WO2001059943A1 - Digital broadcast receiver - Google Patents

Abstract

The convenience of a car radio receiver for digital audio broadcast (DAB) is improved. The audio service components in an ensemble of DAB can be detected by using information on FIC of a transmission frame. A DAB car radio receiver (10) is provided with an exclusive key (25) exclusively used for instruction to do an overall audio service component scanning. When the user operates the key (25), all the audio service components belonging to the same ensemble to which the audio service component being outputted from the loudspeaker belongs are outputted sequentially at regular time intervals from the loudspeaker. The user can designate a language that the user understands. When an announce broadcast starts, the language of the announce broadcast is examined. Only if the language is the designated language, interruption by the announce broadcast is allowed.

Description

 Specification

 Digital broadcast receiver

Technical field

 The present invention relates to a receiver for digital audio broadcasting such as DAB (Digital Audio Broadcasting).

Background art

 In DAB, a plurality of audio service components are combined into one ensemble, each ensemble is transmitted on a predetermined carrier assigned to each ensemble, and the DAB radio receives the carrier, The audio service component selected by the user from the ensemble is output from the audio output means.

 A DAB car radio equipped with a preset scan function is known. In the preset scan, all audio service components that are preset to each preset key are sequentially output at predetermined time intervals from speed.

The known preset scan function of DAB radio is limited to a method of sequentially outputting audio service components within a range of audio service components preset for each preset key. At this point, you may want to know all the audio service components that you can hear, even if they are not turned on. Also, DAB has an announcement broadcast such as an alarm (Alarm) and traffic information (Road Traffic Flash). With a conventional DAB radio, when a user is listening to a normal service component, the announcement broadcast is performed. When this occurs, the announcement broadcast will be interrupted by the service component currently being listened to and output. Various languages are used for DAB announcement broadcasting and service components. In a conventional DAB radio, when a service component occurs, an interrupt is performed regardless of the language of the service component. Also, when the user instructs to switch to another service component or a service component of a predetermined program type, the switching is performed regardless of the language of the service component to be switched to. However, interrupting the announcement broadcast in a language that the user cannot understand or switching to a service component is meaningless.

 An object of the present invention is to provide a digital broadcast receiver which overcomes the above problems.

Disclosure of the invention

 ADVANTAGE OF THE INVENTION According to the digital broadcast receiver of this invention, a user is previously made to specify a language, and when an interrupt broadcast occurs, interruption is permitted only when the language of the interrupt broadcast is the language specified in advance. It is to be forgiven.

Digital broadcasting includes not only digital radio broadcasting but also digital television broadcasting, and in particular includes DAB. Digital broadcast receivers include, in particular, on-board radios. The output of interrupt broadcasting and service components is performed by AV (audio and video) output means. The AV output means is, for example, a speaker in the case of digital radio broadcasting, and is, for example, a speaker in the case of digital television broadcasting. And a monitor. Interruption broadcasting is called “announcement broadcasting” in DAB. _C Digital broadcasting includes not only AV data but also information on the language of interrupt broadcasting. Language information can be extracted from the transmission signal to detect the language of the interrupt broadcast. Word specified by user The number of ^ words is not limited to one, but may be plural.

 In this way, even if an interrupt broadcast of a language not specified by the user occurs, the interrupt of the interrupt broadcast is not recognized, and only the interrupt broadcast of the language specified by the user is permitted. It is possible to avoid having to watch (in the case of digital television broadcasting) or listen to (in the case of digital radio broadcasting) service components in a language that cannot be understood.

 ADVANTAGE OF THE INVENTION According to the digital broadcast receiver of this invention, a user specifies in advance the language, Z, or type of the interrupt broadcast for which the user recognizes the interrupt, and when the interrupt broadcast occurs, the language, Z, or Z of the interrupt broadcast is generated. Only allows interrupts when the type matches a pre-specified language and Z or type.

 Digital broadcasts contain information on the type of interrupt broadcast, and the type of interrupt broadcast can be extracted from the transmission signal to detect the type of interrupt broadcast. In DAB, the types of interrupt broadcasts are Alarm (Alarm), Road Traffic Flash (Road Traffic Flash), Warning (Warning: Warning can be considered a lower level of danger than Alarm), and News Flash. (News Flash) etc. are defined. The type of interrupt broadcast specified by the user is not limited to one, but may be plural.

 The user can listen to (in the case of digital radio broadcasts) only those interrupt broadcasts that match the language and Z or type specified in his or her pre-designated language and / or type. You can watch (in the case of digital television broadcasting).

According to the digital broadcast receiver of the present invention, the user Language is specified, and if the user instructs to switch service components, switching is allowed only when the language of the program currently being broadcast in the service component to be switched is the language specified in advance. It has become so.

 The service component is a broadcast unit that broadcasts each program. When the user desires to output a desired program, the user selects a service component broadcasting the program. It is assumed that the service component in D AB may be either a primary or secondary service component.

 The switching instruction by the user is provided so that the user can output the next service component in a preset key set in advance so that the predetermined service component can be output, or in a cycle of ascending or descending order for each operation. This is done by operating the up-down key that is in operation.

 Even if the user attempts to switch the service component by operating the preset key or the up / down keys, if the language of the program currently being broadcast is different from the language specified in the service component to be switched to For example, the switching to the service component is stopped, and the switching is performed only when the language of the program currently being broadcast matches the specified service component in the switching destination service component, and the switching destination service is performed. You can listen to (in the case of digital radio broadcasting) or watch (in the case of digital television broadcasting) components.

According to the digital broadcast receiver of the present invention, the language is specified in advance by the user, and when the user instructs to switch the service component to specify the program type, the program type is changed to the specified type. Switching is allowed only when the language of the service component broadcasting the matching program is the language specified in advance.

 Program types include, for example, music, news, and sports for DAB. A search is performed for the service component of the program type specified by the user, and even if the corresponding service component is found, if the language of the service component does not match the one specified in advance, the AV output means Output from the Internet is prevented and the user does not have to listen to unnecessary service components (for digital radio broadcasts) or watch (for digital television broadcasts).

 Another object of the present invention is to provide a digital audio broadcast receiver capable of notifying a user of information on all audio service components that can be heard at the present time.

According to the digital audio broadcast receiver of the present invention, a plurality of audio service components are combined into one ensemble, and each ensemble is transmitted on a predetermined carrier assigned to each ensemble. On receiving the carrier, the audio service component selected by the user from the ensemble is output from the audio output means. In this digital audio broadcast receiver, an audio service component scan operation member is set, and as the user operates the audio service component scan operation member, all ensembles included in the currently received ensemble are included. The audio service component is sequentially output from the audio output means at appropriate time intervals. _c

 6 Digital audio broadcasting especially includes DAB. Digitalo-Dio broadcast receivers include, in particular, in-car radios and DAB car radios. The audio output means is, for example, a speaker.

 An ensemble refers to a set of a plurality of audio service components transmitted by one carrier. An audio service component refers to a broadcast output unit that has a mutually identifiable identification name and runs one audio program (= program) at each time. The audio service component includes a primary service component and a secondary service component. In DAB, one service includes one primary service component and zero or more secondary service components. In DAB, the primary service component is usually an audio service component, and the secondary service component is an audio service component or a data service component. Thus, the audio service components in the DAB include both primary and secondary audio service components. The output time of each audio service component from the audio output means is usually equal time, but may be other than equal time.

 In addition to audio data, the digital radio broadcast transmission signal contains what kind of audio service component, and the audio data of the audio service component contains information indicating where in the transmission frame. Based on this information, an arbitrary audio service component in the ensemble can be extracted and output from the audio output means.

"All audio service components" of "All audio service components included in the currently received ensemble" It is assumed that the audio service component output from the audio output means may or may not include the audio service component immediately before the user operates the audio service component scan operation member.

 In this way, the user can output all audio service components belonging to the same ensemble as the audio service component currently being listened to in order from the audio output means, regardless of the preset, and know the audio service components. Can be.

 According to the digital audio broadcast receiver of the present invention, a plurality of audio service components are combined into one ensemble, and each ensemble is transmitted on a predetermined carrier assigned to each ensemble. The carrier is transmitted, and the audio service component selected by the user from the ensemble is output from the audio output means. In this digital audio broadcasting receiver, the audio service component scan operation member is set, and the user specifies values in advance for predetermined attributes of the audio service component, and the user specifies the audio service component. As the scanning operation member is operated, all audio service components included in the currently received ensemble whose attribute value matches the specified value are sequentially output from the audio output means for a predetermined time. ing.

 Attributes for which the user specifies values for audio service components are:

The number is not limited to one (for example, only language or program type), and may be plural (for example, both language and program type). In addition, the value specified by the user for the attribute is not limited to one (for example, English only or French only when the attribute is a language). ₀

(Eg, English and French if the attribute is language). In this way, the user can output all audio service components that belong to the same ensemble as the audio service component currently being listened to and whose attribute value matches the specified value, regardless of the preset. It is possible to know by outputting in order from the means.

 According to the digital audio broadcasting receiver of the present invention, the attribute is a language, a program type, or a region.

 Languages are, for example, English, French, German, and Italian. The program types are, for example, music, news, and sports. A region is a predetermined region that exists in the same country or a predetermined region that exists over multiple countries.

BRIEF DESCRIPTION OF THE FIGURES

 Fig. 1 is a system configuration diagram of a car radio for DAB.

 FIG. 2 is a diagram showing the structure of a DAB transmission frame.

 FIG. 3 is an illustration of the service component structure of the DAB.

 FIG. 4 is a structural diagram of the FIB.

 FIG. 5 is a structural diagram of the FIG data area of FIG. 4 in which the FIG type is 0.

 FIG. 6 is a structural diagram of FIG0Z5.

 FIG. 7 is a flowchart of a program for allowing a user to specify a language on a DAB car radio.

 Fig. 8 is a flowchart of the interrupt program of the announcement broadcast.

FIG. 9 is a flowchart of the program when the user issues a service component switching instruction. _g Fig. 10 is a flowchart of the program when the user switches the service components by specifying the program type PTY.

 FIG. 11 is a flowchart of a program for scanning all audio service components.

 FIG. 12 is a flowchart of a program in a stage before executing the limited all audio service component scan in FIG. 13.

 Figure 13 is a flowchart of a program that performs a limited audio service component scan.

Embodiment of the Invention

 Hereinafter, embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a system configuration diagram of a DAB car radio 10. The DAB radio 10 has a reception signal processing unit 11 and a user interface unit 20. In the reception signal processing unit 11, the DAB system microcomputer 12 has a memory 13 and a plurality of ensembles (each ensemble is transmitted by radio broadcast radio waves modulated by DQPSK-OFDM, and one ensemble is transmitted). (The bandwidth is about 1.5 MHz, which usually contains 6 broadcast programs.) Specify one ensemble and send the specified information to the RF block 14. The RF block 14 extracts the RF (Radio Frequency) of the specified ensemble from the DAB system microcomputer 12 and sends it to the demodulation block 15. The demodulation block 15 demodulates the RF signal from the RF block 14 as DAB data, and the channel decoding block 16 decodes the demodulated signal from the demodulation block 15. In this way, all digital signals of one ensemble designated from the DAB system microcomputer 12 to the RF block 14 are obtained in the channel decoding block 16. O — FIG. 5 (Fast Information Group) data such as program types other than the video data is sent from the channel decoding block 16 to the DAB system microcomputer 12. On the other hand, from the DAB system microcomputer 12 to the channel decoding block 16, it is determined whether the audio data of the audio service component currently selected by the user is included in which sub-channel of the MSC (Main Service Canne 1). The information is transmitted, and the channel decoding block 16 transmits only the decoded audio data relating to the corresponding sub-channel to the audio decoding block 17. The audio decoding block 17 expands the audio data (audio data compressed by MPEG) input from the channel decoding block 16 and sends it to the left and right speakers (not shown). The audio you hear is played. The DAB control microcomputer 21 of the user interface unit 20 has a memory 22 and exchanges data with the DAB system microcomputer 12 of the reception signal processing unit 11. The DAB control microcomputer 21 receives instructions from the user via the key 23 and outputs predetermined data to the display unit 24 to display information and inform the user. It has been

 The communication protocols of various elements of the DAB such as transmission frames are described as appropriate in Figs. 2 to 6 below. For details, refer to the European Telecommunication Standardization Association (European Te 1 ecommun i The European Telecommunications Standard and published by the European Standards Institute (Cations Standards Institute).

Figure 2 shows the structure of the DAB transmission frame. The transmission frame is a synchronization channel and FIC (Fast 丄 丄

It has an Information Channel: Fast Information Channel and an MSC (Main Service Channel: Main Service Component Channel). The data in the FIC is sent from the CDB 16 in FIG. 1 to the DAB system microcomputer 12 and used for controlling the reproduction in the ADB 17. The FIC is further composed of a plurality of FIBs (Fast Information B 1 ock), and the MSC is further composed of a plurality of CIFs (Common Interleaved Frames). The specification of DAB is determined from mode 1 to mode 4, and the transmission frame time (duration) and the number of FIB and CIF in one transmission frame are different for each mode. For example, in mode 1, the time of one transmission frame is 96 ms, and the numbers of FIB and CIF in one transmission frame are 12 and 4, respectively.

FIG. 3 is an illustration of the service component structure of DAB. The user accesses each service component component by selecting the service component. Multiple service components can be accessed by one ensemble, and each service component has one or more service component components. Each service component is transmitted on each subchannel of MSC or FIC. The underlying service component component of each service component is called the primary service component component. The primary service component is usually a program service component as audio, but may be a service component. The ensemble (Ensemble) whose ensemble label (name of ensemble) is DAB ENSEMBLE ONE has service component labels of Alpha 1 Radio (ALPHA 1 Radio), BETA Radio (BETA Radio), and Alpha 2 It includes a plurality of service components (Service) such as radio (ALPHA 2 Radio). Alpha 1 radio has one primary service component component and two secondary service component components. The service component component of the primary is audio, and the service component component of the secondary is a traffic message channel: TMC (Traffic Message Channel) and service component information: SI (Service Information). . The audio component and the SI are transmitted on separate sub-channels (Sub Ch) in the MSC, and the TMC is transmitted on the FIDC (Fast Information Data Channel) in the FIC.

 Bey Even Radio has two service component components. It is composed of audio and secondary audio components (secondary audio components), and is also placed on the MSC subchannel.

 The Alpha 2 radio has the same TMC and SI as the Alpha 1 radio, and the audio may be the same as the Alpha 1 radio depending on the switching of the switch SW.

FIG. 4 is a structural diagram of the FIB for overnight transmission of FIG. The decoded FIB data in the FIC is sent from the CDB 16 in FIG. 1 to the DAB system microcomputer 12 and used for controlling the reproduction in the ADB 17. The FIB consists of a total of 256 bits, and consists of a front 30 byte FIB data area (FIB data Π e 1 d) and a rear 16 bit CRC (Cyclic Redundancy Check word). The FIB data area further includes a plurality of FIG (Fast In format ion Groups), one end marker (End marker), and one padding (FIB data overnight area) in order from the front. The remaining bits to zero in order to match them). The FIG part is useful data area (useful data 丄_g field). Each FIG includes a FIG type, a length (representing a bit length of a subsequent FIG data area), and a FIG data field (FIG data field) in order from the front. The FIG type and Length make up the FIG header.

 FIG. 5 is a structural diagram of the FIG data overnight area of FIG. 4 in which the FIG type is 0 (0000 in 3-bit binary notation). The FIG data area has CZN (Current / Next), OE (Other Ensemble), Ρ / D (Programme / Data), Extension, and type 0 area (Type 0 Π e 1 d) in order from the front. . When Extensions are 1 to 4 and 7, CZN = 0 means the current multiplex structure, and CZN = 1 means the next multiplex structure. means. Further, when CZN = 1, it means that the type 0 region is related to the following sequence. When Extension is 6, 9, 11, 18, 21, 22, 23, 24, 25, 27, 30, C / N indicates the purge ion number of type 0 area . OE is used when Extension = 12, 16, 17, 21, 24, 30, and OE = 0 means that the information of this type 0 area is related to this ensemble However, 〇 E = 1 means that it is related to another ensemble. P ZD = 0 means that the SI d of the type 0 area is the 16-bit Sid used for the program service component, and P ZD::! Indicates that the SI d of the type 0 area is , Which means 32 bits SI d used for the data service component. This PZD is used when Extension is 2, 9, 23, or 24, and when not used, SId is 16 bit format.

FIG. 6 is a structural diagram of FIG0Z5. Note that each FIG The type and the extension are represented as FIG 0 Z 5. The Type 0 area is divided into multiple Service Component 1 language sections. The first bit of each service component component is the LZS flag (L / SΠag). Depending on whether the LZS flag is 0 or 1, the service component language is divided into short format and long format. The MSCZFIC flag in the short format, when it is 0 and 1, indicates that this service component is listed in the MSC and FIC, respectively. The data of the short-form sub-channel I d ZFIDCI d reveals the I d of the sub-channel or FIDC that carries this service component component. From the long-term sub-channel Id data, the Id of the sub-channel on which this service component component is placed can be determined. The language of the service component component can be determined from the language data. That is, the DAB system microcomputer 12 knows the decoded language data of each service in the Ensemble from the language data in the FIC-FIG.

 FIG. 7 is a front chart of a program for allowing a user to specify a language on the DAB power radio 10 in the DAB control microcomputer of FIG. In S40, the user specifies a language such as English or French. Usually one language is specified, but multiple languages can be specified. In S41, the language specified by the user in S40 is stored in a predetermined memory. The specified language data is sent to the DAB system microcomputer 12.

Fig. 8 shows an example of the analog operation performed by the DAB system microcomputer 12 in Fig. 1. This is a flowchart of the interrupt program of the broadcast. In DAB, the interrupt service is called an announcement broadcast. In S45, it is determined whether or not an announcement broadcast has occurred. If the determination is YES, the process proceeds to S46, and if N〇, the program ends. In S47, it is determined whether or not the (current) language of the announcement broadcast generated in S46 matches the specified language stored in S41 described above. Proceed to step 7. If N〇, terminate the program. In step S47, the announcement broadcast generated this time is output from the speaker of the DAB-Radio 10 in place of the service component currently being reproduced. In this way, only the announcement broadcast in the language that matches the language specified by the user in advance is permitted to be interrupted, output from the DAB car radio 10 speaker, and the user is notified of the announcement. You will hear the content of the broadcast.

In the flowchart of FIG. 8, if the language of the generated announcement broadcast matches the language specified by the user in advance in the flowchart of FIG. 7, the announcement broadcast is output from the speaker. However, the language and announcement type (= interrupt broadcasting type: warning, road traffic information, caution, and news flash, etc.) specified by the user in advance are set, and the language and announcement language of the generated announcement broadcasting are set. Only when the type matches the language and type specified by the user in advance, the announcement broadcast may be output from the speaker. Furthermore, the user is required to specify only the announcement type in advance, and only when the type of the generated announcement broadcast matches the type specified by the user, the announcement broadcast is output from the speaker. You may do it.

 FIG. 9 is a flowchart of the program when the user issues a service component switching instruction. In S50, it is determined whether or not there is a service component that can be output in response to the switching instruction from the user. If the determination is YES, the process proceeds to S51, and if the determination is NO, the program is executed. finish. In S51, the language of the service component output-enabled in S50 (strictly speaking, the language of the program currently being broadcast in the service component) matches the specified language stored in S41 described above. It is determined whether or not to execute the process. If the determination is YES, the process proceeds to S52. If the determination is N〇, the program ends. In S52, the service component is switched to the service component determined to be YES in S51. As a result, the service component determined as YES in S51 is output from the speed of the DAB radio 10 and the user listens to the program currently being broadcast with the service component. .

FIG. 10 is a flowchart of a program when a user designates a program type (PTY) and switches service components. In S55, a search is performed in response to the user's PTY (program type) specification switching instruction, and as a result, the service component of the PTY that matches the user-specified PTY Service component of the PTY program). Then, if the determination is YES, the process proceeds to S56, and if N〇, the program ends. In S56, it is determined whether or not the language of the service component determined as PTY-match in S55 matches the specified language stored in S41 described above. If the determination is YES, S is determined. Go to 5 and 7, if NO, end the program. In S57, the service component is switched to the service component determined to be 丫 £ S in 355. As a result, YES was determined in S55. The specified service component is output from the speaker of the DAB car radio 10 and the user listens to the service component program.

FIG. 11 is a flowchart of a program for scanning all audio service components performed by the DAB system microcomputer 12 in FIG. In this all audio service component scan, the audio service components output one after another from the speaker are audio service components belonging to the same ensemble as the currently output audio service component. However, it is possible to cover all audio service components of all ensembles that can be received at the current location. In the DAB car radio 10 shown in FIG. 1, a dedicated key 25 for instructing all audio service component scans is provided in the key 23. In S30, it is determined whether or not the user has operated such a key 25 for instructing all audio service component scans. If the determination is YES, the process proceeds to S31, and if it is N〇 If so, terminate the program. In S31, it is determined whether or not all audio service component scans have been completed. If the determination is YES, the process proceeds to S34, and if NO, the process proceeds to S32. In S32, of all audio service components decoded by CDB 16 in FIG. 1, one of the other audio service components not yet output from the speaker is transferred to the next audio service component. To ADB17 so that it is output from the speaker, and switches the audio service component output from the speaker. In S33, it is determined whether or not a predetermined time T has elapsed since the switching time for the audio service component being output from the speed as the next audio service component in S32, and the predetermined time T or more is determined. Passing , ₀

丄 8 Return to S31. In S34, the output from the speaker is switched to the first audio service component. In this way, all audio service components belonging to the same ensemble as the audio service component currently being output from the speaker are output from the speaker one after another for a predetermined time T, and when all the output is completed, the output from the speaker becomes all. Return to the audio service component before the audio service component scan is started. Fig. 12 is a flowchart of the program before executing the limited all audio service component scan in Fig. 13 and the DAB control. This is performed by microcomputer 21. In S35, the user is caused to select the attribute of the audio service component. Attributes of the audio service component include, for example, language, program type, and region. The attribute selection by the user is not limited to one attribute, and may be performed for a plurality of attributes. In S36, the user is caused to specify the value of the attribute selected by the user in S35. The attribute values include, for example, English, French, and German when the attribute is a language, and music, news, and sports when the attribute is a program type. In DAB, the attributes and values of each audio service component are written and transmitted to the FIC. By reading this information, the attributes and values of each audio service component can be detected. The number of attribute values specified by the user is not limited to one. For example, when the attribute is a language, a plurality of values may be used, such as two values of French and German. At S37, the attribute and its value specified by the user at S36 are stored. The stored data is sent to the DAB system microcomputer 12. Figure 13 performs a limited full audio service component scan This is the flow chart of the program. The same parts as those in the flowchart of FIG. 11 are designated by the same reference numerals, and only the differences will be described. In the flow chart of FIG. 13, S 31 and S 32 in the flow chart of FIG. 11 are replaced with S 31 b and S 32 b, respectively. In S31, the attributes and their values of the audio service components are stored in memory in S37, regardless of whether or not the scanning of all audio service components belonging to the same ensemble has been completed. It is determined whether or not scanning of all audio service components that match (the attribute values are combined and described in the figure) is completed. If the determination is YES, the process proceeds to S34. Proceed, if NO, proceed to S32b. In S32b, among all the audio service components, among the other audio service components which have not yet output from the speaker and whose attribute values match the attribute values stored in the memory in S37, Switch the audio service component of the speaker output so that one is output from the speaker as the next audio service component. In this way, all audio service components belonging to the same ensemble as the audio service component currently being output from the speaker and having attribute values matching those specified by the user are output from the speaker one after another for a predetermined time T. When the scanning of these audio service components is completed, the output from the speaker returns to the audio service component before the start of the scanning of all audio service components.

Claims

The scope of the claims

 1. A user is allowed to specify a language in advance, and when an interrupt broadcast occurs, an interrupt is permitted only when the language of the interrupt broadcast is a language specified in advance. Digital broadcast receiver.

 2. The user is allowed to specify in advance the language and / or type of the interrupt broadcast for which the user recognizes the interrupt, and when the interrupt broadcast occurs, the language and Z or type of the interrupt broadcast are set to the previously specified language and / or type. A digital broadcast receiver characterized in that interruption is allowed only when the type matches.

 3. Let the user specify the language in advance, and when the user instructs to switch the service component, the language of the program currently being broadcast in the service component to be switched to is the language specified in advance. A digital broadcast receiver characterized in that switching is allowed only when

 4. A receiver for receiving a digital audio broadcasting (DAB) signal including an ensemble transmitted in a frame including a main service channel (MSC) and a fast information channel (FIC), wherein the ensemble includes: Contains a plurality of service components and the FIC indicates the attributes of the service components,

 A radio frequency block (RFB) for tuning to a carrier frequency signal that carries one selected ensemble

 A demodulation block (D B) for demodulating the tuned carrier frequency signal to form a demodulation D A B signal;

The DAB data is decoded and all data in the specified ensemble is Channel decoder block (CDB) that forms all service components, and

 A microcomputer which controls the CDB and outputs one service component to be reproduced among all the service components.

 The microcomputer controls the CDB in response to the specified attribute data input by the user, and outputs the service component when the attribute of the service component matches the specified attribute data. Digital broadcast receiver.

A plurality of audio service components are combined into one ensemble, each ensemble is transmitted on a predetermined carrier assigned to each ensemble, and the carrier is received and selected by the user from among the ensembles. In a digital audio broadcast receiver configured to output an audio service component from an audio output unit,

 The audio service component scan operation member is set, and as the user operates the audio service component scan operation member, all the audio service components included in the currently received ensemble are sequentially output as appropriate in time. A digital audio broadcast receiver characterized by outputting from a means.

A plurality of audio service components are combined into one ensemble, each ensemble is transmitted on a predetermined carrier assigned to each ensemble, and the carrier is received and the audio selected by the user from the ensemble is selected. Audio output means Digital audio broadcast receivers that output from

 In addition to setting the audio service component scanning operation member, the user specifies a value for a predetermined attribute of the audio service component in advance, and the user operates the audio service component scanning operation member. In the currently received ensemble, all audio service components included in the ensemble whose attribute value matches the designated value are sequentially output from the audio output means for a predetermined period of time. Digital audio broadcast receiver.

7. The digital audio broadcast receiver according to claim 6, wherein the attribute is language, program type, or region.