JP2020010373A - Broadcast reception device and broadcast reception method - Google Patents

Abstract

To perform an appropriate reception process by receiving broadcast in which a data signal is included in a broadcast signal.SOLUTION: Over a predetermined period in a period in which road traffic information is not included in a data broadcast signal, a control part 185 replaces channel selection frequencies of RF processing units 120and 120. Then, the control part 185 evaluates reception quality of signals IFDand IFDoutput from the RF processing units 120and 120before and during replacement of the channel selection frequencies. Subsequently, on the basis of the reception quality of the signals IFDand IFDbefore the replacement of the channel selection frequency and the reception quality of the signals IFDand IFDduring the replacement of the channel selection frequency, the control part 185 determines an output destination of a detection signal DTDobtained by subjecting the signal IFDto detection processing, and also determines an output destination of a detection signal DTDobtained by subjecting the signal IFDto detection processing.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a broadcast receiving device, a broadcast receiving method, a broadcast receiving program, and a recording medium on which the broadcast receiving program is recorded.

  2. Description of the Related Art Conventionally, broadcast receiving apparatuses that are mounted on a moving body such as a vehicle and receive broadcast waves such as radio broadcast waves have been widely used. The technology of such a broadcast receiving apparatus has been remarkably advanced, and an information transmission system that multiplexes and transmits a data signal using a part of a subcarrier of a radio broadcast has been put to practical use.

  For example, in a radio data system (RDS) implemented in Europe, information on a tuning frequency (AF (Alternative Frequency) of a broadcasting station broadcasting the same program as that of a broadcasting station being selected is being broadcast. ) The data signal carrying the list) is multiplexed and transmitted. In such a case, in order to select an optimal broadcast station at each time point, an alternative broadcast station that refers to the AF list and detects the reception quality of each broadcast wave of the broadcast station registered in the AF list Seek is possible. As a result, it is possible to select an optimal broadcast station for reproducing a specific program.

  Against this background, a configuration having two tuners is employed, a main tuner selects a station for reproducing a specific program, and a sub-tuner detects the reception quality of each of the alternative broadcast stations. A technique for selecting a channel has been proposed (see Patent Document 1: hereinafter, referred to as "conventional example"). In this conventional technique, the main tuner and the sub-tuner are connected to different antennas.

  When it is determined that the reception state of both received signals is good, the main tuner and the sub-tuner can be operated independently, and the main tuner can select a broadcasting station (hereinafter referred to as a broadcasting station) for reproducing a program. , "Desired station") and the sub-tuner selects a broadcast station different from the desired station (hereinafter, this reception mode is also referred to as "independent operation reception mode"). On the other hand, when the reception quality of the broadcast wave of the desired station decreases, the main tuner and the sub-tuner select the desired station, and shift to the phase diversity reception mode for synthesizing the signals output from the two tuners. Has become.

JP 2007-60624 A

  According to the above-described prior art, in order to achieve both seek of an alternative broadcast station and reproduction of a desired program, when the reception state of both received signals is good, the main tuner is requested in the independent operation reception mode. The station is selected, and the sub-tuner is tuned to an alternative broadcasting station. Then, when the reception state of the broadcast signal of the desired station is reduced, both the seek of the alternative broadcast station and the reproduction of the desired program are abandoned, and the mode shifts to the phase diversity reception mode.

  However, in the conventional technology, even in a reception state where the mode shifts to the phase diversity reception mode, when the desired station is selected by the sub-tuner and the alternative broadcast station is selected by the main tuner, both of the two stations are selected. The reception state of the reception signal may be good. In such a case, the simultaneous reproduction of broadcast waves transmitted from different broadcast stations is possible, but the simultaneous reproduction is abandoned.

  Now, the multiplexed data signal may include, for example, road traffic information. Such road traffic information is not always broadcast from all broadcasting stations. For this reason, a two-tuner configuration is required to achieve both acquisition of road traffic information and reproduction of a desired program.

  By the way, when acquiring important information at the time of driving a vehicle, such as road traffic information, it is necessary to obtain the important information as much as possible. Therefore, it is not desirable to give up simultaneous reproduction when the reception state of the broadcast signal of the desired station is reduced in a tuner that selects the desired station exclusively as in the conventional example.

  Therefore, when reproducing a broadcast wave transmitted from a broadcast station including a data signal in a broadcast signal and a broadcast wave transmitted from a broadcast station different from the broadcast station, important information such as road traffic information is reproduced. There is a demand for a technology that can contribute to both the acquisition of a program and the reproduction of a desired program. Responding to such a request is one of the problems to be solved by the present invention.

  The present invention has been made in view of the above circumstances, and provides a new broadcast receiving apparatus and a new broadcast receiving method capable of receiving a broadcast including a data signal in a broadcast signal and performing an appropriate receiving process. The purpose is to:

  According to a first aspect of the present invention, a first reproduction signal generation unit that receives one of output signals from a first and a second reception processing unit and reproduces a first broadcast including a data broadcast signal; A second reproduction signal generation unit that receives the other of the signals and reproduces a second broadcast; a detection unit that detects reception quality of a selected broadcast wave of the first and second reception processing units; a detection result of the detection unit And a control unit for determining an output destination of the output signal based on the control signal.

  According to a second aspect of the present invention, a first reproduction signal generation unit that receives one of output signals from a first and a second reception processing unit and reproduces a first broadcast including a data broadcast signal; A second reproduction signal generation unit for receiving the other of the above and reproducing the second broadcast; a detection unit for detecting the reception quality of the selected broadcast wave of the first and second reception processing units; and a control unit. A broadcast receiving method used in a receiving device, wherein the control unit switches a tuning broadcast wave by the first and second reception processing units; and a tuning change process of the detecting unit before and after the changing. A control step in which the control unit determines an output destination of the output signal based on a detection result.

  According to a third aspect of the present invention, there is provided a broadcast receiving program for causing a computer of a broadcast receiving apparatus to execute the broadcast receiving method of the present invention.

  According to a fourth aspect of the present invention, there is provided a recording medium characterized in that the broadcast receiving program of the present invention is recorded so as to be readable by a computer of the broadcast receiving apparatus.

1 is a block diagram schematically illustrating a configuration of a broadcast receiving device according to an embodiment of the present invention. FIG. 2 is a block diagram illustrating a configuration of a reproduction processing unit in FIG. 1. FIG. 2 is a block diagram illustrating a configuration of a reception control unit in FIG. 1. FIG. 4 is a block diagram illustrating a configuration of a detection unit in FIG. 3. Is a diagram illustrating a BPF214 _1, 214 ₂ in the characteristics of FIG. FIG. 5 is a diagram illustrating characteristics of BPFs 215 ₁ and 215 _{2 in} FIG. 4. FIG. 2 is a flowchart for explaining switching control processing of selective reception by the device of FIG. 1. FIG. 8 is a flowchart for explaining a detection signal output destination determination control process of FIG. 7. 9 is a flowchart illustrating a first type determination process in FIG. 8. 9 is a flowchart illustrating a second type determination process in FIG. 8.

  Hereinafter, an embodiment of the present invention will be described with reference to FIGS. In the present embodiment, an FM radio receiving apparatus arranged in a vehicle and receiving and processing an FM broadcast wave including a data broadcast signal in a broadcast signal will be described as an example. The FM radio receiving apparatus according to the present embodiment has a function of reproducing and displaying an image reflecting the road traffic information when the data broadcast signal includes a signal carrying “road traffic information”. It is assumed that In the following description and drawings, the same or equivalent elements are denoted by the same reference numerals, and redundant description will be omitted.

[Constitution]
FIG. 1 is a block diagram illustrating a schematic configuration of a broadcast receiving apparatus 100 according to an embodiment. As shown in FIG. 1, the broadcast receiving apparatus 100 includes two antennas 110 ₁ and 110 ₂ , two RF processing units 120 ₁ and 120 _2, and a reproduction processing unit 130. In addition, the broadcast receiving device 100 includes an input unit 140, a sound output unit 150, and a display unit 160. Further, the broadcast receiving device 100 includes a reception control unit 180.

The antennas 110 ₁ and 110 ₂ receive broadcast waves. The signal RFS ₁ received by the antenna 110 ₁ is sent to the RF processing unit 120 ₁ . Further, the received signal RFS _{2 from} the antenna 110 ₂ is sent to the RF processing unit 120 ₂ .

The RF processing unit 120 ₁ receives the received signal RFS ₁ sent from the antenna 110 ₁ . The RF processing unit 120 ₁ performs a tuning process of extracting a signal of a physical channel to be selected from the received signal RFS _{1 in} accordance with the tuning command CSL ₁ sent from the reception control unit 180. The result of tuning by the RF processing unit 120 ₁ is sent to the reproduction processing unit 130 and the reception control unit 180 as a signal IFD ₁ .

The RF processing unit 120 ₂ receives the received signal RFS ₂ sent from the antenna 110 ₂ . The RF processing unit 120 ₂ performs a tuning process of extracting a signal of a physical channel to be selected from the received signal RFS _{2 in} accordance with the tuning command CSL ₂ sent from the reception control unit 180. The result of channel selection by the RF processing unit 120 ₂ is sent to the reproduction processing unit 130 and the reception control unit 180 as a signal IFD ₂ .

The RF processing unit 120 _j (j = 1, 2) includes an input filter, a high-frequency amplifier (RF-AMP: Radio Frequency-Amplifier), and a band-pass filter (hereinafter, also referred to as “RF filter”). . The RF processing unit _120j includes a mixer (mixer), an intermediate frequency filter (hereinafter, referred to as an "IF filter"), an AD (Analog to Digital) converter, and a local oscillation circuit (OSC). ing.

The input filter is a high pass filter for cutting a low frequency component of the corresponding received signal RFS _j sent from antenna 110 _j. The high frequency amplifier amplifies the signal that has passed through the input filter. The RF filter selectively passes a high-frequency band signal among the signals output from the high-frequency amplifier. The mixer mixes the signal passed through the RF filter with the local oscillation signal supplied from the local oscillation circuit.

The IF filter selects and passes a signal in a predetermined intermediate frequency range among the signals output from the mixer. Signal that has passed through the IF filter thus, as the signal IFS _j, sent to AD converter. AD converter generates an intermediate frequency signal IFD _j signal IFS _j and AD conversion.

Note that the local oscillation circuit includes an oscillator or the like whose oscillation frequency can be controlled by voltage control or the like. The local oscillator circuit in accordance with the tuning command CSL _j sent from the reception control unit 180, it generates a local oscillation signal of a frequency corresponding to the desired station to be channel selection, and supplies to the mixer.

In the present embodiment, the antenna 110 ₁ corresponds to the first antenna, and the RF processing unit 120 ₁ performs a part of the function of the first reception processing unit. In addition, the antenna 110 ₂ corresponds to the second antenna, and the RF processing unit 120 ₂ performs a part of the function of the second reception processing unit.

The reproduction processing unit 130 processes the signals IFD ₁ and IFD ₂ sent from the RF processing units 120 ₁ and 120 ₂ under the control of the reception control unit 180. When the selected broadcast wave includes a data broadcast signal carrying “road traffic information”, the reproduction processing unit 130 outputs the road traffic information to be supplied to the display unit 160 based on the data broadcast signal. Generate image data IDT. Further, the reproduction processing unit 130 generates audio data ADT to be supplied to the sound output unit 150 based on the audio signal included in the selected broadcast wave. Details of the configuration of the reproduction processing unit 130 will be described later.

  The input unit 140 includes a key unit provided on the main body of the broadcast receiving device 100 and / or a remote input device including the key unit. Here, a touch panel provided on a display device of the display unit 160 can be used as a key provided on the main body. Further, instead of or in combination with the configuration having the key portion, a configuration in which voice input is performed using voice recognition technology can be adopted.

  When the user operates the input unit 140, the operation content of the broadcast receiving apparatus 100 is set and an operation command is input. For example, an input by the user such as designation of channel selection setting is performed using the input unit 140. The contents input to the input unit 140 are sent to the reception control unit 180 as input data IPD.

  The sound output unit 150 includes (i) a DA (Digital to Analogue) converter for converting the audio data ADT sent from the reproduction processing unit 130 into an analog signal, and (ii) an analog output from the DA converter. It comprises an amplifier for amplifying the signal and (iii) a speaker for converting the amplified analog signal into sound. The sound output unit 150 reproduces and outputs broadcast sound corresponding to the broadcast wave of the selected channel.

  The display unit 160 includes, for example, (i) a display device such as a liquid crystal panel, an organic EL (Electro Luminescence) panel, or a PDP (Plasma Display Panel); and (ii) image data IDT sent from the reproduction processing unit 130. A display control circuit for displaying an image on the display device based on the display device. The display unit 160 reproduces and displays an image reflecting “road traffic information”.

  The reception control unit 180 performs various processes and controls the overall operation of the broadcast receiving device 100. Details of the configuration of the reception control unit 180 will be described later.

<Configuration of the reproduction processing unit 130>
Next, the configuration of the reproduction processing unit 130 will be described. Reproduction processing unit 130, as shown in FIG. 2, a detection unit 131 _1, a detection unit 131 _2, a switching unit 132, a data signal decoding unit 133, and a stereo demodulation unit 134.

The detection unit 131 ₁ receives the signal IFD ₁ sent from the RF processing unit 120 ₁ . Then, the detection unit 131 ₁ performs digital detection processing on the signal by a predetermined method to generate a detection signal DTD ₁ . The detection signal DTD ₁ thus generated is sent to the switching unit 132.

The detection unit 131 ₂ receives the signal IFD ₂ sent from the RF processing unit 120 ₂ . Then, the detection unit 131 _2, with respect to the signal is subjected to a digital detection processing in the same predetermined manner as in the case of the detection unit 131 ₁ generates a detection signal DTD _2. The detection signal DTD ₂ thus generated is sent to the switching unit 132.

In the present embodiment, the detection unit 131 _2, with perform some of the functions of the first receiving processing unit, the detection unit 131 ₂ is adapted to perform some of the functions of the second reception processing unit.

The switching unit 132 receives the detection signals DTD ₁ and DTD ₂ sent from the detection units 131 ₁ and 131 ₂ , respectively. Then, the switching unit 132 performs a process of switching the output destination of the detection signals DTD ₁ and DTD ₂ under the control of the reception control unit 180.

The switching unit 132, the switching control command SWC sent from the reception control unit 180, the later-described "A Selection reception" designation is made, the detection signal DTD ₁ sent from the detection unit 131 _1, a detection signal DTD and sends to the data signal decoding unit 133 as a _D, sends a detection signal DTD ₂ sent from the detection unit 131 _2, the stereo demodulation unit 134 as a detection signal DTD _a. The switching unit 132, the switching control command SWC, the designated "B selection reception" to be described later is performed, the detection signal DTD ₂ sent from the detection unit 131 _2, the data signal decoding unit as the detection signal DTD _D 133, and also sends the detection signal DTD ₁ sent from the detection unit 131 ₁ to the stereo demodulation unit 134 as a detection signal DTD _A.

Above data signal decoding unit 133 receives a detection signal DTD _D sent from the switching unit 132. Data signal decoding unit 133 receives the detection signal DTD _D, performs block synchronization establishment processing of the data broadcast signal carrying the "road traffic information". Then, while the data broadcast signal is in block synchronization, the data signal decoding unit 133 sends a synchronization report SYN to the reception control unit 180 indicating that the block is synchronized, and the data broadcast signal is blocked. While the synchronization is not established, a synchronization report SYN indicating that the block synchronization is not established is sent to the reception control unit 180.

  The data signal decoding unit 133 checks whether or not the content of the data broadcast signal is “road traffic information” while the block synchronization is being established. Then, the data signal decoding unit 133 sends an acquisition report REP indicating that the content of the data broadcast signal is road traffic information to the reception control unit 180 while the content of the data broadcast signal is “road traffic information”. . In addition, the data signal decoding unit 133 determines that the content of the data broadcast signal is not included in the period other than “road traffic information” (for example, “clock information” or “program information”). An acquisition report REP indicating that it is not information is sent to the reception control unit 180.

Further, the decoding unit 133 for data signals, the block synchronization of the data broadcast signal carrying the "road traffic information" is 0.00, while the content of the data broadcast signal is road traffic information, with respect to the detection signal DTD _D, data A decoding process for a signal is performed to generate image data IDT related to “road traffic information”. The image data IDT thus generated is sent to the display unit 160.

The above-mentioned stereo demodulation section 134 receives the detection signal DTD _A sent from the switching section 132. Then, stereo demodulation section 134 performs stereo demodulation processing including separation processing on detection signal DTD _A , and generates audio data ADT. The audio data thus generated is sent to the sound output unit 150.

  In the present embodiment, the data signal decoding unit 133 performs the function of the first reproduction signal generation unit, and the stereo demodulation unit 134 performs the function of the second reproduction signal generation unit.

<Configuration of Reception Control Unit 180>
Next, the configuration of the reception control unit 180 will be described. Reception control unit 180, as shown in FIG. 3, a detecting unit 181 _1, 181 _2, and a control unit 185.

The detection unit 181 ₁ receives the signal IFD ₁ sent from the RF processing unit 120 ₁ . Then, detecting section 181 ₁ detects information about the reception quality of signal IFD ₁ and sends a detection result of the information about the reception quality to control section 185. The detection unit 181 ₂ receives the signal IFD ₂ sent from the RF processing unit 120 ₂ . The detection unit 181 ₂ detects information regarding reception quality of the signals IFD _2, and sends the detection result of the information on the reception quality to the control unit 185. Here, prior to description of the structure of the control unit 185 will be described in detail detector 181 _1, 181 ₂ configuration.

(Configuration of the detection unit 181 _1, 181 ₂₎
The configuration of the detection unit 181 _j (j = 1, 2) will be described. As shown in FIG. 4, the detection unit 181 _j includes a level detection unit 211 _j , an amplitude modulation (AM) component extraction unit 212 _j, and a level detection unit 213 _j . The detecting unit 181 _j includes band-pass filter (BPF) units 214 _j and 215 _j and level detecting units 216 _j and 217 _j .

The level detector 211 _j receives the signal IFD _j sent from the RF processing unit 120 _j . Then, level detector 211 _j detects the level of the signal IFD _j. The detection result by the level detection unit 211 _j reflects the electric field strength of the broadcast wave of the broadcast station selected by the RF processing unit 120 _j . The result of detection by the level detector 211 _j is sent to the controller 185 as a signal level SLD _j .

The AM component extraction unit 212 _j receives the signal IFD _j sent from the RF processing unit 120 _j . Then, AM component extracting unit 212 _j extracts the AM modulated component of the signal IFD _j. Such an AM modulation component is generated by the influence of multipath fading. The result of the extraction by the AM component extraction unit 212 _j is sent to the level detection unit 213 _j as a signal MPD _j .

The level detector 213 _j receives the signal MPD _j sent from the AM component extractor 212 _j . Then, the level detector 213 _j detects the level of the signal MPD _j . Detection result by the level detecting unit 213 _j has a reflects the influence of multipath fading. The detection result by the level detection unit 213 _j is sent to the control unit 185 as a multipath level MPL _j .

Additional BPF unit 214 _j receives a signal IFD _j sent from the RF processing unit 120 _j. Then, BPF unit 214 _j passes the narrow-band component around the center frequency of the lower lower neighbor frequency than the center frequency of the broadcasting station specified tuning. The signal NMD _{j that} has passed through the BPF unit 214 _j is sent to the level detection unit 216 _j . 5 shows an example of the frequency change characteristics of the passing rate of the BPF unit 214 _j is shown.

Here, in FIG. 5, the center frequency of the lower lower neighbor frequency than the center frequency IF ₀ broadcasters specified channel selection "IF _-" is shown as a high frequency than the center frequency IF ₀ above The center frequency of the adjacent station is shown as "IF ₊ ". In FIG. 5, an example of the frequency distribution of the signal of the broadcasting station designated to be tuned is shown as a curve SP ₀ (F), and the example of the frequency distribution of the signal of the lower adjacent station and the upper adjacent station is shown as a curve SP _{0. -} (F), SP ₊ (F). The notation in FIG. 5 is the same in FIG. 6 described later.

The BPF unit 215 _j receives the signal IFD _j sent from the RF processing unit 120 _j . Then, the BPF unit 215 _j allows the above-described narrow band component centered on the frequency IF ₊ to pass. The signal NPD _{j that} has passed through the BPF unit 215 _j is sent to the level detection unit 217 _j . FIG. 6 shows an example of a frequency change characteristic of the pass rate of the BPF unit 215 _j .

The level detection section 216 _j receives the signal NMD _j sent from the BPF section 214 _j . Then, the level detector 216 _j detects the level of the signal NMD _j . Detection result by the level detector 216 _j is a frequency IF _- the electric field strength of the lower adjacent stations to the center frequency, which reflects the mixed degree of signal of the lower adjacent stations in turn signals IFD _j. The detection result by the level detection unit 216 _j is sent to the control unit 185 as the lower adjacent station level NLM _j .

The level detector 217 _j receives the signal NPD _j transmitted from the BPF 215 _j . Then, the level detector 217 _j detects the level of the signal NPD _j . Results detection by the level detector 217 _j, the electric field intensity of the upper adjacent station having a center frequency of IF _+, reflecting the incorporation of the signal of the upper adjoining stations in turn signals IFD _j. The detection result by the level detection unit 217 _j is sent to the control unit 185 as an upper adjacent station level NLP _j .

Returning to FIG. 3, the control unit 185 implements the functions of the broadcast receiving device 100 by performing various processes. The control unit 185, the signal level SLD ₁ sent from the detecting unit 181 _1, a multipath level MPL _1, receiving a lower adjacent station level NLM ₁ and the upper neighboring station level NLP _1. Then, control section 185 evaluates the reception quality of signal IFD ₁ based on these levels SLD ₁ , MPL ₁ , NLM ₁ , NLP ₁ . The control unit 185, the signal level SLD ₂ sent from the detecting unit 181 _2, the multipath level MPL _2, receiving the lower adjacent station level NLM ₂ and upper adjacent station level NLP _2. Then, control section 185 evaluates the reception quality of signal IFD ₂ based on these levels SLD ₂ , MPL ₂ , NLM ₂ and NLP ₂ . Further, the control unit 185 receives the acquisition report REP sent from the data signal decoding unit 133.

Then, the control unit 185, reception quality and reception quality of the signal IFD ₂ signals IFD _1, and, based on the contents or the like of the acquired report REP, "A Selection reception" and "B selection received" in the broadcast receiving apparatus 100 Decide to select one of them. Here, in "A Selection reception", the control unit 185, RF processing unit 120 ₁ to a desired "road traffic information" plays broadcast station for broadcasting including data broadcasting (hereinafter referred to as "data desired station" ) broadcast wave transmitted from the (first broadcast wave, hereinafter causes tuned is also referred to as "data desired station broadcast wave"), RF processing unit 120 ₂ broadcasting stations performing audio broadcasting (hereinafter, " A broadcast wave (second broadcast wave: hereinafter, also referred to as “sound desired station broadcast wave”) transmitted from the desired sound station is selected. The detection signal DTD ₁ output from the detection unit 131 ₁ is sent to the data signal decoding unit 133 as the detection signal DTD _D , and the detection signal DTD ₂ output from the detection unit 131 ₂ is used as the detection signal DTD _A. The signal is sent to the data signal decoding unit 133.

In the “selection B reception”, the control unit 185 causes the RF processing unit 120 ₂ to select the broadcast wave of the desired data station transmitted from the desired data station, and also transmits to the RF processing unit 120 _{1 the} broadcast wave transmitted from the desired voice station. The desired broadcast wave. The detection signal DTD ₂ output from the detection unit 131 ₂ is sent to the data signal decoding unit 133 as the detection signal DTD _D , and the detection signal DTD ₁ output from the detection unit 131 ₁ is used as the detection signal DTD _A. The signal is sent to the data signal decoding unit 133.

  Here, the “audio desired station” does not refer to the specified one broadcasting station, but refers to a broadcasting station that performs an audio broadcasting specified and selected by the user.

Upon switching control of the two selected receiving, the control unit 185, and sends a tuning command CSL ₁ to the RF processing unit 120 ₁ sends a tuning command CSL ₂ to RF processing unit 120 _2. Further, the control unit 185 sends a switching control command SWC to the switching unit 132 of the reproduction processing unit 130.

  The details of the switching control process of the two selective receptions performed by the control unit 185 will be described later.

[motion]
The operation of the broadcast receiving apparatus 100 configured as described above will be described focusing on switching control processing between “A selection reception” and “B selection reception” performed by the control unit 185.

Initially, in the broadcast receiving apparatus 100, the control unit 185 designates one of “A selective reception” and “B selective reception”. When the control unit 185 designates “A selection reception”, the control unit 185 sends a tuning command CSL ₁ corresponding to the data desired station to the RF processing unit 120 ₁ and selects by the user. Send a tuning command CSL ₂ corresponding to the station specified voice desired station to the RF processing unit 120 _2. When the control unit 185 designates “A selection designation”, the control unit 185 converts the detection signal DTD ₁ sent from the detection unit 131 ₁ toward the switching unit 132 into the detection signal DTD _D. as and it sends the data signal decoding unit 133, a detection signal DTD ₂ sent from the detection unit 131 _2, and sends a switching control command SWC specified to send to the stereo demodulation unit 134 as a detection signal DTD _a.

Specifying the state of these "A Selection received" signal IFD ₁ output from the RF processing unit 120 ₁ is transmitted to the detection unit 131 _1, the detection signal DTD ₁ which detection processing has been performed by the detection unit 131 _1, The signal is sent to the data signal decoding unit 133. The signal IFD ₂ output from the RF processing unit 120 ₂ is sent to the detection unit 131 _2, and the detection signal DTD ₂ subjected to the detection processing by the detection unit 131 ₂ is sent to the stereo demodulation unit 134. Then, it is assumed that the control unit 185 has received the synchronization report SYN and the acquisition report REP sent from the data signal decoding unit 133.

When the control unit 185 specifies “B selection reception”, the control unit 185 sends a tuning command CSL ₂ corresponding to the data desired station to the RF processing unit 120 ₂ and selects the data by the user. A tuning command CSL ₁ corresponding to the designated voice desired station is sent to the RF processing unit 120 ₁ . Further, when the control unit 185 designates the "B selection designation", the control unit 185 toward the switching unit 132, a detection signal DTD ₂ sent from the detection unit 131 _2, the detection signal DTD _D And a switch control command SWC that specifies that the detection signal DTD ₁ sent from the detection unit 131 _{1 be} sent to the stereo demodulation unit 134 as the detection signal DTD _A.

The specified state of these "B selection received" signal IFD ₂ output from the RF processing unit 120 ₂ are sent to the detection unit 131 _2, the detection signal detection processing has been performed by the detection unit 131 _2, a data signal Is sent to the decoding unit 133. The signal IFD ₁ output from the RF processing unit 120 ₁ is sent to the detection unit 131 _1, and the detection signal subjected to the detection processing by the detection unit 131 ₁ is sent to the stereo demodulation unit 134. Then, it is assumed that the control unit 185 has received the synchronization report SYN and the acquisition report REP sent from the data signal decoding unit 133.

  Under such circumstances, as shown in FIG. 7, first, in step S11, the control unit 185 determines whether or not block synchronization of the data broadcast signal can be obtained from the content of the synchronization report SYN, that is, reproduction of data broadcast. It is determined whether or not is possible. If the result of this determination is negative (step S11: N), the processing of step S11 is repeated. On the other hand, if the result of the determination in step S11 is positive (step S11: Y), the process proceeds to step S12.

  In step S12, the control unit 185 determines whether or not the content of the data broadcast signal is road traffic information from the acquisition report REP. If the result of this determination is affirmative (step S12: Y), the process returns to step S11. On the other hand, if the result of the determination in step S12 is negative (step S12: N), the process proceeds to step S13.

In step S13, the control unit 185, based on the detection unit 181 ₁ level sent from SLD _1, MPL _1, NLM _1, NLP _1, by evaluating the reception quality of the signals IFD _1, RF processing unit 120 ₁ To obtain the reception quality of the broadcast wave being selected. Further, selection control unit 185 on the basis of the detection unit 181 ₂ level sent from the SLD _2, MPL _2, NLM _2, NLP _2, by evaluating the reception quality of the signals IFD _2, the RF processing unit 120 ₂ Obtain the reception quality of the broadcast wave being broadcast. Thereafter, the processing proceeds to step S14.

In step S14, the control unit 185 switches the tuning frequencies of the RF processing units 120 ₁ and 120 ₂ over a predetermined period. That is, when the "A selection reception" is designated at the present time, the control unit 185, and sends a channel selection command corresponding to the data desired station to the RF processing unit 120 _2, channel selection corresponding to the sound desired station It sends a command to the RF processing unit 120 _1. Also, if the "B selection reception" is designated at the present time, the control unit 185, and sends a channel selection command corresponding to the data desired station to the RF processing unit 120 _1, the tuning corresponding to the sound desired station It sends a command to the RF processing unit 120 _2.

  The “predetermined period” is determined in advance based on experiments, simulations, experiences, and the like, from the viewpoint of ensuring comfortable listening to the audio broadcast designated by the user.

Next, in step S15, the control unit 185 performs the same processing as in step S13 described above to obtain the reception quality of the broadcast wave selected by the RF processing units 120 ₁ and 120 ₂ . Subsequently, in step S16, the control unit 185 restores the channel selection frequencies of the RF processing units 120 ₁ and 120 ₂ replaced in step S14. Thereafter, the processing proceeds to step S17. In this step S17, "determination signal output destination determination control processing" is performed. The details of the “detection signal output destination determination control process” will be described later.

  When the “detection signal output destination determination control process” in step S17 ends, the process returns to step S11. Thereafter, the processing of steps S11 to S17 is repeated, and the switching control processing of the selective reception is performed.

<Detection signal output destination determination control processing>
Next, the “control process for determining the output destination of the detection signal” in step S17 described above will be described.

In the “control process for determining the output destination of the detection signal”, as shown in FIG. 8, first, in step S21, the control unit 185 performs the process based on the reception quality of the broadcast wave acquired in steps S13 and S15 described above. It is determined whether the data broadcast signal can be acquired by both RF processing units 120 ₁ and 120 ₂ . If the result of this determination is negative (step S21: N), the process proceeds to step S22.

In step S22, based on the reception quality of the broadcast wave acquired in steps S13 and S15, the control unit 185 determines whether any of the RF processing units 120 ₁ and 120 ₂ cannot acquire the data broadcast signal. Is determined. If the result of this determination is negative (step S22: N), the process proceeds to step S23. In this step S23, "first type determination processing" is performed. Details of the “first type determination process” will be described later.

  If the result of the determination in step S21 described above is positive (step S21: Y), and if the result of the determination in step S22 is positive (step S22: Y), the process proceeds to step S24. Proceed to. In this step S24, a "second type determination process" is performed. Details of the “second type determination process” will be described later.

<< Type 1 determination processing >>
Next, the “first type determination process” in step S23 described above will be described.

In the “first type determination processing”, as shown in FIG. 9, first, in step S31, the control unit 185 performs an RF processing unit based on the reception quality of the broadcast wave acquired in steps S13 and S15 described above. It is determined from the signal IFD ₁ output from 120 ₁ whether or not data broadcast can be reproduced. If the result of this determination is affirmative (step S31: Y), the process proceeds to step S32.

  In step S32, the control unit 185 determines whether or not the designation of the current selective reception is “A selective reception”. If the result of this determination is affirmative (step S32: Y), the process of step S23 ends without switching the output destination of the detection signal. Then, the process returns to step S11 in FIG. 7 described above.

  On the other hand, if the result of the determination in step S32 is negative, the process proceeds to step S33. In this step S33, the control unit 185 specifies "A selection reception". When “A selection reception” is selected in this way, the process of step S23 ends. Then, the process returns to step S11 in FIG. 7 described above.

If the determination in step S31 described above result is negative (step S31: N), i.e., if it is determined that the data broadcast signal by the RF processing unit 120 ₂ can be acquired, the process step S34 Proceed to.

  In step S34, the control unit 185 determines whether or not the designation of the current selection reception is “B selection reception”. If the result of this determination is affirmative (step S34: Y), the process of step S23 ends without switching the output destination of the detection signal. Then, the process returns to step S11 in FIG. 7 described above.

  On the other hand, if the result of the determination in step S34 is negative (step S34: N), the process proceeds to step S35. In this step S35, the control unit 185 specifies "B selection reception". When “B selection reception” is selected in this way, the process of step S23 ends. Then, the process returns to step S11 in FIG. 7 described above.

<< Type 2 determination processing >>
Next, the “second type determination process” in step S24 described above will be described.

In this “second type determination process”, as shown in FIG. 10, first, in step S41, the control unit 185 performs an RF processing unit based on the reception quality of the broadcast wave acquired in steps S13 and S15 described above. 120 reception quality of the voice desired station broadcast wave tuning ₂ is equal to or better than the reception quality of the voice desired station broadcast wave tuning the RF processing unit 120 _1. If the result of this determination is affirmative (step S41: Y), the process proceeds to step S42. Thereafter, in steps S42 and S43, the same processing as steps S32 and S33 shown in FIG. 9 described above is performed.

On the other hand, if the result of the judgment in step S41 is negative (step S41: N), i.e., the reception quality of the voice desired station broadcast wave tuned by RF processing unit 120 _1, the RF processing unit 120 ₂ If it is better than the reception quality of the selected desired broadcast wave, the process proceeds to step S44. Thereafter, in steps S44 and S45, the same processing as in steps S34 and S35 shown in FIG. 9 described above is performed.

As described above, in the present embodiment, the control unit 185 performs the RF processing before the predetermined period over a predetermined period in a period in which the road traffic information is not included in the data broadcast signal transmitted from the data desired station broadcast wave. the broadcasting station unit 120 ₁ had tuned, it causes tuned to the RF processing unit 120 _2, a broadcast station RF processing unit 120 ₂ before the predetermined period has been tuned, the RF processing unit 120 ₁ Select a station. Then, the control unit 185 evaluates the reception quality of the signals IFD ₁ and IFD ₂ output from the RF processing units 120 ₁ and 120 ₂ during the predetermined period and the period before the predetermined period. Subsequently, the control unit 185 performs a detection process on the signal IFD ₁ based on the reception quality of the signals IFD ₁ and IFD ₂ in the predetermined period and the reception quality of the signals IFD ₁ and IFD _{2 in} the period before the predetermined period. the output destination of the detection signal DTD ₁ subjected, and to determine the destination of the detection signal DTD ₂ subjected to detection processing on the signal IFD _2.

When determining the output destination of the detection signal, the control unit 185 selects the broadcast wave transmitted from the desired sound station when both RF processing units 120 ₁ and 120 ₂ can acquire the data broadcast signal. The output destination of the detection signal is determined by giving priority to the station. Also, the control unit 185 gives priority to the selection of the broadcast wave transmitted from the desired audio station even when the data broadcast signal cannot be obtained by both the RF processing units 120 ₁ and 120 ₂ , Determine the output destination of the detection signal. Further, when a data broadcast signal can be obtained by any of the RF processing units 120 ₁ and 120 ₂ , the selection of the broadcast wave transmitted from the data desired station broadcast wave is prioritized so that the detection signal Determine the output destination of

As described above, in the present embodiment, the channel selection frequencies of the RF processing units 120 ₁ and 120 ₂ are switched during a predetermined period during which the road traffic information cannot be obtained from the data broadcast signal. Then, the reception quality of the broadcast wave of the data desired station and the reception quality of the broadcast wave of the desired sound station are evaluated by both the RF processing units 120 ₁ and 120 ₂ before and after the change of the tuning frequency. Subsequently, based on the evaluation result of the reception quality, an RF processing unit suitable for selecting a desired broadcast wave of a data station is determined, and an RF processing unit suitable for selecting a desired broadcast wave of a sound is determined.

  Therefore, when receiving a broadcast wave transmitted from a broadcast station including a data signal in a broadcast signal and a broadcast wave transmitted from a broadcast station different from the broadcast station, important information such as road traffic information is received. And reproducing the desired program.

  Therefore, according to the present embodiment, it is possible to receive a broadcast including a data signal in a broadcast signal and perform an appropriate reception process.

[Modification of Embodiment]
The present invention is not limited to the above embodiment, and various modifications are possible.

  For example, in the above-described embodiment, the signal level reflecting the electric field strength of the broadcast wave, the multipath level reflecting the influence of the multipath fading, and the degree of mixing of the signal of the lower adjacent station of the designated broadcasting station are determined. The reception quality of the broadcast wave is evaluated based on the reflected lower adjacent station level and the upper adjacent station level reflecting the degree of signal mixture of the upper adjacent station of the selected broadcasting station. On the other hand, for example, the reception quality of the broadcast wave may be evaluated based only on the signal level reflecting the electric field strength of the broadcast wave, or the signal level reflecting the electric field strength of the broadcast wave and the multipath may be evaluated. The reception quality of the broadcast wave may be evaluated based on the level. Further, the reception quality of the broadcast wave may be evaluated based on the signal level reflecting the electric field strength of the broadcast wave, and the lower adjacent station level and the upper adjacent station level.

  When evaluating the reception quality of the broadcast wave, the signal level of the high-frequency component of the detection signal subjected to the detection processing by the detection unit is detected, and the signal level of the high-frequency component (high-frequency noise level) is used. The reception quality of the broadcast wave may be evaluated.

Further, in the above embodiment, the switching unit is arranged after the detection unit. However, the switching unit may be arranged before and immediately before the detection unit. In this case, the switching unit receives the intermediate frequency signals IFD ₁ and IFD ₂ output from the RF processing unit. Then, the switching unit sends the intermediate frequency signals IFD ₁ and IFD ₂ to one of the two detection units according to the switching control command sent from the reception control unit. Incidentally, when to place the switch unit in the preceding stage immediately before the detection unit, RF processing unit 120 _1, with functions of the first receiving processing unit, RF processing unit 120 _2, the second reception processing It performs the function of the department. Further, the detection unit 131 ₁ and the decoding unit for the data signal, together with the functions of the first reproduction signal generating unit, the detection unit 131 ₂ and a stereo demodulation unit, adapted to perform the function of the first reproduction signal generating unit I have.

Further, the switching unit may be arranged between the antennas 110 ₁ and 110 ₂ and the RF processing units 120 ₁ and 120 ₂ .

Further, in the above embodiment, a two-tuner configuration is used, but three or more pairs of antennas and RF processing units may be used. For example, when a four-tuner configuration is employed, two tuners can correspond to the RF processing unit 120 ₁ , and the other two tuners can correspond to the RF processing unit 120 ₂ .

  Further, in the above embodiment, the data broadcast signal carrying “road traffic information” is received and processed. However, the data broadcast signal to be received and processed is information other than “road traffic information”. Is also good.

  Further, in the above embodiment, the parallel reception processing of the data broadcast signal and the audio broadcast signal is performed, but the parallel reception processing of the two types of data broadcast signals may be performed.

  In the above embodiment, the audio broadcast signal transmitted from the desired audio station is a signal carrying analog information, but may be a signal carrying digital information.

Further, in determining the destination of the detection signal from the switching unit, the reception quality of the broadcast wave to be channel selection target by RF processing unit 120 ₁ in a predetermined period, and, a broadcast wave to be channel selection target by RF processing unit 120 ₂ both reception quality, if it is better than the reception quality in the period before the predetermined period, the RF processing unit 120 _1, to select the broadcasting station RF processing unit 120 ₂ had tuned in before the predetermined time period causes the station, the output destination detection signal DTD _1, to determine the destination of the detection signal DTD ₂ before the predetermined period. Then, the RF processing unit 120 _2, the RF processing unit 120 ₁ in the previous predetermined period causes tuned broadcasting station which has been tuned, the output destination of the detection signal DTD _2, of the detection signal DTD ₁ before a predetermined time period The destination may be determined.

  Also, the present invention can be applied to, for example, a receiving apparatus corresponding to an information transmission system in which a data signal is multiplexed with an audio signal of an RDS system or the like implemented in Europe and broadcast. is there.

  Further, in the above embodiment, the present invention is applied to the broadcast receiving device mounted on the vehicle, but the present invention can also be applied to a broadcast receiving device arranged on a moving object other than the vehicle. The present invention can also be applied to a broadcast receiving device arranged in a portable terminal device such as a smartphone.

  A part or all of the reception control unit described above is configured as a computer as an arithmetic unit including a central processing unit (CPU), and a prepared program is executed by the computer. The function of the reception control unit in the above embodiment may be realized. This program is recorded on a computer-readable recording medium such as a hard disk, a CD-ROM, and a DVD, and is read out from the recording medium and executed by the computer. The program may be obtained in a form recorded on a portable recording medium such as a CD-ROM or a DVD, or may be obtained in a form of distribution via a network such as the Internet. Is also good.

100 Broadcast receiver 120 ₁ RF processing unit (part of first reception processing unit)
120 ₂ ... RF processing unit (part of the second reception processing unit)
131 ₁ Detector (part of first reception processor)
131 ₂ Detector (part of second reception processor)
133: data signal decoding unit (first reproduced signal generation unit)
134 ... stereo demodulation unit (second reproduction signal generation unit)
181 ₁ Detector 181 ₂ Detector 185 Control

Claims (1)

A first reproduction signal generation unit that receives one of the output signals from the first and second reception processing units and reproduces a first broadcast including a data broadcast signal;
A second reproduction signal generation unit that receives the other of the output signals and reproduces a second broadcast;
A detection unit for detecting reception quality of a selected broadcast wave of the first and second reception processing units;
A control unit that determines an output destination of the output signal based on a detection result of the detection unit;
Broadcast receiving device comprising:

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