JPH0630477B2 - Optical transmission device - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an optical transmission device for converting a video signal into an optical signal and performing spatial transmission.

[Prior art]

When transmitting analog signals consisting of video signals, audio signals, etc. on radio waves for spatial transmission, if a wide frequency range is divided into multiple channels and multiple receivers are set to receive channels, each channel can be set individually. By transmitting an analog signal as needed, the receiver can be appropriately selected on the transmitting side to output the content of the signal.

However, when using light as a carrier wave, at present,
Since the usable frequency range is limited due to the characteristics of the light emitting / receiving element, the frequency range of the carrier cannot be divided into a plurality of channels. Therefore, in the conventional optical transmission system, when converting an analog signal into an optical signal and transmitting it, it is impossible to configure a system in which the receiver selects the receiver and outputs the content of the signal. there were.

[Object of the Invention]

The present invention has been made in consideration of the above problems, and selects a receiver on the transmission side by converting an address signal into an optical signal together with a video signal output by the receiver and transmitting the optical signal. It is an object of the present invention to provide an optical transmission device that can output the contents of a video signal.

[Structure of Invention]

In order to achieve the above object, an optical transmission device according to the present invention includes a transmitter that converts a video signal into an optical signal so that the video signal is spatially transmitted, and a plurality of receivers that convert the optical signal into a video signal. And a transmitter for providing a video signal FM modulating means for FM-modulating a video signal with a carrier wave, a designated address signal generating means for generating a signal of a designated address, and a carrier wave of a frequency different from that of the carrier wave on which the video signal is modulated. An address signal FM modulating means for FM-modulating the address signal generated by the designated address signal generating means on a carrier wave, an adding means for adding the signals modulated by the video signal FM modulating means and the address signal FM modulating means, and an optical signal. And a light modulating light emitting means for emitting light by modulating the carrier wave of the light with the signal added by the adding means, and the receiving unit receives the light sent from the transmitting unit. A light receiving demodulating means for light demodulating a frequency separating means for separating a signal demodulated by the receiving demodulation means for each carrier for each frequency, the video signal F for FM demodulating the video signals from the separated signals in the frequency separation means
M demodulation means, address signal FM demodulation means for FM demodulating an address signal from the signal separated by the frequency separation means, set address signal generation means for generating a signal of a set address, and this set address signal generation means Address comparing means for comparing the address signal generated in step 1 with the address signal separated by the frequency separating means, and a video for preventing output of the video signal when the address comparing means determines that these addresses do not match. A signal output blocking means is provided, and by designating an address on the transmitting side, the video signal can be output only on the receiving side that has set the same address as the designated address. It is what

〔Example〕

An embodiment of the present invention will be described below with reference to FIGS. 1 to 4.

As shown in FIG. 1, the transmitter 1 as a transmitter is provided with input terminals 2.2.2 for inputting left and right audio signals and video signals as analog signals. Each input terminal 2 is connected to each analog signal FM demodulator 4, 4, 4 of the analog signal modulating means 3, respectively. Further, the transmitter 1 is provided with a designated address signal generating means 5 for appropriately designating an analog and outputting an analog signal corresponding to the analog, and is connected to an FM modulator 6 for an address signal as an address signal modulating means. ing. The analog signal FM modulator 4 and the address signal FM modulator 6 are set with different carrier frequencies so that the frequency bands of the output signals do not overlap. The output signal of each of the analog signal FM modulator 4 and the address signal FM modulator 6 is input to the adding means 7, added, and sent to the light modulation light emitting means 8.
The light modulating light emitting means 8 converts the electric signal from the adding means 7 input to the light emitting element drive circuit 9 such as a wide band video amplifier into an optical signal by the light emitting element 10, that is, converts the carrier wave of light into electric power from the adding means 7. It is configured to emit light after being modulated with a signal.

A plurality of receivers 11 as receivers are arranged in the system, and as shown in FIG. 2, light receiving and demodulating means 12 for receiving an optical signal from the light emitting element 10 of the transmitter 1 are provided. The light receiving and demodulating means 12 receives an optical signal by the light receiving element 13 and converts it into an electric signal through the amplifier 14.
That is, it is configured to demodulate. Further, the light receiving and demodulating means 12 is designed so that the output signal is sent to the frequency separating means 15. The frequency separation means 15 includes four types of bandpass filters that pass only the frequency bands of the left and right FM-modulated audio signals, video signals, and address signals.
.. 16 so that the output signal from the light receiving and demodulating means 12 is separated for each frequency band and output. These bandpass filters 16
The band pass filter 1 that transmits the frequency band of the left and right FM-modulated audio and video signals out of 16
6. 16 and 16 are connected to the analog signal FM demodulators 18, 18 and 18 of the analog signal demodulating means 17, respectively. Further, the bandpass filter 16 that transmits the frequency band of the FM-modulated address signal is connected to the FM demodulator 19 for address signal as an address signal demodulating means. The FM demodulator 18 for analog signals
18, 18 is an output terminal 20 provided in the receiver 11.
20 and 20 are connected to each other so that left and right audio signals and video signals can be output. The FM demodulator for address signal 19 is connected to the address comparing means 21, and the demodulated address signal is supplied to the address comparing means 21.
It is designed to be sent to. Also, this receiver 11 has
A set address signal generating means 22 for setting an address and outputting an address signal corresponding thereto is provided, and the address signal generated here is also sent to the address comparing means 21. The address comparison means 21 compares the two received address signals, and when they do not match, sends a control signal to the analog signal FM demodulators 18, 18, 18 of the analog signal demodulation means 17, respectively. It is like this. The analog signal FM demodulators 18, 18 and 18 are each provided with a mute mechanism 23 so that when the control signal is sent from the address comparison means 21, the output of the demodulated analog signal is stopped.

In the above configuration, the left and right audio signals and video signals input to the transmitter 1 are FM-modulated by the analog signal modulator 3, respectively. Further, the address signal generated by the designated address signal generating means 5 is also the FM modulator 6 for the address signal.
Is FM-modulated by. In this case, if AM modulation is adopted,
Although the bandwidth can be reduced, there are problems in securing the S / N ratio and in the linearity of the characteristics of the light emitting element 10 and the light receiving element 13. However, in the case of FM modulation, the S / N ratio is good and the linearity of the element does not matter, and if the limiter of the FM demodulation circuit is within the effective range, the influence of the transmission / reception system such as indoor reflection is small. , Does not require much bandwidth. Therefore, the FM modulation is adopted in the embodiment. The frequency allocation of each signal is as follows.

* Audio signal (20Hz ~ 20kHz) Deviation 200kHz Maximum frequency of input signal 20kHz Modulation index 10 Carrier frequency (right) 2MHz Carrier frequency (left) 2.5MHz * Video signal (0-4.2MHz) Deviation 1.7MHz Input signal Maximum frequency 4.2MHz Modulation index 0.4 Carrier frequency 7.6MHz * Address signal deviation 50kHz 1: + 25kHz 0: -25kHz Carrier frequency 1.5MHz Data rate 1kbit / sec Data modulation method Biphase FM modulated in this way As shown in FIG. 3, the frequency bands of the signals do not overlap with each other, and the signals are added by the adding means 7.

As shown in FIG. 4, the address signal generated by the designated address signal generating means 5 is a bit composed of a synchronizing part corresponding to 3 bits, an address part of 4 bits and a spare part of 4 bits × 3. It is a composition. Since the address part is composed of 4 bits, a maximum of 16 types of addresses can be designated and set. When specifying multiple addresses at the same time, specify the first address in the first block and the second address in the next block. Good. In this case, the repetition cycle of the same address is every 16 blocks at maximum.

The electric signal output from the adding means 7 is the light modulation light emitting means 8
Is converted into an optical signal by the light emitting element 10, and the light emitting element 10 emits the optical signal toward each receiver 11.

The optical signal emitted from the transmitter 1 is received by the light receiving element 13 of the light receiving and demodulating means 12 of the receiver 11, converted into an electric signal again, and separated by the frequency separating means 15 for each frequency band. Then, the analog signal demodulation means 17 performs FM demodulation and outputs the left and right audio signals and video signals from the output terminals 20, 20 and 20, respectively.

However, the address signal demodulated by the FM demodulator for address signal 19 is sent to the address comparison means 21, and the set address signal generation means 2 is set in advance for each receiver 11.
2 is compared with the address signal from 2. If these addresses do not match, the address comparison means 21
From the analog signal FM demodulator 18, the mute mechanism 23 operates to block the output of the analog signal FM demodulator 18. Therefore, the receiver 11 outputs the video signal only when the receiver 11 is set to the same address as the address specified on the transmitter 1 side.

In the embodiment, the mute mechanism 23 of the FM demodulator for analog signal 18 is used as the analog signal output blocking means, but it is not limited to such a configuration as long as the receiving side can block the output of the analog signal. Of course.

[Structure of Invention]

As described above, the optical transmission device according to the present invention includes a transmitter that converts a video signal into an optical signal for spatially transmitting the video signal, and a plurality of receivers that convert the optical signal into a video signal, The transmitting unit specifies the video signal FM modulating means for FM-modulating the video signal with a carrier, the designated address signal generating means for generating a signal of a designated address, and the carrier with a frequency different from the carrier on which the video signal is modulated. The address signal FM modulating means for FM-modulating the address signal generated by the address signal generating means, the adding means for adding the signals modulated by the video signal FM modulating means and the address signal FM modulating means, and the optical carrier And light modulating light emitting means for emitting light by modulating with the signal added by the adding means, and each receiving section receives the light sent from the transmitting section. Light receiving and demodulating means for performing demodulation, frequency separating means for separating the signal demodulated by the light receiving and demodulating means for each carrier wave of each frequency, and video signal FM demodulating means for demodulating a video signal from the signal separated by the frequency separating means. And an address signal FM demodulation means for FM demodulating an address signal from the signal separated by the frequency separation means,
Setting address signal generating means for generating a unique address signal in each receiving section, address comparing means for comparing the address signal generated by the setting address signal generating means with the address signal separated by the frequency separating means, and this address The video signal output blocking means for blocking the output of the video signal when the comparison means determines that these addresses do not match.

As a result, when an address is appropriately designated on the transmitting side, the video signal is output only on the receiving side to which the same address as the designated address is set. For this reason, the receiver or the like for receiving the signal can be freely selected on the transmitting side, so that it is possible to configure a complicated transmission system even in the case of optical transmission. Further, since the address signal is FM-modulated, the processing of modulation and demodulation can be performed in the same manner as the video signal, and the configuration can be simplified.

[Brief description of drawings]

1 to 4 show an embodiment of the present invention. FIG. 1 is a block diagram showing a circuit of a transmitter, FIG. 2 is a block diagram showing a circuit of a receiver, and FIG. Is a frequency spectrum of each FM-modulated signal, and FIG. 4 is an explanatory diagram showing a bit configuration of an address signal. 1 is a transmitter (transmission unit), 3 is an analog signal modulating means, 4
Is an analog signal FM modulator, 5 is a designated address signal generating means, 6 is an address signal FM modulator (address signal FM modulating means), 7 is adding means, 8 is light modulating light emitting means,
Reference numeral 10 is a light emitting element, 11 is a receiver (reception unit), 12 is light receiving and demodulating means, 13 is a light receiving element, 15 is frequency separating means, 1
Reference numeral 6 is a bandpass filter, 17 is an analog signal demodulating means, 18 is an analog signal FM demodulator, 19 is an address signal FM demodulator (address signal FM demodulating means), 21.
Is an address comparing means, 22 is a set address signal generating means, and 23 is a mute mechanism (video signal output blocking means).

Claims (1)

[Claims] 1. A transmission unit for converting a video signal into an optical signal for spatially transmitting the video signal, and a plurality of reception units for converting the optical signal into a video signal, wherein the transmission unit uses the carrier wave for the video signal. FM modulating video signal FM modulating means, designated address signal generating means for generating a signal at a designated address, and address signal generated by the designated address signal generating means on a carrier wave having a frequency different from the carrier wave on which the video signal is modulated. Address signal FM modulating means for performing FM modulation of the signal, addition means for adding the signals modulated by the video signal FM modulating means and the address signal FM modulating means, and an optical carrier wave is modulated by the signal added by the adding means. The light receiving and demodulating means for receiving and demodulating the light sent from the transmitting portion, and the light receiving and restoring means. A frequency separation means for separating a signal demodulated by means for each carrier for each frequency, the video signal from the separated signals in the frequency separation means FM
Video signal FM demodulation means for demodulation, address signal FM demodulation means for FM demodulating an address signal from the signal separated by the frequency separation means, set address signal generation means for generating a signal of a set address, and this setting Address comparing means for comparing the address signal generated by the address signal generating means with the address signal separated by the frequency separating means, and outputting a video signal when the address comparing means judges that these addresses do not match. An optical transmission apparatus comprising: