JP6659245B2 - Transmission device - Google Patents

Description

  Embodiments of the present invention relate to a transmission device.

  In FM (Frequency Modulation) broadcasting, a plurality of transmitting apparatuses may broadcast the same program in order to expand a broadcasting service area. In such a case, if the transmission program broadcasts the program at the same frequency, the transmission waves transmitted from the transmission devices cause mutual interference in the vicinity of the boundary area of the broadcast service area of the plurality of transmission devices. There is. Therefore, when transmitting a transmission wave, each transmission device performs a delay adjustment that delays the time at which the transmission wave is transmitted in accordance with each transmission device, so that an area where mutual interference occurs is located in a mountainous area where almost no people live. There is known a method of adjusting the area to a desired area such as the above.

  As such a method, a method of delaying a time at which a transmission wave is transmitted by delaying an input signal to be input to the transmission device before modulating the transmission signal into a transmission signal, or a method of converting a transmission signal after modulation into a transmission wave There is known a method of delaying at a stage before conversion and transmission. However, in the method of delaying the input signal before it is modulated into the transmission signal, the sampling rate is lower than that of the transmission signal after the modulation of the input signal, and it may be difficult to finely control the delay time. Was. In the method of delaying the modulated transmission signal before transmission, an analog signal is used instead of a digital signal, so that physical costs such as a longer cable are required, and the delay time is frequently reduced. In some cases, it could not be changed.

JP 2012-182585 A

  The problem to be solved by the present invention is to provide a transmission device that can easily and accurately adjust the position of a region where mutual interference of transmission waves occurs.

  The transmission device according to the embodiment includes a storage unit, a delay adjustment unit, and a frequency conversion unit. The storage unit stores an input signal transmitted based on an FM (Frequency Modulation) broadcast standard. The delay adjustment unit controls the timing of reading the input signal from the storage unit and adjusts the delay of the input signal. The frequency conversion unit up-converts the input signal adjusted by the delay adjustment unit.

FIG. 1 is a diagram illustrating an example of a configuration of a transmission device 1 according to an embodiment. 5 is a flowchart showing an example of the flow of processing from the time when the transmission device 1 delays an input signal to the time when it is transmitted as a transmission wave.

Hereinafter, a transmitting device according to an embodiment will be described with reference to the drawings. FIG. 1 is a diagram illustrating an example of a configuration of a transmission device 1 according to the embodiment.
The transmission device 1 transmits a broadcast wave of a program of FM (Frequency Modulation) broadcast as a transmission wave. The transmission device 1 transmits a transmission wave in order to adjust a position of an area where mutual interference between a transmission wave transmitted from another transmission device 1 and a transmission wave transmitted by the own device occurs to a desired position. Is delayed by a desired delay time. The desired position is, for example, a position included in an area where the number of receiving devices capable of receiving FM broadcast waves is less than a predetermined number, such as a mountain area where almost no people live. The predetermined number is, for example, three. Note that the numerical value of 3 is merely an example, and may be another numerical value such as 0 or 10. Note that the receiving device is a device fixed to a predetermined installation position such as a building or the ground, but in addition to this, a device that can move together with a moving body such as an automobile or a ship may be included. In this case, the predetermined position is a position included in an area in which the number of the receiving devices present in the area per unit time such as one hour or one day is less than the predetermined number.

  The transmission device 1 includes a signal acquisition unit 11, a stereo modulation unit 12, an FM modulation unit 13, an up-converter 14, an amplification unit 15, a band-pass filter (BPF) 16, and an antenna unit 17.

  The signal obtaining unit 11 obtains an input signal input from another device to the own device. The input signal is, for example, a digital audio signal for FM broadcasting of AES (Audio Engineering Society) standard. The input signal is a coded signal. The input signal may be a signal of another standard instead of the signal of the AES standard. The signal acquisition unit 11 decodes the acquired input signal as a broadcast signal including a left channel signal and a right channel signal. The signal acquisition unit 11 outputs the decoded broadcast signal to the stereo modulation unit 12.

  The stereo modulator 12 generates a stereo composite signal (stereo modulation) from a sum-difference signal between the right-channel signal and the left-channel signal of the broadcast signal acquired from the signal acquisition unit 11. The stereo modulation unit 12 outputs the generated stereo composite signal to the FM modulation unit 13.

  The FM modulation unit 13 generates an FM modulation signal by performing FM modulation on a predetermined carrier based on the stereo composite signal acquired from the stereo modulation unit 12. The FM modulation unit 13 outputs the generated FM modulation signal to the up-converter 14.

  The up-converter 14 includes a storage unit 141, a delay adjustment unit 142, a frequency conversion unit 143, and a DAC (Digital-to-Analog Converter) 144.

  The storage unit 141 is, for example, a shift register. Note that the storage unit 141 may be another storage medium such as an SRAM (Static Random Access Memory) instead.

  The delay adjustment unit 142 causes the storage unit 141 to store the FM modulation signal acquired from the FM modulation unit 13. In addition, the delay adjustment unit 142 reads the FM modulation signal from the storage unit 141 every time the delay time stored in advance elapses from the timing when the FM modulation signal is stored in the storage unit 141. The delay adjustment unit 142 outputs the read FM modulation signal to the frequency conversion unit 143.

  Frequency conversion section 143 up-converts the FM modulation signal obtained from delay adjustment section 142. More specifically, frequency conversion section 143 performs quadrature modulation on the FM modulation signal. Frequency conversion section 143 frequency-converts the frequency of the orthogonally-modulated FM signal to a designated transmission frequency. The frequency conversion unit 143 outputs the frequency-converted FM modulated signal to the DAC 144.

  The DAC 144 converts the FM modulated signal obtained from the frequency conversion unit 143, which is a digital signal, into an analog signal. The DAC 144 outputs the converted analog signal to the amplifier 15.

  The amplifier 15 power-amplifies the analog signal acquired from the DAC 144. The amplifier 15 outputs the power-amplified analog signal to the BPF 16.

  The BPF 16 extracts (filters) only a desired frequency component from the analog signal acquired from the amplifier 15. The BPF 16 outputs the extracted analog signal of the frequency component to the antenna unit 17.

  The antenna unit 17 radiates an analog signal acquired from the BPF 16 into space as a transmission wave.

Hereinafter, the delay adjustment processing of the FM modulation signal by the delay adjustment unit 142 will be described.
For example, when the delay time stored in advance is 1 microsecond, the delay adjustment unit 142 transmits the FM modulation signal from the storage unit 141 after 1 microsecond elapses from the timing at which the FM modulation signal is stored in the storage unit 141. Read the signal. For example, if the clock frequency of the delay adjustment unit 142 is 100 megahertz, and if it is desired to delay by 1 microsecond, the FM modulation signal is stored in the storage unit 141 for 100 clocks. Then, after 100 clocks have elapsed, the delay adjustment unit 142 reads the FM modulation signal from the storage unit 141. Thereby, the transmission device 1 can delay the time at which the transmission wave is transmitted. Thereby, transmitting apparatus 1 can easily and accurately adjust the position of the region where mutual interference of transmission waves occurs.

  Also, the transmission device 1 controls the delay time of the input signal at a stage before the up converter 14 acquires the delay time of the input signal because the delay adjustment unit 142 included in the up converter 14 controls the delay time of the FM modulation signal. In comparison, the signal has a higher sample rate. For example, the sample rate of the broadcast signal output from the signal acquisition unit 11 to the stereo modulation unit 12 is about 48 kHz, whereas the sample rate of the FM modulation signal acquired by the up-converter 14 is about 150 MHz. For this reason, the transmission device 1 can perform finer control of the delay time.

  Further, the FM modulation signal has a smaller data amount than a signal accompanied by video. For this reason, the up-converter 14 does not require a large-capacity storage medium as the storage unit 141. That is, the transmission device 1 can delay the FM modulation signal without increasing the size.

  Hereinafter, the flow of processing from transmission apparatus 1 delaying an input signal to transmitting the transmission signal as a transmission wave will be described. FIG. 2 is a flowchart illustrating an example of the flow of processing from transmission device 1 delaying an input signal to transmitting the transmission signal as a transmission wave.

  The signal acquisition unit 11 acquires an input signal input from another device to the own device (step S100). Then, the signal acquisition unit 11 decodes the acquired input signal as a broadcast signal including a left channel signal and a right channel signal. The signal acquisition unit 11 outputs the decoded broadcast signal to the stereo modulation unit 12. Next, the stereo modulation unit 12 generates (stereo-modulates) a stereo composite signal from the sum-difference signal of the right channel signal and the left channel signal of the broadcast signal acquired from the signal acquisition unit 11 (step S110). Then, stereo modulator 12 outputs the generated stereo composite signal to FM modulator 13.

  Next, based on the stereo composite signal obtained from the stereo modulation unit 12, the FM modulation unit 13 performs FM modulation on a predetermined carrier to generate an FM modulation signal (step S120). Then, the FM modulator 13 outputs the generated FM modulated signal to the delay adjuster 142 included in the up-converter 14.

  Next, the delay adjustment unit 142 causes the storage unit 141 to store the FM modulation signal acquired from the FM modulation unit 13 (Step S130). Next, the delay adjustment unit 142 waits until the previously stored delay time has elapsed (step S140). When the previously stored delay time has elapsed (step S140-Yes), the delay adjustment unit 142 stores The FM modulation signal is read from 141 (step S150). Then, the delay adjustment unit 142 outputs the read FM modulation signal to the frequency conversion unit 143.

  Next, frequency conversion section 143 performs quadrature modulation on the FM modulation signal acquired from delay adjustment section 142. The frequency conversion unit 143 frequency-converts the frequency of the orthogonally-modulated FM signal to a designated transmission frequency (step S160). Then, the frequency conversion unit 143 outputs the frequency-converted FM modulated signal to the DAC 144.

  Next, the DAC 144 converts the FM modulated signal, which is the FM signal acquired from the frequency conversion unit 143, which is a digital signal, into an analog signal (Step S170). Then, the DAC 144 outputs the converted analog signal to the amplifier 15. Next, the amplification unit 15 power-amplifies the analog signal acquired from the DAC 144 (Step S180). Then, the amplifier 15 outputs the power-amplified analog signal to the BPF 16.

Next, the BPF 16 extracts only a desired frequency component from the analog signal acquired from the amplifier 15 (Step S190). Then, the BPF 16 outputs the extracted analog signal of the frequency component to the antenna unit 17. Next, the antenna unit 17 radiates (transmits) the analog signal acquired from the BPF 16 into space as a transmission wave (step S200).
As described above, by the processing from step S100 to step S200, the transmission device 1 can delay the input signal and transmit the delayed input signal as a transmission wave.

  According to at least one embodiment described above, in the up-converter 14, the storage unit 141 stores an input signal based on the FM (Frequency Modulation) broadcast standard, and the delay adjustment unit 142 reads the input signal from the storage unit 141. The timing is controlled to adjust the delay of the input signal, and the frequency conversion unit 143 up-converts the input signal adjusted by the delay adjustment unit 142. Thereby, transmitting apparatus 1 can easily and accurately adjust the position of the region where mutual interference of transmission waves occurs.

  Note that a program for realizing the function of an arbitrary component in the above-described device (for example, the transmission device 1) is recorded on a computer-readable recording medium, and the program is read and executed by a computer system. You may do so. Here, the “computer system” includes an OS (Operating System) and hardware such as peripheral devices. The “computer-readable recording medium” refers to a portable medium such as a flexible disk, a magneto-optical disk, a ROM, a CD (Compact Disk) -ROM, and a storage device such as a hard disk built in a computer system. . Further, the “computer-readable recording medium” refers to a volatile memory (RAM) inside a computer system that is a server or a client when a program is transmitted through a network such as the Internet or a communication line such as a telephone line. And those holding programs for a certain period of time.

Further, the above program may be transmitted from a computer system storing the program in a storage device or the like to another computer system via a transmission medium or by a transmission wave in the transmission medium. Here, the "transmission medium" for transmitting a program refers to a medium having a function of transmitting information, such as a network (communication network) such as the Internet or a communication line (communication line) such as a telephone line.
Further, the above program may be a program for realizing a part of the functions described above. Furthermore, the above-mentioned program may be a program that can realize the above-described functions in combination with a program already recorded in the computer system, that is, a so-called difference file (difference program).

  Although several embodiments of the present invention have been described, these embodiments are provided by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in other various forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and equivalents thereof.

DESCRIPTION OF SYMBOLS 1 ... Transmission device, 11 ... Signal acquisition part, 12 ... Stereo modulation part, 13 ... FM modulation part, 14 ... Up converter, 15 ... Amplification part, 16 ... BPF, 17 ... Antenna part, 141 ... Storage part, 142 ... Delay Adjustment unit, 143: frequency conversion unit, 144: DAC

Claims (4)

A storage unit for storing an input signal transmitted based on an FM (Frequency Modulation) broadcast standard;
A delay adjusting unit that adjusts a delay of the input signal by controlling a timing at which the input signal is read from the storage unit to a timing at which a predetermined delay time has elapsed from a timing at which the input signal is stored in the storage unit. ,
A frequency converter for up-converting the input signal adjusted by the delay adjuster,
With
The delay time is a time for which the own device delays transmission of a transmission wave, and a position of an area where mutual interference between a transmission wave transmitted from another transmission device and a transmission wave transmitted by the own device occurs is a predetermined time. Time adjusted to be a position,
Transmission device. The input signal for which the delay adjusting unit adjusts the delay is a signal that is an FM-modulated signal and is not up-converted.
The transmission device according to claim 1. The input signal is an AES (Audio Engineering Society) standard signal.
The transmission device according to claim 1. The storage unit is a shift register or a static random access memory (SRAM).
The transmission device according to claim 1.

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