JP4997071B2 - TMCC signal receiver - Google Patents

Description

  The present invention relates to a terrestrial digital television broadcast receiver, and more particularly to a TMCC signal receiver for ISDB-T terrestrial digital television broadcast.

In ISDB-T (Integrated Services Digital Broadcasting-Terrestrial), which is a terrestrial digital television broadcast transmission system, TMCC (Transmission and Multiplexing Configuration Configuration Signal) is used as control information for assisting demodulation and decoding processing of a receiver. It is transmitted using a carrier. FIG. 1 shows bit allocation in the TMCC signal and the contents of TMCC information to be transmitted. In the TMCC signal, as shown in FIG. 1, the first bit B ₀ is a reference for differential demodulation, bits B _{1 to} B ₁₆ are frame synchronization signals, bits B _{17 to} B ₁₉ are segment format identification, and bit B ₂₀ ˜B ₁₂₁ are TMCC information such as transmission parameters, and bits B _{122 to} B ₂₀₃ are error correction parity bits. That is, the TMCC signal is composed of 204 bits, and 1 bit is transmitted in 1 symbol and 204 bits are transmitted in 1 frame, and is repeatedly transmitted every frame.

  In a TMCC signal receiver or a terrestrial digital broadcast receiver equipped with a TMCC signal receiver, as a conventional technique for receiving a specific bit (TMCC information) of this TMCC signal with low power consumption, intra-frame intermittent reception and inter-frame intermittent reception Is known (see, for example, Patent Document 1).

A timing example of the intra-frame intermittent reception processing is shown in FIG. In this example, the desired the TMCC _information, emergency warning broadcast start flag assigned to _{B 26} is set to (hereinafter, referred to as EWS signal.). Start receiving circuit of the TMCC signal receiving apparatus near the first symbol of a frame to receive the TMCC signal to the total of 27 symbol periods to EWS signals B _26, stops the receiving circuit for subsequent symbol B ₂₇ To do. The start and stop control of the receiving circuit may be performed on the entire receiving circuit, or a part of the receiving circuit with high power consumption may be started or stopped. Thereby, the power consumption of the TMCC signal receiving apparatus can be reduced as compared with the case where all symbols are received in one frame period.

  On the other hand, the intermittent reception between frames is an intermittent reception process in which the reception circuit is not activated for a few frame periods after the symbol of the EWS signal, and the TMCC signal is not received (see, for example, Patent Document 1).

  FIG. 3 shows an example of intermittent reception timing using the intra-frame intermittent reception process and the inter-frame intermittent reception process. In this way, for a certain frame, the receiving circuit is activated and received for 27 symbol periods from the beginning of the frame, and for the subsequent symbol period and n × frame period (n is a positive number), the receiving circuit is activated. By providing the non-receiving circuit that is stopped, the power consumption of the receiving circuit can be significantly reduced.

JP 2006-319771 A

  In the ISDB-T digital terrestrial broadcasting reception, in order to realize the automatic activation by the emergency warning broadcast on the battery-powered portable terminal or the like, considering the influence of the battery depletion on the call time and standby time of the portable terminal It is necessary to monitor a desired symbol (for example, an EWS signal of an emergency warning broadcast activation flag included in the TMCC signal) with as low power consumption as possible.

  In the conventional TMCC signal receiving apparatus, as described above, a method of performing intra-frame intermittent reception processing has been proposed in order to keep the power consumption of the receiving circuit low. That is, in-frame intermittent reception processing is a period from the beginning of the TMCC signal, that is, the beginning of the OFDM frame (hereinafter simply referred to as a frame) to the OFDM symbol (hereinafter simply referred to as a symbol) in which the EWS signal is transmitted. Is the only way to receive. The inter-frame intermittent reception process is a method of receiving by thinning out the frame period to be received in units of frames.

  As shown in FIG. 2, when the transmission mode of digital terrestrial television broadcasting is mode 3 and the guard interval ratio (GI ratio) is 1/8, one frame is 231.336 msec. In intermittent reception within a frame, the duration of supplying power to the receiving circuit in the conventional TMCC signal receiving apparatus is, for example, 30.618 msec (for 27 symbols), and the receiving circuit is turned on from the beginning of the TMCC signal frame. When a desired symbol (for example, EWS signal) is received, the power supply is shut off. Therefore, at least one frame or more is required to receive the EWS signal. Also, as shown in FIG. 3, in intermittent reception between frames, the power-on timing of the receiving circuit is the beginning of the frame, and the ON / OFF interval is N frames (N is a natural number). In the intermittent reception between frames, there is no restriction on the power-on timing of the receiving circuit, and the on / off interval can be a predetermined value (for example, every 10 seconds).

  However, in intermittent reception within a frame, in each received frame, the receiving circuit is activated every time during the period from the beginning to a desired symbol (a total of 27 symbols when receiving an EWS signal), and reception by emergency alert broadcasting is performed. In order to realize the automatic activation of the terminal, there is a problem that the power consumption of the receiving circuit for monitoring the TMCC signal is not sufficient. Furthermore, even if the inter-frame intermittent reception process is used in combination with the intra-frame intermittent reception process, it takes time to detect a signal of a desired symbol, and there is room for further improvement.

  Furthermore, when intermittent reception is continued, there is a problem that symbol synchronization or frame synchronization may be lost depending on reception conditions, and subsequent resynchronization cannot be performed, and a desired symbol cannot be intermittently received.

  An object of the present invention is to provide a TMCC signal receiver that monitors a desired symbol with low power consumption, shortens the detection time of the monitored symbol, and avoids a situation in which continuous reception is impossible due to loss of synchronization. There is to do.

  In the TMCC signal receiving apparatus of the present invention, in order to realize further reduction in power consumption of the receiving circuit, a symbol synchronization signal synchronized with a symbol and a frame synchronization signal synchronized with a frame are generated, and the synchronization signals are referred to Then, power is supplied to the receiving circuit in synchronization with a desired symbol and the receiver circuit is activated, and the power to be supplied to the receiving circuit is interrupted for the subsequent symbols to stop the receiving circuit. In this way, a minimum of one symbol period is received per frame.

That is, the TMCC signal receiver of the present invention is a TMCC signal receiver that demodulates a TMCC signal included in a terrestrial digital television broadcast signal and outputs TMCC information, and converts the received signal in the RF band of the broadcast signal. A receiver circuit that outputs an IF signal, a TMCC demodulator circuit that demodulates a TMCC signal from the IF signal, outputs TMCC information included in the TMCC signal, and reproduces the symbol timing of the OFDM signal from the IF signal, A symbol synchronization reproduction circuit that generates and outputs a symbol synchronization signal, a frame synchronization reproduction circuit that reproduces frame timing from the TMCC information and generates and outputs a frame synchronization signal, and the reception based on each synchronization signal A control circuit that generates and outputs a control signal for controlling power supply to the circuit, and The control circuit determines a synchronization state of the reception signal from the symbol synchronization signal and the frame synchronization signal, and outputs a reception mode selection signal for selecting a reception mode based on the determination result; The first reception mode includes a continuous reception mode control signal generation circuit that continuously outputs a control signal for operating the reception circuit, and the second reception mode includes a symbol indicating an emergency warning broadcast activation flag. The symbol reception mode control signal generation circuit that outputs a control signal for intermittently operating the reception circuit only for a predetermined symbol, and the reception mode selection signal output from the synchronization determination circuit, the continuous reception Either the control signal of the mode control signal generation circuit or the control signal of the symbol decimation reception mode control signal generation circuit Or the other select, anda switch circuit for outputting a control signal selected, the synchronization determination circuit, when detecting loss of synchronization as the determination result, the first receiver to establish a synchronization A reception mode selection signal for selecting a mode is output , synchronization is established, a reception mode selection signal for selecting a second reception mode is output, and the symbol decimation reception mode control signal generation circuit For each frame, a control signal for intermittently operating the receiving circuit is output only for a predetermined symbol including an emergency warning broadcast activation flag and a symbol indicating a TMCC synchronization signal. A control signal for intermittently operating the receiving circuit is output only for a symbol indicating an alarm broadcast activation flag .

  According to the TMCC signal receiving apparatus of the present invention, since the power source for driving the receiving circuit is controlled based on the control signal output from the control circuit, the EWS signal is monitored with low power consumption and the EWS signal detection time is shortened. Can be achieved.

  Furthermore, according to the TMCC signal receiving apparatus of the present invention, by providing the control circuit with the synchronization determination circuit, it is possible to avoid the situation where continuous reception is not possible due to loss of synchronization and to perform resynchronization.

  First, a TMCC signal receiving apparatus according to Embodiment 1 of the present invention will be described.

Example 1
To facilitate understanding of the present invention, TMCC information B ₂₆ to Allocated emergency warning broadcast start flag for the (EWS signal) will be described symbol portion transmitted as desired symbol. The EWS signal is usually “0”, but when a warning declaration of a large-scale earthquake or a tsunami warning is issued, an emergency warning broadcast starts and changes to “1”. It is.

  FIG. 4 shows a block diagram of the TMCC signal receiving apparatus according to the first embodiment of the present invention. The TMCC signal receiver 1 according to the first embodiment is a device that receives and demodulates a TMCC signal included in an ISDB-T terrestrial digital television broadcast signal and outputs TMCC information. The TMCC signal receiving apparatus 1 includes a reception antenna 10, a reception circuit 11, a TMCC demodulation circuit 12, a symbol synchronization reproduction circuit 13, a frame synchronization reproduction circuit 14, a control circuit 15, a power switch 16 and a power supply 17.

  The receiving circuit 11 converts the received signal in the radio frequency (RF) band of the broadcast signal received via the receiving antenna 10 into an intermediate frequency (IF) signal and outputs it.

  The TMCC demodulation circuit 12 receives the IF signal from the reception circuit 11, demodulates the TMCC signal from the IF signal, and outputs TMCC information included in the TMCC signal. Any known method can be used as a method for demodulating the TMCC signal and a method for extracting TMCC information included in the TMCC signal. The TMCC demodulation circuit 12 has a function of demodulating a TMCC signal by establishing both symbol synchronization and frame synchronization by a known method.

  The symbol synchronization reproduction circuit 13 receives the IF signal from the reception circuit 11, reproduces the symbol timing of the OFDM signal from the IF signal, and generates and outputs a symbol synchronization signal. That is, the symbol synchronization signal is a signal whose timing is matched to the OFDM symbol of the OFDM signal. For example, for reproducing the symbol timing of an OFDM signal, the correlation between the in-phase quadrature component (I, Q signal) from the IF signal and the in-phase quadrature component (I ′, Q ′ signal) obtained by delaying them by the effective symbol length. There is a method of reproducing the symbol synchronization signal by using. The symbol synchronization signal can be a pulse signal that triggers on a symbol-by-symbol basis. The symbol synchronization reproduction circuit 13 generates, for example, a clock generator and counter with a frequency higher than or equal to the symbol synchronization signal in order to generate the symbol synchronization signal. The clock generated by the clock generator is counted by a counter, a pulse is generated every time the count value becomes a symbol unit value, and after counting 204 symbols of one frame, the count value is reset. repeat.

The frame synchronization reproduction circuit 14 receives TMCC information from the TMCC demodulation circuit 12, reproduces frame timing from the TMCC information, and generates and outputs a frame synchronization signal. For example, the frame timing is reproduced using a TMCC information synchronization signal (assigned to bits B _{1 to} B ₁₆ ) that is an output of the TMCC demodulation circuit 12. That is, the frame synchronization signal is a signal whose timing is matched to the OFDM frame of the OFDM signal. The frame synchronization signal can be a pulse signal that generates a trigger in units of frames, and the frame synchronization reproduction circuit 14 generates a frame synchronization signal, for example, a clock generator (preferably higher than or equal to the frame synchronization signal). The same clock as the symbol synchronous reproduction circuit 13 is used, and a counter is provided. The clock generated by the clock generator is counted by the counter, and a pulse is generated every time the count value becomes the first value of the frame. Repeatedly resetting the count value every frame.

  The control circuit 15 receives the symbol synchronization signal from the symbol synchronization reproduction circuit 13 and also receives the frame synchronization signal from the frame synchronization reproduction circuit 14 and supplies the power supply 17 to the reception circuit 11 based on each synchronization signal. A control signal for controlling via the power switch 16 is generated and output. The control circuit 15 includes a clock generator and a counter. The control circuit 15 detects the first symbol of the frame by the frame synchronization signal, starts counting, and resets the counter after a predetermined count by the symbol synchronization signal, thereby turning on the power switch 16. A control signal for controlling off / off is generated.

  Therefore, the TMCC signal receiving apparatus 1 controls the power supply of the power supply 17 that drives the receiving circuit 11 based on the control signal output from the control circuit 15.

  Hereinafter, the operation of the TMCC signal receiving apparatus according to the first embodiment will be described in detail.

  An ISDB-T radio frequency (RF) signal received by the receiving antenna 10 is input to the receiving circuit 11. The input RF signal is frequency-converted to an intermediate frequency (IF) signal by the receiving circuit 11 and output. The IF signal output from the reception circuit 11 is input to the TMCC demodulation circuit 12 and the symbol synchronous reproduction circuit 13.

  The TMCC demodulating circuit 12 extracts and demodulates the TMCC signal component included in the input IF signal, and outputs the obtained TMCC information to the frame synchronization reproduction circuit 14 as well as externally. When detecting the EWS signal included in the TMCC signal of the terrestrial digital television broadcast wave, the TMCC demodulation circuit 12 activates the terrestrial digital television broadcast tuner having the OFDM demodulation function. Digital terrestrial television broadcast receivers (including mobile phones with a one-segment reception function) are ready to receive emergency alert broadcasts for the first time.

  The symbol synchronization reproduction circuit 13 receives the IF signal output from the reception circuit 11 and generates a symbol synchronization signal synchronized with the symbol timing of the OFDM signal. Here, the generated symbol synchronization signal is supplied to the control circuit 15. As a result, the control circuit 15 can count in symbol units.

The frame synchronization reproduction circuit 14 detects a 16-bit synchronization signal assigned to the bits B _{1 to} B ₁₆ shown in FIG. 1, and generates a frame synchronization signal synchronized with the frame timing of the OFDM signal. Here, the generated frame synchronization signal is supplied to the control circuit 15 in the same manner as the symbol synchronization signal. Thereby, the timing of the first symbol of the frame can be detected by the frame synchronization signal input to the control circuit 15.

The control circuit 15, based on the symbol synchronization regeneration circuit 13 and the frame symbol synchronization signal are input from the synchronous reproduction circuit 14 and the frame sync signal, near EWS signal B ₂₆ is the desired TMCC information from the first symbol of a frame ( For example, an intermittent reception control signal for starting up the reception circuit 11 is generated and output to the power switch 16 until the timing of the EWS signal can be adjusted.

  The power switch 16 turns on / off the DC power supply (or AC power supply) supplied from the power supply 17 based on the intermittent reception control signal. That is, while the power switch 16 is on, power is supplied from the power source 17 to the receiving circuit 11, and the receiving circuit 11 is activated and receives a signal. During the period in which the power switch 16 is off, the power supply 17 is not supplied with power from the power supply 17, and the reception circuit 11 is not activated and receives no signal. Here, the power supply destination that is turned on / off by the power switch 16 has been described as the entire receiving circuit 11; however, the power supply destination may be a part of the receiving circuit 11 (for example, reception of an EWS signal). It can only be a component part that is indispensable or a component that consumes a lot of power.)

  Thereby, it is possible to control the power supply from the power source 17 that drives the receiving circuit 11 based on the control signal output from the control circuit 15, and to monitor the EWS signal with low power consumption and to shorten the EWS signal detection time. It becomes possible to plan.

  Next, a timing example of the intermittent reception control signal output from the control circuit 15 to the power switch 16 (referred to as a symbol decimation reception mode) will be described with the EWS signal as desired TMCC information in the first embodiment.

  The head symbol of the frame is detected by the frame synchronization signal input to the control circuit 15, and a predetermined number of symbols from the head symbol to the desired symbol (the predetermined number of symbols is the TMCC defined in the radio industry standard). Can be counted by the control circuit 15 based on the pulse of the symbol synchronization signal input to the control circuit 15, and the timing of a desired symbol in the frame can be detected. it can.

  Next, the control circuit 15 sends an intermittent reception control signal to the power switch 16 in order to supply the power supply 17 for starting the reception circuit 11 (or a part of the reception circuit 11) near the detected timing. Output.

As a result, it is possible to preferably receive only one symbol of B ₂₆ in one frame period composed of 204 symbols, and to significantly reduce the power consumption of the receiving circuit compared to the conventional TMCC signal receiver. Can do.

  If the desired TMCC information is 3 bits, intermittent reception is performed in which 3 symbols are received per frame.

  In addition, the example shown in FIG. 5 shows a state in which a 27-symbol period is received once every several frames. This is an oscillator (not shown) that generates a clock signal inside the TMCC signal receiving apparatus 1. This is for correcting the shift in the frame synchronization timing caused by the frequency drift. That is, the reception period (that is, the start-up time in the receiving circuit 11) can be minimized by receiving every several frames instead of receiving the TMCC synchronization signal for each frame.

  Next, a TMCC signal receiving apparatus according to a second embodiment of the present invention will be described.

(Example 2)
As in Example 1, TMCC information B ₂₆ to Allocated emergency warning broadcast start flag for the (EWS signal) will be described symbol portion transmitted as desired symbol. The EWS signal is usually “0”, but when a warning declaration of a large-scale earthquake or a tsunami warning is issued, an emergency warning broadcast starts and changes to “1”. It is.

  FIG. 6 shows a block diagram of the TMCC signal receiving apparatus according to the second embodiment of the present invention. Components similar to those in the first embodiment are denoted by the same reference numerals. Similarly to the first embodiment, the TMCC signal receiving apparatus 2 according to the second embodiment receives a TMCC signal included in an ISDB-T terrestrial digital television broadcast signal, demodulates the TMCC information included in the TMCC signal, and outputs the TMCC information. It is a device to do. The TMCC signal receiving apparatus 2 includes a receiving antenna 10, a receiving circuit 11, a TMCC demodulating circuit 12, a symbol synchronous reproduction circuit 13, a frame synchronous reproduction circuit 14, a control circuit 15, a power switch 16 and a power supply 17.

  The TMCC signal receiving apparatus 2 according to the second embodiment is different from the TMCC signal receiving apparatus 1 according to the first embodiment in that the internal configuration of the control circuit 15 is configured to be switchable between two reception modes.

  Accordingly, in the TMCC signal receiving apparatus 2, the operations of the receiving antenna 10, the receiving circuit 11, the TMCC demodulating circuit 12, the symbol synchronization reproduction circuit 13, the frame synchronization reproduction circuit 14, the power switch 16 and the power source 17 are the same as those in the first embodiment. Therefore, detailed description is omitted.

  The control circuit 15 according to the second embodiment includes a synchronization determination circuit 20, a continuous reception mode control signal generation circuit 21, a symbol decimation reception mode control signal generation circuit 22, and a reception mode switch 23.

The synchronization determination circuit 20 determines the synchronization state of the reception signal received through the reception circuit 11 from the symbol synchronization signal and the frame synchronization signal supplied from the symbol synchronization reproduction circuit 13 and the frame synchronization reproduction circuit 14, respectively, and the determination result The reception mode selection signal for selecting the reception mode of the reception circuit 11 is output based on the above. Also, the synchronization determination circuit 20 functions to detect the desynchronization based on the determination result, when detecting loss of synchronization is received for selecting a first reception mode to establish a synchronization After the mode selection signal is output and synchronization is established, a reception mode selection signal for selecting the second reception mode is output .

  The determination of the synchronization state of the received signal is performed by monitoring the input symbol synchronization signal for the presence of a frame synchronization signal. That is, when the pulse signal of each synchronization signal is not detected, it is determined that the synchronization is lost.

  The continuous reception mode control signal generation circuit 21 outputs a control signal for continuously operating the reception circuit 11 as the first reception mode. Specifically, the continuous reception mode control signal generation circuit 21 continuously supplies power from the power supply 17 to the reception circuit 11, and generates and outputs a control signal for continuously receiving broadcast waves.

  The symbol decimation reception mode control signal generation circuit 22 intermittently sets the reception circuit 11 as a second reception mode in symbol units from the symbol synchronization signal and the frame synchronization signal supplied from the symbol synchronization reproduction circuit 13 and the frame synchronization reproduction circuit 14, respectively. A control signal for operating automatically is output. Specifically, the symbol decimation reception mode control signal generation circuit 22 intermittently performs on / off control of the power supply from the power supply 17 supplied to the reception circuit 11, and generates a control signal for intermittently receiving broadcast waves. And output.

  The reception mode changeover switch 23 is either a control signal from the continuous reception mode control signal generation circuit 21 or a control signal from the symbol decimation reception mode control signal generation circuit 22 according to the reception mode selection signal output from the synchronization determination circuit 20. One is selected, and the selected control signal is output as an intermittent reception control signal for the power switch 16.

  Hereinafter, the operation of the TMCC signal receiving apparatus according to the second embodiment will be described in detail.

  As in the first embodiment, the control circuit 15 receives the symbol synchronization signal and the frame synchronization signal supplied from the symbol synchronization reproduction circuit 13 and the frame synchronization reproduction circuit 14, respectively. In the second embodiment, both the symbol synchronization signal and the frame synchronization signal are supplied to the synchronization determination circuit 20 and the symbol decimation reception mode control signal generation circuit 22.

  The synchronization determination circuit 20 determines the reception status based on the input symbol synchronization signal and frame synchronization signal, and outputs a reception circuit selection mode selection signal to the reception mode changeover switch 23 according to the determination of the reception status.

  Here, the reception operation based on the determination of the reception status will be described. FIG. 7 shows an example of a control signal from the continuous reception mode control signal generation circuit 21 and a control signal from the symbol decimation reception mode control signal generation circuit 22. FIG. 7 shows an example of control signals in a symbol decimation reception mode for receiving only one symbol period of the EWS signal and a continuous reception mode for receiving all symbols. Note that the symbol decimation reception mode shown in FIG. 7 may be considered to be the same as in FIG. 5 described in the first embodiment.

  Usually, in a mobile / mobile reception environment, loss of frame synchronization or loss of symbol synchronization may occur due to reception level fluctuations, frequency shift due to the Doppler effect, multipath effects, and the like. Therefore, the synchronization determination circuit 20 determines whether or not a synchronization loss has occurred in either or both of the symbol synchronization signal and the frame synchronization signal, and whether or not the synchronization signal is input (that is, the presence or absence of a pulse signal for synchronization). ).

  First, when determining that synchronization loss has not occurred in both the symbol synchronization signal and the frame synchronization signal, the synchronization determination circuit 20 selects a signal output by the symbol decimation reception mode control signal generation circuit 22 so as to select a signal to be output. The changeover switch 23 is controlled.

  Next, when the synchronization determination circuit 20 determines that out-of-synchronization has occurred in either or both of the symbol synchronization signal and the frame synchronization signal, in order to continuously receive broadcast waves and establish synchronization again, The reception mode changeover switch 23 is controlled so as to select a signal output from the continuous reception mode control signal generation circuit 21.

  Next, after the synchronization determination circuit 20 establishes frame and symbol synchronization in the continuous reception mode (first reception mode), the control signal output by the symbol decimation reception mode control signal generation circuit 22 is selected again. The reception mode change-over switch 23 is changed over. By selecting the control signal output by the symbol decimation reception mode control signal generation circuit 22 and operating in the symbol decimation reception mode (second reception mode), the EWS signal is returned to a standby state with low power consumption.

  By automatically performing the operation of the synchronization determination circuit 20, the TMCC signal receiving apparatus 2 can monitor the EWS signal with low power consumption while maintaining synchronization with the broadcast wave to be always received.

  Therefore, when either the symbol synchronization signal or the frame synchronization signal is out of synchronization by the synchronization determination circuit 20, it is detected as out of synchronization, and the receiving circuit 11 is controlled so as to continuously receive the broadcast wave until resynchronization is performed. By resynchronizing, it becomes possible to avoid a situation in which continuous reception is impossible due to loss of synchronization.

  Although the above embodiments have been described as representative examples, it will be apparent to those skilled in the art that many variations and substitutions can be made within the spirit and scope of the invention. For example, a TMCC signal receiver can be combined with other signal receivers, and such a TMCC signal receiver can be provided in a terrestrial digital television broadcast receiver. Further, the element of the present invention can be applied to any system that conforms to the ISDB-T system. Accordingly, the invention should not be construed as limited by the embodiments described above, but only by the claims.

  The TMCC signal receiver according to the present invention can monitor an emergency alert broadcast signal with low power consumption, and is useful as a receiver in a transmission system using an emergency alert broadcast signal.

It is a figure which shows the bit allocation in a TMCC signal, and the content of the TMCC information to transmit. It is a figure which shows the example of a timing of the intermittent reception process in a flame | frame. It is an example of the timing of intermittent reception which used intermittent reception processing within a frame, and intermittent reception processing between frames together. It is a figure which shows the TMCC signal receiver of Example 1 by this invention. It is a figure which shows the example of a timing of the intermittent reception control signal in the symbol decimation mode which used EWS signal as desired TMCC information. It is a figure which shows the TMCC signal receiver of Example 2 by this invention. It is a figure which shows the example of a timing of the intermittent reception control signal in switching of the symbol thinning-out mode which used EWS signal as desired TMCC information, and continuous reception mode.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1, 2 TMCC signal receiver 10 Reception antenna 11 Reception circuit 12 TMCC demodulation circuit 13 Symbol synchronous reproduction circuit 14 Frame synchronous reproduction circuit 15 Control circuit 16 Power switch 17 Power supply 20 Synchronization determination circuit 21 Continuous reception mode control signal generation circuit 22 Symbol decimation Reception mode control signal generation circuit 23 Reception mode selector switch

Claims (1)

A TMCC signal receiving apparatus that demodulates a TMCC signal included in a terrestrial digital television broadcast signal and outputs TMCC information,
A receiving circuit that converts an RF band received signal of the broadcast signal and outputs an IF signal;
A TMCC demodulation circuit that demodulates a TMCC signal from the IF signal and outputs TMCC information included in the TMCC signal;
Reproducing symbol timing of OFDM signal from the IF signal, generating a symbol synchronization signal and outputting the symbol synchronization reproduction circuit;
A frame synchronization reproduction circuit that reproduces frame timing from the TMCC information and generates and outputs a frame synchronization signal;
A control circuit that generates and outputs a control signal for controlling supply of power to the receiving circuit based on each synchronization signal;
With
The control circuit includes:
A synchronization determination circuit that determines a synchronization state of the reception signal from the symbol synchronization signal and the frame synchronization signal, and outputs a reception mode selection signal for selecting a reception mode based on the determination result;
As a first reception mode, a continuous reception mode control signal generation circuit that outputs a control signal for continuously operating the reception circuit;
As a second reception mode, a symbol decimation reception mode control signal generation circuit that outputs a control signal for intermittently operating the reception circuit only for a predetermined symbol including a symbol indicating an emergency warning broadcast activation flag; ,
According to the reception mode selection signal output from the synchronization determination circuit, either the control signal of the continuous reception mode control signal generation circuit or the control signal of the symbol decimation reception mode control signal generation circuit is selected and selected A switch circuit for outputting a control signal;
Have
The synchronization determination circuit, when detecting loss of synchronization as the determination result, outputs the received mode selection signal for selecting a first reception mode to establish the synchronization, after establishing the synchronization, the Output a reception mode selection signal for selecting a reception mode of 2 ;
The symbol decimation reception mode control signal generation circuit is configured to intermittently operate the reception circuit only for a predetermined symbol including an emergency warning broadcast activation flag and a symbol indicating a TMCC synchronization signal every several frames. A TMCC signal receiving apparatus which outputs a control signal and outputs a control signal for intermittently operating the receiving circuit only for a symbol indicating an emergency warning broadcast activation flag in the remaining frames .

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