider 41 which variably divides the output signal of the fixed divider 40 according to a broadcasting scheme to match the frequency of the output signal of the intermediate frequency divider 38; Oscillation of the reference oscillator 39 by filtering the phase comparator 42 comparing the phases of the output signals of the intermediate frequency divider 38 and the variable divider 41 and the phase difference signal of the phase comparator 42. A PLL type local oscillator 44 which generates a local oscillation signal and applies it to the frequency converter 32 in synchronization using a low pass filter 43 for adjusting a signal and an oscillation signal of the reference oscillator 39 as a reference signal. And synchronously transmit using the oscillation signal of the reference oscillator 39 as a reference signal. It was composed of a transmission oscillator (45) for generating an oscillation signal transmission.

According to the present invention configured as described above, the intermediate frequency signal output from the intermediate frequency amplifier 33 as shown in FIG. 5 (a) is input to the modulator 36 and also to the detector 34 to be connected to FIG. The transmission signal is detected as shown in Fig. 2), and the detected transmission signal is inverted as shown in (c) of FIG. 5 in the inverter 35 and input to the mixer 36.

The mixer 36 then mixes the output signals of the intermediate frequency amplifier 33 and the inverter 35 to output a signal from which the audio signal has been removed as shown in FIG. 5 (d), and the output signal is limited. In the amplifier 37, the amplitude is limited amplified as shown in (e) of FIG. 5, and is divided in the intermediate frequency divider 38 as shown in (f) of FIG. 5 and input to the phase comparator 42. do.

The oscillator 39A of the reference oscillator 39 oscillates to output an oscillation signal, and the fixed oscillator 40 divides the output oscillation signal as shown in FIG. 41 is divided and input to the phase comparator 42 according to the broadcast mode selection signal as shown in FIG.

The phase comparator 42 then compares the phases of the output signals of the intermediate frequency divider 38 and the variable frequency divider 41 and outputs the phase difference signals as shown in FIG. 5 (i) (j) according to the phase difference. The output phase difference signal is filtered by the low pass filter 43 and then input to the reference oscillator 39 to accurately synchronize the oscillation signal of the reference oscillator 39 to the received signal received by the high frequency amplifier 11.

In this way, the oscillation signal output by the reference oscillator 39 in synchronization with the received signal is input to the PLL type local oscillator 44 and the PLL type oscillator 45 as a reference signal and synchronized with the received signal. Signals are generated separately, and the generated local oscillation signals are input to the frequency converter 32 and used to convert the received signals of the high frequency amplifier 31 into intermediate frequency signals. The transmission oscillation signals are input to the transmitter and synchronized with the transmission oscillation signals. Generates a transmission carrier signal and modulates and transmits the transmission signal.

Here, since the amplitude and sideband modulation method has no frequency shift unlike the frequency modulation method, the division value of the intermediate frequency divider 38 is set to the common factor and the common multiple of the oscillation frequency of the intermediate frequency and the reference oscillator 39.

As described in detail above, the present invention adjusts the oscillation frequency of the oscillator in synchronization with the reception signal frequency of each repeater to synchronize the oscillation frequency of the repeater with the oscillation frequency of the home transmitter so that each repeater can transmit the same frequency. It can reduce the use of frequency and stabilize the oscillation frequency without installing a separate automatic frequency regulator and thermostat in the dynamometer.

Claims (4)

Receives a mother station transmitter 1 for modulating and transmits a transmission signal at a first frequency F1, and a signal at a first frequency F1 transmitted by the mother station timing unit 1 and transmits a signal of the first frequency F1. A first repeater (2, 2A, 2B, ...) for generating a second frequency (F2) in synchronization with the signal and relaying the transmission signal; and the first repeater (2, 2A, 2B, ...) Repeaters (3, 3A, 3B) for receiving the signal of the second frequency (F2) transmitted by the controller and generating the first frequency (F1) in synchronization with the signal of the second frequency (F2) to relay the transmission signal. Wireless repeater, characterized in that consisting of ...). 2. The high frequency amplifier of claim 1, wherein the first repeaters (2, 2A, 2B, ...) and the second repeaters (3, 3A, 3B, ...) amplify the received signal of the antenna ANT11. (11), a frequency converter (12) for mixing a local oscillation signal to an intermediate frequency signal by mixing a local oscillation signal with the output signal of the high frequency amplifier (11), and an intermediate frequency for intermediately amplifying the output signal of the frequency converter (12). An amplifier 13, a detector 14 for detecting a transmission signal from the output signal of the intermediate frequency amplifier 13 and outputting the signal to a transmitter, and a limiting amplifier 15 for amplifying the output signal of the intermediate frequency amplifier 13; And an intermediate frequency divider 16 for dividing the output signal of the limited amplifier 15, a reference oscillator 17 for generating a reference signal, and a fixed divider for dividing an oscillation signal of the reference oscillator 17. (18) and the frequency division of the output signal of the fixed frequency divider (18) by varying the frequency of the output signal of the intermediate frequency divider (16). The phase difference signal of the phase comparator 20 and the phase comparator 20 comparing the phases of the output signal of the intermediate frequency divider 16 and the variable frequency divider 19 to match, The low frequency filter 21 which controls the oscillation signal of the mood oscillator 17 and the oscillation signal of the reference oscillator 17 as a reference signal generates a local oscillation signal in synchronization and generates the frequency converter 12. And a PLL type oscillator 23 which outputs the transmission oscillation signal of the transmitter synchronously using the PLL type local oscillator 22 to be supplied to the reference oscillation signal and the oscillation signal of the reference oscillator 17 as a reference signal. Wireless repeater. 3. The radio repeater according to claim 2, wherein the division value of the intermediate frequency divider 16 is equal to or greater than the frequency shift value of the received signal and is set to the common factor and common multiple of the intermediate frequency and the oscillation frequency of the reference oscillator 17. . 2. The high frequency amplifier (31) of claim 1, wherein the first repeaters (2, 2A, 2B, ...) and the second repeaters (3, 3A, 3B, ...) amplify the received signal of the antenna ANT31. ), A frequency converter 32 for mixing a local oscillation signal with the output signal of the high frequency amplifier 31 and converting it into an intermediate frequency signal, and an intermediate frequency amplifier for intermediately amplifying the output signal of the frequency converter 32 ( 33), a detector 34 for detecting a transmission signal from the output signal of the intermediate frequency amplifier 33 and outputting it to a transmitter, an inverter 35 for inverting the detection hole of the detector 34, and the inverter A mixer (36) for mixing the output signal of (33) and the output signal of the intermediate frequency amplifier (33) to remove the audio signal, a limiting amplifier (37) for amplifying the output signal of the mixer (36), and A reference signal is generated by oscillating the intermediate frequency divider 38 which divides the output signal of the limiting amplifier 37 and the oscillator 39A. A variable frequency divider of the reference oscillator 39, the fixed frequency divider 40 for dividing the oscillation signal of the reference oscillator 39, and the output signal of the fixed frequency divider 40 are variably distributed to the intermediate frequency divider 38. A variable comparator 41 matching the frequency of the output signal, a phase comparator 42 for comparing the phases of the output signals of the intermediate frequency divider 38 and the variable divider 41, and the phase comparator 42 A low pass filter 43 for controlling the oscillation signal of the reference oscillator 39 by filtering a phase difference signal of the second oscillator, and generating a local oscillation signal using the oscillation signal of the reference oscillator 39 as a reference signal. And a local oscillator 44 applied to (32), and a transmission oscillator 45 for outputting a transmission oscillation signal of the transmitter using the oscillation signal of the reference oscillator 39 as a reference signal. Device.

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