KR19980014474A - Radio wave detection device (BEACON) - Google Patents

Abstract

Discloses a radio wave detection apparatus capable of stabilizing the entire operation in spite of the failure of some components. The apparatus includes a transmitting and receiving antenna, first and second transmitting sections for radiating a first super-frequency signal, and a second transmitting section for receiving the first super-frequency signal from either the first or second transmitting section in response to the first selecting signal, A first controller for generating the first selection signal in response to a first alternate command signal and generating an enable signal for the first and second transmission units, A second receiving section for receiving a second super-frequency signal and for selectively outputting the second super-frequency signal received by the receiving antenna to the first or second receiving section in response to a second selecting signal, And a second controller for generating the second selection signal in response to the second alternate command signal and generating an enable signal for the first and second transmission units.

Description

Radio wave detection device (BEACON)

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio wave detecting apparatus (BEACON), and relates to a radio wave detecting apparatus capable of stable operation of the entire system despite the unstable operation of some components.

Generally, a signal emitted from a transmitter of a radio wave detecting device is transmitted to a transponder having the same communication component, transmitted through a transmitting antenna, with promised information, and the counterpart communication device transmits a signal Information is transmitted to the receiver of the radio wave detecting device so that mutual communication can be performed. However, the conventional radio wave detecting apparatus is composed of one independent transmitting unit and a receiving unit. In such a radio wave sensor, a failure of some transmitting or receiving parts may cause paralysis of the entire system.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a subwoofer sensing apparatus capable of performing stable operation even if some components fail in order to solve the above-mentioned conventional problems.

1A and 1B illustrate a transmitting unit and a receiving unit of a general radio wave detecting apparatus.

2 is a block diagram for explaining a radio wave detecting apparatus according to the present invention.

According to an aspect of the present invention, there is provided a radio wave detecting apparatus comprising: a transmitting and receiving antenna; First and second transmitters for radiating a first super-frequency signal; A first switching unit for selecting the first super frequency signal from any one of the first and second transmission units in response to a first selection signal and outputting the selected first super frequency signal to the transmission antenna; A first control unit for generating the first selection signal in response to a first alternate command signal and generating an enable signal for the first and second transmission units; First and second receivers for receiving a second super-frequency signal; A second switching unit for selectively outputting the second super-frequency signal received by the receiving antenna to the first or second receiving unit in response to a second selection signal; And a second control unit for generating the second selection signal in response to the second alternate command signal and generating an enable signal for the first and second transmission units.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First, to facilitate understanding of the present invention, a transmitter and a receiver of a conventional radio wave detecting apparatus will be described with reference to FIGS. 1A to 1B.

1A and 1B are block diagrams of a transmitter and a receiver of a conventional radio wave detecting apparatus. Reference numeral 1 denotes a carrier frequency generator, 3 denotes a divider, 5 and 9 denote amplifiers, 7 denotes an RF 11 is an isolator, 13 is a transmitting antenna, 15 is an E / O converting unit, 17 is an intermediate frequency (IF) amplifying unit, 19 and 25 are hybrid dividers, 22 is a divider, 27 is a limiter, 29 is an amplifier, 31 is a directional coupler, and 33 is a receiving antenna.

First, the carrier frequency generated in the carrier frequency generator 1 is divided through the divider 3 and input to the amplifier 5 and the divider 22 of the receiver. The carrier frequency inputted to the amplifying unit 5 is amplified at a predetermined gain factor, and then inputted to the RF switching unit 7 and the switching operation is performed according to the ASK-MOD signal to generate an ASK (amplitude shifting keying) signal. Amplified by the amplifying unit 9 to amplify the attenuated power through the switching operation, and then inputted to the isolator 11 having the unidirectional transmission characteristic. The signal that has passed through the isolator 11 is radiated to the air through the transmission antenna 13.

The signal received through the receiving antenna 33 is transmitted to the amplifying unit 29 through the isolator 31 in a unidirectional manner. The transmitted signal is attenuated through the amplifying unit 29 and the normal signal . And is limited to a predetermined level through the limiter 27 in order to cancel excessive amplification by the amplifying unit 29. Subsequently, the hybrid divider 25 shifts the signal passed through the limiter 27 to the synthesizing section 21 by 90 °, and outputs it to the synthesizing section 23 as it is. At this time, the combining units 21 and 23 combine the signal that has passed through the hybrid divider 25 and the signal Rx-LO signal that is output from the divider 3 of the transmitting unit that is divided through the divider 22, respectively. The signal having passed through the combining section 21 is shifted by 90 degrees through the hybrid divider 19 and the signal passing through the combining section 23 passes through the hybrid divider 19 as it is. Then, an intermediate frequency (IF) signal is amplified through the intermediate frequency amplifier 17 and is converted into an optical signal through the E / O converter 15. [

2 is a block diagram for explaining a radio wave detecting apparatus according to the present invention. Reference numerals 40A and 40B denote transmitting units having the same configuration, reference numerals 50A and 50B denote receiving units, Reference numeral 71 denotes an E / O conversion unit. Reference numerals 63 and 73 denote control units 63 for controlling transmission and reception units, respectively. Reference numerals 60 and 70 denote transmission and reception antennas, and reference numerals 65 and 75 denote transmission and reception switching units, respectively. 1A and 1B are denoted by the same reference numerals, and a description thereof will be omitted.

As shown in FIG. 2, in order to prevent paralysis of the entire operation due to a failure of a part of the configuration, as in the conventional radio wave detection apparatus, the present invention is composed of two transmitting and receiving units.

First, the E / O conversion unit 61 converts input data (DATA) and an alternate command signal into optical signals and inputs them to the control unit 63. At this time, the control unit generates a switching signal to the transmission switching unit 65 according to the alternate command signal, and generates an ASK-MOD signal for ASK modulation according to the data. At this time, only the transmitter 40A or 40B selected according to the switching signal receives the ASK-MOD signal. Then, only one of the two transmission units 40A and 40B performs a transmission operation, and the transmission switching unit 65 selectively outputs only the output signal of the transmission unit performing the transmission operation to the transmission antenna 60. [ On the other hand, in the receiver side, the E / O converter 71 converts the alternate command signal into an optical signal and outputs it to the controller 73. In accordance with the alternate command signal converted into the optical signal, And outputs the switching control signal to the receiving units 50A and 50B, so that only one receiving unit receives the power supply through the power supply unit 33. [ That is, one of the two receiving units 40A and 40B is selected through the respective power supply units 33 according to the alternate command signal, and the receiving operation is performed. At this time, the reception switching unit 75 selectively supplies the signal received by the reception antenna 70 to the reception unit in which the reception operation is performed. At this time, there is a difference in selection operation between the transmitter and the receiver. After the power is turned on, the transmitter units 40A and 40B need to warm up for a predetermined time, and the receiver units 50A and 50B do not need a separate warm-up time. Therefore, the transmitting units 40A and 40B are enabled to transmit data by the ASK-MOD signal, and the receiving units 50A and 50B are enabled to receive data according to the power supply.

As described above, according to the present invention, even if some transmission or reception units fail, the entire operation can be stabilized by selectively operating the two transmission units and the reception units.

Claims (1)

Transmit and receive antennas; First and second transmitters for radiating a first super-frequency signal; A first switching unit for selecting the first super frequency signal from any one of the first and second transmission units in response to a first selection signal and outputting the selected first super frequency signal to the transmission antenna; A first control unit for generating the first selection signal in response to a first alternate command signal and generating an enable signal for the first and second transmission units; First and second receivers for receiving a second super-frequency signal; A second switching unit for selectively outputting the second super-frequency signal received by the receiving antenna to the first or second receiving unit in response to a second selection signal; And And a second control unit for generating the second selection signal in response to the second alternate command signal and generating an enable signal for the first and second transmission units.