JP2010252064A - Wireless microphone system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To make analog and digital microphones coexist in one system by modulating a digital signal in the vicinity of an analog signal. <P>SOLUTION: A wireless microphone system is equipped with: a plurality of coaxial cables 2 connected at a mixing side of a high frequency mix distributor 11; an analog antenna unit 4a or a digital antenna unit 4d, connected to any one of the coaxial cables 2; and an analog receiver 3a or a digital receiver 3d, connected on the distributing side of the high frequency mix distributor 11. The digital antenna unit 4d has: a high frequency amplifier 42; a frequency conversion circuit 43; and a reference frequency detector 45. The high frequency mix distributor 11 includes a reference frequency oscillation circuit 15 for transmitting a reference frequency signal to each coaxial cable 2. In the digital antenna unit 4d, a high frequency signal amplified by the high frequency amplifier 42 is converted into a frequency of the same band as an output signal from the analog antenna unit 4a on the basis of the received reference frequency. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a wireless microphone system for use in stations, broadcasting stations, schools, theaters, broadcasting, and the like, and particularly relates to a system suitable when analog wireless microphones and digital wireless microphones are mixed.

  There are two known wireless microphone systems, digital and analog, but recently there is a tendency to replace existing analog systems with digital ones. In this case, in a large-scale system, the entire system cannot be changed at a time, and both analog and digital systems are mixed. For example, Patent Document 1 discloses a system having a plurality of receiver bodies and a large number of antennas connected thereto. However, only a part of the plurality of receiver bodies is replaced with a digital receiver. The analog receiver and the replaced digital receiver are used together.

  However, when these two analog and digital systems are used in combination, there are the following problems. Generally, the receiver body and the antenna are connected via a coaxial cable, a line compensator, or the like. In this case, since analog and digital use frequencies with different bandwidths, transmission losses are different. Therefore, line design must be performed for each, and the respective coaxial cables must be laid and connected. As a result, when the analog system is replaced with the digital system, it is necessary not only to replace the antenna and the receiver body, but also to replace the coaxial cable that connects them.

  However, in wireless microphones used in large places such as station premises, the distance between the antenna and the receiver is long, and the coaxial cable is also long, so the existing coaxial cable has been removed and a new digital cable Laying down is difficult to work. Therefore, it is convenient if the existing analog cable can be diverted to the digital system for the coaxial cable connecting the antenna and the receiver body.

  On the other hand, in a digital wireless microphone, after the signal received by the antenna is converted by a high frequency amplifier, the signal from the high frequency amplifier and the oscillation frequency (reference frequency) from the oscillator are mixed and converted to an intermediate frequency. Yes. As shown in Patent Document 2, the intermediate frequency conversion oscillator is provided on the receiver body or the antenna side. However, an analog wireless microphone does not require such a reference frequency. Therefore, when the analog and digital receivers are used in combination, it is necessary to consider how the reference frequency is supplied to the digital intermediate frequency amplifier.

Japanese Patent Publication No. 7-50955 Japanese Patent Publication No.8-10845

  However, the inventions of Patent Document 1 and Patent Document 2 do not use both analog and digital systems. For this reason, it has not been possible to solve the problems of sharing the coaxial cable and supplying the reference frequency.

  The present invention has been proposed to solve the above-described problems of the prior art. The object of the present invention is that the coaxial cable can be shared by both analog and digital systems, and even when a digital antenna unit is connected to the coaxial cable, the reference frequency for frequency conversion is placed on the digital antenna unit side. It is to provide a wireless microphone system that can be supplied.

  In order to achieve the above object, the present invention provides a plurality of coaxial cables connected to a mixing side of a high-frequency mixer / distributor, an analog antenna unit or a digital antenna unit connected to any one of these coaxial cables, An analog receiver or a digital receiver connected to the distribution side of the high-frequency mixing distributor. Each antenna unit is connected to a receiving antenna. The analog antenna unit has a high frequency amplifier. The digital antenna unit includes a high frequency amplifier, a frequency conversion circuit, and a reference frequency detection unit. The high-frequency mixer / distributor has a reference frequency oscillation circuit that transmits a reference frequency signal to each coaxial cable.

  In the present invention, an analog or digital line compensator can be provided on the coaxial cable. In this case, the digital line compensator is provided with a filter that passes the reference frequency signal from the high frequency mixing / distributing device to the antenna unit side. The high frequency amplifier is not necessarily provided in each unit or line compensator.

  In the wireless microphone system of the present invention having the above-described configuration, a reference frequency signal is output from the high-frequency mixer / distributor to each coaxial cable. Therefore, in the digital antenna unit connected to the tip of the coaxial cable, frequency conversion is performed based on the reference frequency signal received from the high frequency mixer / distributor and the high frequency signal from the high frequency amplifier in the unit, and output from the analog antenna unit. The signal of the same frequency band as the frequency to be output is output. As a result, regardless of whether the antenna unit connected to the coaxial cable is an analog system or a digital system, signals in the same frequency band flow through the coaxial cable, and both systems can share the coaxial cable.

1 is a block diagram showing the overall configuration of Embodiment 1 of the present invention. FIG. 2 is a block diagram illustrating a configuration of a digital antenna unit according to the first embodiment. FIG. 2 is a block diagram illustrating a configuration of an analog antenna unit according to the first embodiment. FIG. 3 is a block diagram illustrating a configuration of a digital line compensator according to the first embodiment. FIG. 2 is a block diagram illustrating a configuration of an analog line compensator according to the first embodiment. 1 is a block diagram showing a configuration of a high-frequency mixing / distributing device in Embodiment 1. FIG.

Embodiment 1 of the present invention will be specifically described below with reference to FIGS.
In FIG. 1, reference numeral 1 denotes a high-frequency mixer / distributor unit that is the core of the wireless microphone system of the present invention. A plurality of receivers are connected to the output side (distribution side) of the high-frequency mixer / distributor unit 1 through the coaxial cable 2. In FIG. 1, as an example, one digital wireless receiver 3d and one analog wireless receiver 3a are connected, but the number is not limited.

  A plurality of antenna units 4 are connected to the input side (mixing side) of the high-frequency mixer / distributor unit 1 via a coaxial cable 2. As this antenna unit 4, two types of a digital antenna unit 4d and an analog antenna unit 4a are prepared in accordance with the receiver system to be used. A line compensator 6 is provided on the coaxial cable 2 connecting the high-frequency mixer / distributor unit 1 and each antenna unit 4. As this line compensator 6, two types of line compensator 6 d for digital and line compensator 6 a for analog are prepared according to the type of antenna unit 4 connected to the coaxial cable 2.

  As shown in FIG. 2, the digital antenna unit 4 d is connected to a receiving antenna 41. The digital antenna unit 4 d includes a high frequency amplifier 42, a frequency conversion circuit 43, a connector 44, a reference frequency detection unit 45, and a local amplifier 46. The receiving antenna 41 receives radio waves from the digital wireless microphone 5d. The high frequency amplifier 42 amplifies the signal received by the antenna 41. The frequency conversion circuit 43 converts the high frequency signal amplified by the high frequency amplifier 42 to a frequency in the same band as the output signal from the analog antenna unit 4a based on the reference frequency received from the high frequency mixing / distributing unit 1.

  The connector 44 outputs a signal from the frequency conversion circuit 43 to the coaxial cable 2. The reference frequency detection unit 45 detects a reference frequency signal transmitted from the high-frequency mixer / distributor unit 1 through the coaxial cable 2 and outputs the signal to the local amplifier 46. The local amplifier 46 has a multiplication circuit that amplifies the reference frequency from the reference frequency detection unit 45, amplifies the reference frequency signal, and outputs the amplified signal to the frequency conversion circuit 43.

  As shown in FIG. 3, the analog antenna unit 4 a is connected to the receiving antenna 41. The analog antenna unit 4 a includes a high frequency amplifier 42 and a connector 44. The high-frequency amplifier 42 outputs a frequency in the same band as the signal output from the frequency conversion circuit 43 of the digital antenna unit 4d.

  As shown in FIG. 4, a digital line compensator 6d disposed on the coaxial cable 2 includes a high-frequency amplifier 61 that amplifies a received signal from an antenna, and antenna-side connectors connected to both sides of the high-frequency amplifier 61. 62 and a connector 63 on the high frequency mixer / distributor unit 1 side. A reference frequency filter 64 is provided in parallel with the high frequency amplifier 61. This filter 64 bypasses the high frequency amplifier 61 and transmits the reference frequency signal transmitted from the high frequency mixing / distributing unit 1 to the antenna side. Since only the reference frequency is passed, the received signal from the antenna flows through the high frequency amplifier 61 and is amplified there.

  As shown in FIG. 5, the analog line compensator 6 a disposed in the coaxial cable 2 includes a high-frequency amplifier 61 that amplifies a received signal from the antenna, and antenna-side connectors connected to both sides of the high-frequency amplifier 61. 62 and a connector 63 on the high frequency mixer / distributor unit 1 side.

  As shown in FIG. 6, the high-frequency mixer / distributor unit 1 includes a high-frequency mixer / distributor 11, a plurality of antenna connectors 12 provided on the input side (mixing side), and an output side (distribution side). A receiver-side connector 13 is provided. A high-frequency amplifier 14 that amplifies a signal input from each connector 12 is provided between the high-frequency mixer / distributor 11 and each antenna connector 12. A reference frequency oscillation circuit 15 is provided in the high-frequency mixer / distributor unit 1. The output of the reference frequency oscillation circuit 15 is connected to each connector 12 for an antenna, and the reference frequency signal output from the reference frequency oscillation circuit 15 is transmitted to each antenna unit 4 via the connector 12 and the coaxial cable 2. .

  In the first embodiment having the above-described configuration, the reference frequency signal from the high-frequency mixer / distributor unit 1 is received via the antenna connector 12, the coaxial cable 2, and the line compensator 6 provided in the unit 1. Can be sent to unit 4. In this case, when the existing analog receiver 3a and the antenna unit 4a are connected to the high-frequency mixer / distributor unit 1, the reference frequency signal from the high-frequency mixer / distributor unit 1 is sent to the analog line compensator 5a. It is blocked and does not reach the analog antenna unit 4a. Further, when the line compensator 5a is not provided, even if the reference frequency signal reaches the analog antenna unit 4a, a problem arises because the analog antenna unit 4a has no circuit for processing the reference frequency signal. Absent.

  On the other hand, when the digital receiver 3d and the digital antenna unit 4d are connected to the high-frequency mixer / distributor unit 1 due to equipment update or the like, the reference frequency signal from the high-frequency mixer / distributor unit 1 is a digital line. The compensator 5d passes through the filter 64 and reaches the digital antenna unit 4d. As a result, the digital antenna unit 4d can convert the high frequency signal amplified by the high frequency amplifier 42 to a frequency in the same band as the output signal from the analog antenna unit 4a based on the received reference frequency.

  As described above, according to the first embodiment, the reference frequency signal is transmitted from the high-frequency mixer / distributor unit 1 to each antenna through the coaxial cable 2, and when the antenna is a digital system, from the antenna unit based on the reference frequency signal. The output signal band can be the same as the output signal from the analog antenna unit. As a result, output signals in the same band will flow through the coaxial cable 2 regardless of whether the reception method is analog or digital, so there is no need to design a dedicated line for each reception method, and existing analog coaxial cables are used as they are. Thus, a digital wireless microphone system can be constructed. In particular, the circuit design dedicated to each system is not required, and the coaxial cable can be shared. Therefore, both analog and digital systems can be mixed in the same system, and the system can be easily migrated.

The present invention is not limited to the embodiment described above, and includes other embodiments as follows.
(1) The high-frequency amplifier provided in each antenna unit 4, high-frequency mixer / distributor unit 1, or line compensator 6 is not necessarily provided in that portion, and may be appropriately arranged according to the strength of the signal to be communicated. it can.
(2) The line compensators 6a and 6d on the coaxial cable 2 connecting the antenna unit 4 and the high-frequency mixer / distributor unit 1 can be appropriately arranged according to the line design, or can be omitted at all.

DESCRIPTION OF SYMBOLS 1 ... High frequency mixer / distributor unit 2 ... Coaxial cable 3d ... Digital wireless receiver 3a ... Analog wireless receiver 4d ... Digital antenna unit 4a ... Analog antenna unit 5d ... Digital wireless microphone 5a ... Analog wireless microphone 6d ... Digital line compensator 6a ... analog line compensator 15 ... reference frequency oscillation circuit 43 ... frequency conversion circuit 45 ... reference frequency detector 64 ... filter

Claims (3)

A plurality of coaxial cables connected to the mixing side of the high-frequency mixing distributor;
An analog receiving antenna or a digital receiving antenna connected to any of these coaxial cables;
An analog receiver or a digital receiver connected to the distribution side of the high-frequency mixing distributor;
A frequency conversion circuit and a reference frequency detection unit are connected to the digital reception antenna,
The high-frequency mixer / distributor is provided with a reference frequency oscillation circuit that transmits a reference frequency signal for each coaxial cable,
Using the reference frequency received from the high-frequency mixer / distributor, the frequency conversion circuit and the reference frequency detection unit allow the signal received by the digital reception antenna to have a frequency in the same band as the output signal from the analog reception antenna to the coaxial cable. A wireless microphone system that converts and outputs to a coaxial cable.   The digital and analog reception antennas are configured as a unit having a high frequency amplifier for amplifying a reception signal from the reception antenna, and the digital antenna unit includes an output signal from the high frequency amplifier in the same band as the output signal from the analog antenna unit. 2. The wireless microphone system according to claim 1, wherein the frequency conversion circuit and a reference frequency detection unit are provided to convert the signal into the following signal.   A line compensator is provided in the coaxial cable connecting the antenna and the high-frequency mixer / distributor, and the digital line compensator connecting the digital reception antenna includes a high-frequency amplifier that amplifies a received signal and a high-frequency mixer / distributor. The wireless microphone system according to claim 1, wherein filters that pass only the reference frequency signal are connected in parallel.

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