JP7495222B2 - How to generate a transmission wave - Google Patents

Description

The present invention relates to broadcast transmission technology or broadcast reception technology.

Digital broadcasting services began in many countries in the late 1990s to replace traditional analog broadcasting services. Digital broadcasting services have achieved improvements in broadcast quality using error correction technology, multi-channel and HD (High Definition) using compression coding technology, and multimedia services using BML (Broadcast Markup Language) and HTML5 (Hyper Text Markup Language version 5).

In recent years, advanced digital broadcasting systems have been under study in many countries with the aim of further improving frequency usage efficiency, and achieving higher resolution and functionality.

JP 2016-14420 A

More than 10 years have passed since the current digital broadcasting service started, and broadcast receiving devices capable of receiving the current digital broadcasting service are widely available. For this reason, when starting the advanced digital broadcasting service that is currently under consideration, it is necessary to consider compatibility with the current digital broadcasting service. In other words, it is preferable to realize UHD (Ultra High Definition) video signals while maintaining the viewing environment of the current digital broadcasting service.

The system described in Patent Document 1 is a technology for achieving UHD broadcasting in digital broadcasting services. However, the system described in Patent Document 1 is intended to replace current digital broadcasting and does not take into consideration the maintenance of the viewing environment for current digital broadcasting services.

The objective of the present invention is to provide technology that can more suitably transmit or receive advanced digital broadcasting services with higher functionality while also taking into account compatibility with current digital broadcasting services.

The technology described in the claims is used as a means to solve the above problems.

As an example, a method for generating a transmission wave in which a 4K broadcast service and a 2K broadcast service are both transmitted, in which the 4K broadcast service and the 2K broadcast service are stored in different layers of a plurality of frequency segments obtained by dividing a predetermined frequency band of the broadcast wave, each of which is composed of a combination of different segments, and transmitted. In the TMCC information included in the transmission wave, 3-bit identification information capable of identifying whether the modulation method is synchronous modulation is set for each of the first layer in which the 4K broadcast service is stored and the second layer in which the 2K broadcast service is stored, and even if the modulation methods of both the first layer in which the 4K broadcast service is stored and the second layer in which the 2K broadcast service is stored are synchronous modulation, the 3-bit identification information set for the first layer in which the 4K broadcast service is stored and the 3-bit identification information set for the second layer in which the 2K broadcast service is stored may be set to different values.

The present invention provides a technology for more optimally transmitting or receiving advanced digital broadcasting services.

1 is a system configuration diagram of a broadcasting system according to an embodiment of the present invention. 1 is a block diagram of a broadcast receiving device according to an embodiment of the present invention. 2 is a detailed block diagram of a first tuner/demodulation unit of a broadcast receiving device according to an embodiment of the present invention. FIG. 2 is a detailed block diagram of a second tuner/demodulation unit of a broadcast receiving device according to an embodiment of the present invention. 4 is a detailed block diagram of a third tuner/demodulation unit of a broadcast receiving device according to an embodiment of the present invention. FIG. 4 is a detailed block diagram of a fourth tuner/demodulation unit of a broadcast receiving device according to an embodiment of the present invention. FIG. 2 is a detailed block diagram of a first decoder unit of a broadcast receiving device according to an embodiment of the present invention. FIG. 4 is a detailed block diagram of a second decoder section of a broadcast receiving device according to one embodiment of the present invention. FIG. 2 is a software configuration diagram of a broadcast receiving device according to an embodiment of the present invention. 2 is a configuration diagram of a broadcasting station server according to an embodiment of the present invention. FIG. 2 is a configuration diagram of a service provider server according to an embodiment of the present invention. 1 is a diagram illustrating a segment configuration related to digital broadcasting in one embodiment of the present invention. FIG. 1 is a diagram illustrating hierarchical allocation in hierarchical transmission related to digital broadcasting in one embodiment of the present invention. 2 is a diagram illustrating a generation process of an OFDM transmission wave related to digital broadcasting in one embodiment of the present invention. FIG. 1 is a diagram illustrating a basic configuration of a transmission path coding unit related to digital broadcasting in an embodiment of the present invention. 1 is a diagram illustrating segment parameters of an OFDM system related to digital broadcasting in one embodiment of the present invention. 1 is a diagram illustrating transmission signal parameters related to digital broadcasting in one embodiment of the present invention. FIG. 1 is a diagram illustrating the arrangement of pilot signals in a synchronous modulation segment related to digital broadcasting in one embodiment of the present invention. FIG. 1 is a diagram illustrating the arrangement of pilot signals in a differential modulation segment related to digital broadcasting in one embodiment of the present invention. FIG. 1 is a diagram illustrating bit allocation of a TMCC carrier for digital broadcasting in one embodiment of the present invention. 1 is a diagram illustrating bit allocation of TMCC information related to digital broadcasting in one embodiment of the present invention. 1 is a diagram illustrating transmission parameter information of TMCC information related to digital broadcasting in one embodiment of the present invention. FIG. 1 is a diagram illustrating system identification of TMCC information related to digital broadcasting in one embodiment of the present invention. FIG. 1 is a diagram illustrating a carrier modulation mapping method for TMCC information related to digital broadcasting in one embodiment of the present invention. 1 is a diagram illustrating frequency conversion processing identification of TMCC information related to digital broadcasting according to one embodiment of the present invention. FIG. 1 is a diagram illustrating physical channel number identification of TMCC information related to digital broadcasting in one embodiment of the present invention. 1 is a diagram illustrating an example of main signal identification of TMCC information related to digital broadcasting in one embodiment of the present invention. FIG. A diagram explaining 4K signal transmission layer identification of TMCC information related to digital broadcasting in one embodiment of the present invention. A diagram explaining additional layer transmission identification of TMCC information related to digital broadcasting in one embodiment of the present invention. 1 is a diagram illustrating identification of the coding rate of the inner code of TMCC information related to digital broadcasting in one embodiment of the present invention. FIG. 1 is a diagram illustrating bit allocation of a TMCC carrier for digital broadcasting in one embodiment of the present invention. 2 is a diagram illustrating bit allocation of an AC signal related to digital broadcasting in one embodiment of the present invention. FIG. 1 is a diagram illustrating the configuration identification of an AC signal related to digital broadcasting in one embodiment of the present invention. FIG. FIG. 2 is a diagram illustrating earthquake motion warning information of an AC signal related to digital broadcasting according to an embodiment of the present invention. 1 is a diagram illustrating signal identification of earthquake motion warning information of an AC signal related to digital broadcasting according to an embodiment of the present invention. FIG. 1 is a diagram illustrating earthquake motion warning detail information of earthquake motion warning information of an AC signal related to digital broadcasting according to an embodiment of the present invention. FIG. 1 is a diagram illustrating earthquake motion warning detail information of earthquake motion warning information of an AC signal related to digital broadcasting according to an embodiment of the present invention. FIG. 10A and 10B are diagrams for explaining additional information related to transmission control of modulated waves of AC signals in digital broadcasting according to an embodiment of the present invention. 10A and 10B are diagrams illustrating additional information of transmission parameters of an AC signal related to digital broadcasting according to an embodiment of the present invention. 1 is a diagram illustrating an error correction method for an AC signal related to digital broadcasting in one embodiment of the present invention. 1 is a diagram illustrating the NUC format of an AC signal related to digital broadcasting in one embodiment of the present invention. FIG. 1 is a diagram illustrating a dual-polarized transmission system according to an embodiment of the present invention; 1 is a system configuration diagram of a broadcasting system using a dual-polarized transmission method according to an embodiment of the present invention. 1 is a system configuration diagram of a broadcasting system using a dual-polarized transmission method according to an embodiment of the present invention. FIG. 4 is a diagram illustrating a frequency conversion process according to an embodiment of the present invention. 1 is a diagram illustrating the configuration of a pass-through transmission method according to one embodiment of the present invention. FIG. 2 is a diagram illustrating a pass-through transmission band according to one embodiment of the present invention. 1 is a diagram illustrating the configuration of a pass-through transmission method according to one embodiment of the present invention. FIG. 2 is a diagram illustrating a pass-through transmission band according to one embodiment of the present invention. FIG. 2 is a diagram illustrating a pass-through transmission band according to one embodiment of the present invention. 1 is a diagram illustrating a hierarchical division multiplexing transmission method according to one embodiment of the present invention. 1 is a system configuration diagram of a broadcasting system using a hierarchical division multiplexing transmission method according to one embodiment of the present invention. 5A to 5C are diagrams illustrating a frequency conversion and amplification process according to an embodiment of the present invention. A diagram explaining the protocol stack of MPEG-2 TS. A diagram explaining the names and functions of tables used in MPEG-2 TS. A diagram explaining the names and functions of tables used in MPEG-2 TS. A diagram explaining the names and functions of descriptors used in MPEG-2 TS. A diagram explaining the names and functions of descriptors used in MPEG-2 TS. A diagram explaining the names and functions of descriptors used in MPEG-2 TS. A diagram explaining the names and functions of descriptors used in MPEG-2 TS. A diagram explaining the names and functions of descriptors used in MPEG-2 TS. A diagram explaining the names and functions of descriptors used in MPEG-2 TS. FIG. 1 is a diagram illustrating a protocol stack in an MMT broadcast transmission path. FIG. 1 is a diagram illustrating a protocol stack in an MMT communication line. A diagram explaining the names and functions of tables used in MMT TLV-SI. A diagram explaining the names and functions of the descriptors used in MMT TLV-SI. A diagram explaining the names and functions of messages used in MMT-SI of MMT. A diagram explaining the names and functions of tables used in MMT-SI of MMT. A diagram explaining the names and functions of descriptors used in MMT-SI of MMT. A diagram explaining the names and functions of descriptors used in MMT-SI of MMT. A diagram explaining the names and functions of descriptors used in MMT-SI of MMT. FIG. 2 is a diagram for explaining the relationship between data transmission in the MMT method and each table. 4 is an operational sequence diagram of a channel setting process of the broadcast receiving device 100 according to an embodiment of the present invention. FIG. FIG. 4 is a diagram illustrating a data configuration of a network information table. FIG. 13 is a diagram for explaining the data structure of a terrestrial distribution system descriptor. 11 is a diagram illustrating the data structure of a service list descriptor. 11 is a diagram illustrating the data structure of a TS information descriptor. 1 is an external view of a remote controller according to an embodiment of the present invention. 11A and 11B are diagrams illustrating a banner display when a channel is selected in accordance with an embodiment of the present invention. 1 is a diagram illustrating an example of a reception range of hierarchical division multiplexing terrestrial digital broadcasting. 1 is a diagram illustrating an example of a modulated wave of hierarchical division multiplexing terrestrial digital broadcasting. FIG. 1 is a diagram illustrating an example of additional information on transmission parameters of an AC signal related to digital broadcasting according to an embodiment of the present invention. 1 is a diagram illustrating an example of injection level state identification of an AC signal related to digital broadcasting according to an embodiment of the present invention. FIG. 1 is a diagram illustrating an example of injection level state identification of an AC signal related to digital broadcasting in an embodiment of the present invention. FIG. 10 is an explanatory diagram of an example of an operation sequence of a rescanning process of the broadcast receiving device 100 according to an embodiment of the present invention. FIG. 1 is a diagram illustrating modulated waves of hierarchical division multiplexing terrestrial digital broadcasting. FIG. 1 is a diagram illustrating frequency interleaving. FIG. 1 is a diagram illustrating frequency deinterleaving. FIG. 1 is a diagram illustrating frequency deinterleaving. 1 is a diagram illustrating hierarchical allocation in hierarchical transmission related to digital broadcasting in one embodiment of the present invention. FIG. 1 is a block diagram of a broadcast receiving device according to an embodiment of the present invention. 2 is a detailed block diagram of a second tuner/demodulation unit of a broadcast receiving device according to an embodiment of the present invention. 4 is a detailed block diagram of a second demodulation unit of a broadcast receiving device according to an embodiment of the present invention. FIG. 1 is a configuration diagram of a broadcasting system according to an embodiment of the present invention.

Below, an example embodiment of the present invention will be described with reference to the drawings.

Example 1
[System configuration]
FIG. 1 is a system configuration diagram showing an example of the configuration of a broadcasting system.

The broadcasting system is composed of, for example, a broadcast receiving device 100 and an antenna 200, a broadcasting station radio tower 300 and a broadcasting station server 400, a service provider server 500, a mobile telephone communication server 600 and a base station 600B of a mobile telephone communication network, a mobile information terminal 700, a broadband network 800 such as the Internet, and a router device 800R. In addition, various server devices and communication devices may be further connected to the Internet 800.

The broadcast receiving device 100 is a television receiver equipped with a receiving function for an advanced digital broadcasting service. The broadcast receiving device 100 may further be equipped with a receiving function for an existing digital broadcasting service. Furthermore, the broadcast receiving device 100 can be compatible with a broadcasting and communication linkage system that links a digital broadcasting service (an existing digital broadcasting service or an advanced digital broadcasting service) with a function using a broadband network, and combines the acquisition of additional content via a broadband network, arithmetic processing in a server device, and presentation processing in cooperation with a mobile terminal device with the digital broadcasting service. The broadcast receiving device 100 receives digital broadcast waves sent from a radio tower 300 via an antenna 200. The digital broadcast waves may be directly transmitted from the radio tower 300 to the antenna 200, or may be transmitted via a broadcasting satellite or a communication satellite (not shown). The broadcasting signal retransmitted by a cable television station may be received via a cable line or the like. The broadcast receiving device 100 can also be connected to the Internet 800 via a router device 800R, and can transmit and receive data by communicating with each server device on the Internet 800.

The router device 800R is connected to the Internet 800 by wireless or wired communication, and is also connected to the broadcast receiving device 100 by wired communication and to the mobile information terminal 700 by wireless communication. This allows each server device on the Internet 800, the broadcast receiving device 100, and the mobile information terminal 700 to transmit and receive data to and from each other via the router device 800R. The router device 800R, the broadcast receiving device 100, and the mobile information terminal 700 form a LAN (Local Area Network). Note that communication between the broadcast receiving device 100 and the mobile information terminal 700 may be performed directly using a method such as BlueTooth (registered trademark) or NFC (Near Field Communication) without going through the router device 800R.

The radio tower 300 is the broadcasting equipment of the broadcasting station, and transmits digital broadcast waves including various control information related to digital broadcasting services and content data of broadcast programs (video content, audio content, etc.). The broadcasting station also includes a broadcasting station server 400. The broadcasting station server 400 stores the content data of broadcast programs and metadata of each broadcast program, such as the program title, program ID, program summary, cast, broadcast date and time, etc. The broadcasting station server 400 provides the content data and metadata to the service provider based on a contract. The content data and metadata are provided to the service provider through an API (Application Programming Interface) provided by the broadcasting station server 400.

The service provider server 500 is a server device prepared by a service provider to provide services through the broadcasting and communication cooperation system. The service provider server 500 stores, manages, and distributes the content data and metadata provided by the broadcasting station server 400, and the content data and applications (operating programs and/or various data, etc.) created for the broadcasting and communication cooperation system. It also has a function of searching for and providing a list of available applications in response to inquiries from television receivers. The storage, management, and distribution of the content data and metadata and the storage, management, and distribution of the applications may be performed by different server devices. The broadcasting station and the service provider may be the same or different providers. A plurality of service provider servers 500 may be prepared for each different service. The functions of the service provider server 500 may also be provided by the broadcasting station server 400.

The mobile telephone communication server 600 is connected to the Internet 800, and is also connected to the mobile information terminal 700 via a base station 600B. The mobile telephone communication server 600 manages telephone communications (calls) and data transmission/reception of the mobile information terminal 700 via the mobile telephone communication network, and enables data transmission/reception through communication between the mobile information terminal 700 and each server device on the Internet 800. Note that communication between the mobile information terminal 700 and the broadcast receiving device 100 may be performed via the base station 600B, the mobile telephone communication server 600, the Internet 800, and the router device 800R.

[Hardware configuration of broadcast receiving device]
FIG. 2A is a block diagram showing an example of the internal configuration of the broadcast receiving device 100.

The broadcast receiving device 100 is composed of a main control unit 101, a system bus 102, a ROM 103, a RAM 104, a storage (accumulation) unit 110, a LAN communication unit 121, an expansion interface unit 124, a digital interface unit 125, a first tuner/demodulation unit 130C, a second tuner/demodulation unit 130T, a third tuner/demodulation unit 130L, a fourth tuner/demodulation unit 130B, a first decoder unit 140S, a second decoder unit 140U, an operation input unit 180, a video selection unit 191, a monitor unit 192, a video output unit 193, an audio selection unit 194, a speaker unit 195, and an audio output unit 196.

The main control unit 101 is a microprocessor unit that controls the entire broadcast receiving device 100 according to a predetermined operating program. The system bus 102 is a communication path for transmitting and receiving various data, commands, etc. between the main control unit 101 and each operating block within the broadcast receiving device 100.

ROM (Read Only Memory) 103 is a non-volatile memory that stores basic operation programs such as an operating system and other operation programs, and may be a rewritable ROM such as an EEPROM (Electrically Erasable Programmable ROM) or a flash ROM. ROM 103 also stores operation setting values and the like required for the operation of broadcast receiving device 100. RAM (Random Access Memory) 104 serves as a work area when the basic operation programs and other operation programs are executed. ROM 103 and RAM 104 may be integrated with main control unit 101. ROM 103 may not be an independent configuration as shown in FIG. 2A, but may use a portion of the storage area in storage unit 110.

The storage (accumulation) unit 110 stores the operation program and operation setting values of the broadcast receiving device 100, personal information of the user of the broadcast receiving device 100, etc. It can also store operation programs downloaded via the Internet 800 and various data created by the operation programs. It can also store content such as videos, still images, and audio acquired from broadcast waves or downloaded via the Internet 800. A portion of the storage (accumulation) unit 110 may replace all or part of the functions of the ROM 103. The storage (accumulation) unit 110 must retain the stored information even when power is not being supplied from an external source to the broadcast receiving device 100. Therefore, for example, devices such as flash ROM, semiconductor element memories such as SSDs (Solid State Drives), and magnetic disk drives such as HDDs (Hard Disc Drives) are used.

The operating programs stored in the ROM 103 and the storage unit 110 can be added to, updated, and have their functions expanded by downloading from each server device on the Internet 800 or from broadcast waves.

The LAN communication unit 121 is connected to the Internet 800 via the router device 800R, and transmits and receives data to and from each server device and other communication devices on the Internet 800. It also acquires program content data (or a part of it) transmitted via a communication line. The connection to the router device 800R may be a wired connection, or a wireless connection such as Wi-Fi (registered trademark). The LAN communication unit 121 includes an encoding circuit, a decoding circuit, and the like. The broadcast receiving device 100 may also include other communication units such as a BlueTooth (registered trademark) communication unit, an NFC communication unit, or an infrared communication unit.

The first tuner/demodulator 130C, the second tuner/demodulator 130T, the third tuner/demodulator 130L, and the fourth tuner/demodulator 130B each receive broadcast waves of a digital broadcast service, and perform channel selection processing (channel selection) by tuning to a channel of a specified service under the control of the main control unit 101. Furthermore, they perform demodulation processing and waveform shaping processing of the modulated wave of the received signal, as well as frame structure and hierarchical structure reconstruction processing, energy despreading processing, error correction decoding processing, etc., to reproduce a packet stream. They also extract and decode a transmission TMCC (Transmission Multiplexing Configuration Control) signal from the received signal.

The first tuner/demodulator 130C can receive digital broadcast waves of the current terrestrial digital broadcast service received by the antenna 200C, which is a current terrestrial digital broadcast receiving antenna. The first tuner/demodulator 130C can also receive a broadcast signal of one of the horizontal (H) and vertical (V) polarization signals of the dual-polarized terrestrial digital broadcasting described below, and demodulate a hierarchical segment that employs the same modulation method as the current terrestrial digital broadcasting service. The first tuner/demodulator 130C can also receive a broadcast signal of the hierarchical division multiplexed terrestrial digital broadcasting described below, and demodulate a hierarchical segment that employs the same modulation method as the current terrestrial digital broadcasting service. The second tuner/demodulator 130T receives digital broadcast waves of the advanced terrestrial digital broadcasting service received by the antenna 200T, which is a dual-polarized terrestrial digital broadcast receiving antenna, via the converter 201T. The third tuner/demodulator 130L inputs the digital broadcast waves of the advanced terrestrial digital broadcasting service received by the antenna 200L, which is an antenna for receiving hierarchical division multiplexed terrestrial digital broadcasting, via the converter 201L. The fourth tuner/demodulator 130B inputs the digital broadcast waves of the advanced BS (Broadcasting Satellite) digital broadcasting service and the advanced CS (Communication Satellite) digital broadcasting service received by the antenna 200B, which is an antenna for receiving both BS and CS, via the converter 201B.

The term "tuner/demodulation unit" refers to a component that has both tuner and demodulation functions.

In addition, antenna 200C, antenna 200T, antenna 200L, antenna 200B, conversion unit 201T, conversion unit 201L, and conversion unit 201B do not constitute part of broadcast receiving device 100, but belong to the facility side, such as the building in which broadcast receiving device 100 is installed.

The current terrestrial digital broadcasting mentioned above is a broadcast signal for a terrestrial digital broadcasting service that transmits video with a maximum resolution of 1920 pixels horizontal by 1080 pixels vertical.

The details of dual-polarized terrestrial digital broadcasting (advanced terrestrial digital broadcasting that employs a dual-polarized transmission method) will be described later, but it is a broadcast signal of a terrestrial digital broadcasting service that can transmit video with a maximum resolution of more than 1920 horizontal pixels by 1080 vertical pixels. Dual-polarized terrestrial digital broadcasting is terrestrial digital broadcasting that uses multiple polarized waves, horizontal (H) polarization and vertical (V) polarization, and transmits a terrestrial digital broadcasting service that can transmit video with a maximum resolution of more than 1920 horizontal pixels by 1080 vertical pixels in some divided segments in both polarized waves.

In the description of each embodiment of the present invention, when the expression "multiple polarized waves" is used in relation to dual polarized terrestrial digital broadcasting, unless otherwise specified, it means two polarized waves, horizontal (H) polarized waves and vertical (V) polarized waves. In addition, when the expression "polarized waves" is simply used, it means a "polarized signal". In addition, in one or both of the multiple polarized waves, some of the divided segments can transmit the above-mentioned current terrestrial digital broadcasting, which transmits video with a maximum resolution of 1920 pixels horizontally x 1080 pixels vertically, using the same modulation method. In other words, in dual polarized terrestrial digital broadcasting, different segments of the multiple polarized waves in each embodiment of the present invention can simultaneously transmit the current terrestrial digital broadcasting service that transmits video with a maximum resolution of 1920 pixels horizontally x 1080 pixels vertically, and the terrestrial digital broadcasting service that can transmit video with a maximum resolution of more than 1920 pixels horizontally x 1080 pixels vertically.

In addition, the details of hierarchical division multiplexing terrestrial digital broadcasting (advanced terrestrial digital broadcasting using a hierarchical division multiplexing transmission method) will be described later, but it is a broadcast signal of a terrestrial digital broadcasting service capable of transmitting video with a maximum resolution of more than 1920 pixels horizontally x 1080 pixels vertically. Hierarchical division multiplexing terrestrial digital broadcasting multiplexes multiple digital broadcasting signals with different signal levels. Note that digital broadcasting signals with different signal levels mean that the power for transmitting the digital broadcasting signals is different. In the hierarchical division multiplexing terrestrial digital broadcasting of each embodiment of the present invention, as the multiple digital broadcasting signals with different signal levels, the broadcast signal of the current terrestrial digital broadcasting service that transmits video with a maximum resolution of 1920 pixels horizontally x 1080 pixels vertically and the broadcast signal of the terrestrial digital broadcasting service that can transmit video with a maximum resolution of more than 1920 pixels horizontally x 1080 pixels vertically can be hierarchically multiplexed and transmitted in the frequency band of the same physical channel. In other words, in the hierarchical division multiplexing terrestrial digital broadcasting of each embodiment of the present invention, it is possible to simultaneously transmit, on multiple hierarchical layers with different signal levels, a current terrestrial digital broadcasting service that transmits video with a maximum resolution of 1920 pixels horizontal by 1080 pixels vertical, and a terrestrial digital broadcasting service that can transmit video with a maximum resolution of more than 1920 pixels horizontal by 1080 pixels vertical.

The broadcast receiving device in each embodiment of the present invention may be configured to be able to receive advanced digital broadcasts favorably, and does not necessarily have to include all of the first tuner/demodulation unit 130C, the second tuner/demodulation unit 130T, the third tuner/demodulation unit 130L, and the fourth tuner/demodulation unit 130B. For example, it is sufficient to include at least either the second tuner/demodulation unit 130T or the third tuner/demodulation unit 130L. Furthermore, in order to achieve more advanced functions, in addition to either the second tuner/demodulation unit 130T or the third tuner/demodulation unit 130L, one or more of the above four tuner/demodulation units may also be included.

In addition, antenna 200C, antenna 200T, and antenna 200L may be used in common as appropriate. In addition, among first tuner/demodulator 130C, second tuner/demodulator 130T, and third tuner/demodulator 130L, multiple tuner/demodulators may be used in common (or integrated) as appropriate.

The first decoder unit 140S and the second decoder unit 140U respectively input packet streams output from the first tuner/demodulator unit 130C, the second tuner/demodulator unit 130T, the third tuner/demodulator unit 130L, and the fourth tuner/demodulator unit 130B, or packet streams acquired from each server device on the Internet 800 via the LAN communication unit 121. The packet streams input by the first decoder unit 140S and the second decoder unit 140U may be packet streams in formats such as MPEG (Moving Picture Experts Group)-2 TS (Transport Stream), MPEG-2 PS (Program Stream), TLV (Type Length Value), and MMT (MPEG Media Transport).

The first decoder unit 140S and the second decoder unit 140U each perform a conditional access (CA) process, a demultiplexing process for separating and extracting video data, audio data, and various information data from the packet stream based on various control information contained in the packet stream, a video and audio data decode process, a program information acquisition process and an EPG (Electronic Program Guide) generation process, a data broadcast screen and a multimedia data playback process, etc. In addition, the first decoder unit 140S and the second decoder unit 140U each perform a process for superimposing the generated EPG and the played multimedia data with the decoded video data and audio data.

The video selection unit 191 inputs the video data output from the first decoder unit 140S and the video data output from the second decoder unit 140U, and performs appropriate processing such as selection and/or superimposition based on the control of the main control unit 101. The video selection unit 191 also performs appropriate scaling processing and superimposition processing of OSD (On Screen Display) data. The monitor unit 192 is a display device such as a liquid crystal panel, and displays the video data selected and/or superimposed by the video selection unit 191 and provides it to the user of the broadcast receiving device 100. The video output unit 193 is a video output interface that outputs the video data selected and/or superimposed by the video selection unit 191 to the outside.

The audio selection unit 194 inputs the audio data output from the first decoder unit 140S and the audio data output from the second decoder unit 140U, and performs appropriate processing such as selection and/or mixing based on the control of the main control unit 101. The speaker unit 195 outputs the audio data selected and/or mixed by the audio selection unit 194 and provides it to the user of the broadcast receiving device 100. The audio output unit 196 is an audio output interface that outputs the audio data selected and/or mixed by the audio selection unit 194 to the outside.

The digital interface unit 125 is an interface that outputs or inputs a packet stream including encoded digital video data and/or digital audio data. The digital interface unit 125 can directly output the packet stream input by the first decoder unit 140S or the second decoder unit 140U from the first tuner/demodulator unit 130C, the second tuner/demodulator unit 130T, the third tuner/demodulator unit 130L, or the fourth tuner/demodulator unit 130B. In addition, the digital interface unit 125 may control the packet stream input from the outside via the digital interface unit 125 to be input to the first decoder unit 140S or the second decoder unit 140U, or to be stored in the storage (accumulation) unit 110. Alternatively, the video data or audio data separated and extracted by the first decoder unit 140S or the second decoder unit 140U may be output. In addition, the digital interface unit 125 may control the video data or audio data input from the outside via the digital interface unit 125 to be input to the first decoder unit 140S or the second decoder unit 140U, or to be stored in the storage (accumulation) unit 110.

The expansion interface unit 124 is a group of interfaces for expanding the functions of the broadcast receiving device 100, and is composed of an analog video/audio interface, a USB (Universal Serial Bus) interface, a memory interface, etc. The analog video/audio interface inputs analog video/audio signals from external video/audio output devices, outputs analog video/audio signals to external video/audio input devices, etc. The USB interface connects to a PC or the like to send and receive data. A HDD may be connected to record broadcast programs and other content data. A keyboard or other USB device may also be connected. The memory interface connects to a memory card or other memory medium to send and receive data.

The operation input unit 180 is an instruction input unit that inputs operation instructions to the broadcast receiving device 100, and is composed of a remote control receiving unit that receives commands transmitted from a remote control (remote controller) (not shown), and an operation key with an array of button switches. Only one of them may be used. The operation input unit 180 can also be replaced by a touch panel or the like placed over the monitor unit 192. It may also be replaced by a keyboard or the like connected to the extended interface unit 124. The remote control can be replaced by a mobile information terminal 700 equipped with a remote control command transmission function.

When the broadcast receiving device 100 is a television receiver or the like, the video output unit 193 and the audio output unit 196 are not essential components. The broadcast receiving device 100 may also be an optical disk drive recorder such as a DVD (Digital Versatile Disc) recorder, a magnetic disk drive recorder such as a HDD recorder, an STB (Set Top Box), etc. It may also be a PC (Personal Computer) or a tablet terminal equipped with a function for receiving digital broadcast services. When the broadcast receiving device 100 is a DVD recorder, an HDD recorder, an STB, etc., the monitor unit 192 and the speaker unit 195 are not essential components. By connecting an external monitor and an external speaker to the video output unit 193 and the audio output unit 196 or the digital interface unit 125, the same operation as a television receiver or the like is possible.

Figure 2B is a block diagram showing an example of a detailed configuration of the first tuner/demodulator unit 130C.

The channel selection/detection unit 131C inputs the current digital broadcast wave received by the antenna 200C and selects a channel based on the channel selection control signal. The TMCC decoding unit 132C extracts the TMCC signal from the output signal of the channel selection/detection unit 131C and acquires various TMCC information. The acquired TMCC information is used to control each process in the subsequent stages. Details of the TMCC signal and TMCC information will be described later.

The demodulation unit 133C inputs a modulated wave modulated using a method such as QPSK (Quadrature Phase Shift Keying), DQPSK (Differential QPSK), 16QAM (Quadrature Amplitude Modulation), or 64QAM based on TMCC information, and performs demodulation processing including frequency deinterleaving, time deinterleaving, and carrier demapping processing. The demodulation unit 133C may also be capable of supporting modulation methods different from the above-mentioned modulation methods.

The stream playback unit 134C performs layer division processing, inner code error correction processing such as Viterbi decoding, energy despreading processing, stream playback processing, outer code error correction processing such as RS (Reed Solomon) decoding, etc. Note that the error correction processing may be a method other than those described above. Also, the packet stream played and output by the stream playback unit 134C is, for example, MPEG-2 TS, etc. Other formats of packet streams may also be used.

Figure 2C is a block diagram showing an example of a detailed configuration of the second tuner/demodulator unit 130T.

The channel selection/detection unit 131H inputs the horizontal (H) polarized signal of the digital broadcast wave received by the antenna 200T, and performs channel selection based on the channel selection control signal. The channel selection/detection unit 131V inputs the vertical (V) polarized signal of the digital broadcast wave received by the antenna 200T, and performs channel selection based on the channel selection control signal. Note that the operation of the channel selection process in the channel selection/detection unit 131H and the operation of the channel selection process in the channel selection/detection unit 131V may be controlled in conjunction with each other, or may be controlled independently of each other. That is, it is possible to treat the channel selection/detection unit 131H and the channel selection/detection unit 131V as one channel selection/detection unit and control them to select one channel of a digital broadcasting service transmitted using both horizontal and vertical polarization, or it is possible to treat the channel selection/detection unit 131H and the channel selection/detection unit 131V as two independent channel selection/detection units and control them to select two different channels of a digital broadcasting service transmitted using only horizontal polarization (or only vertical polarization).

In addition, the horizontally (H) polarized signal and the vertically (V) polarized signal received by the second tuner/demodulation unit 130T of the broadcast receiving device in each embodiment of the present invention may be polarized signals of broadcast waves whose polarization directions differ by approximately 90 degrees, and the horizontally (H) polarized signal and the vertically (V) polarized signal described below and the configuration related to their reception may be reversed.

The TMCC decoding unit 132H extracts the TMCC signal from the output signal of the tuning/detection unit 131H to obtain various TMCC information. The TMCC decoding unit 132V extracts the TMCC signal from the output signal of the tuning/detection unit 131V to obtain various TMCC information. Only one of the TMCC decoding unit 132H and the TMCC decoding unit 132V may be present. The obtained TMCC information is used to control each process in the subsequent stages.

The demodulation units 133H and 133V each input a modulated wave modulated using a method such as BPSK (Binary Phase Shift Keying), DBPSK (Differential BPSK), QPSK, DQPSK, 8PSK (Phase Shift Keying), 16APSK (Amplitude and Phase Shift Keying), 32APSK, 16QAM, 64QAM, 256QAM, 1024QAM, etc. based on TMCC information, etc., and perform demodulation processing including frequency deinterleaving, time deinterleaving, carrier demapping processing, etc. The demodulation units 133H and 133V may also be capable of supporting modulation methods other than the above-mentioned modulation methods.

The stream reproduction unit 134H and the stream reproduction unit 134V each perform hierarchical division processing, inner code error correction processing such as Viterbi decoding and LDPC (Low Density Parity Check) decoding, energy despreading processing, stream reproduction processing, outer code error correction processing such as RS decoding and BCH decoding, etc. Note that the error correction processing may be a method other than those described above. The packet stream reproduced and output by the stream reproduction unit 134H is, for example, MPEG-2 TS, etc. The packet stream reproduced and output by the stream reproduction unit 134V is, for example, MPEG-2 TS or TLV including an MMT packet stream, etc. Each may be a packet stream of another format.

Figure 2D is a block diagram showing an example of a detailed configuration of the third tuner/demodulator unit 130L.

The channel selection/detection unit 131L inputs digital broadcast waves that have been subjected to layered division multiplexing (LDM) processing from the antenna 200L, and selects a channel based on a channel selection control signal. The digital broadcast waves that have been subjected to layered division multiplexing processing may be used to transmit different digital broadcast services (or different channels of the same broadcast service) in which the modulated waves in the upper layer (Upper Layer: UL) and the lower layer (Lower Layer: LL) are different. In addition, the modulated waves in the upper layer are output to the demodulation unit 133S, and the modulated waves in the lower layer are output to the demodulation unit 133L.

The TMCC decoding unit 132L receives the modulated wave of the upper layer and the modulated wave of the lower layer output from the tuning/detection unit 131L, extracts the TMCC signal, and obtains various TMCC information. The signal input to the TMCC decoding unit 132L may be either the modulated wave of the upper layer or the modulated wave of the lower layer.

Since demodulation unit 133S and demodulation unit 133L perform the same operations as demodulation unit 133H and demodulation unit 133V, detailed explanations are omitted. Also, since stream reproduction unit 134S and stream reproduction unit 134L perform the same operations as stream reproduction unit 134H and stream reproduction unit 134V, detailed explanations are omitted.

Figure 2E is a block diagram showing an example of a detailed configuration of the fourth tuner/demodulator unit 130B.

The channel selection/detection unit 131B inputs the digital broadcasting waves of the advanced BS digital broadcasting service or the advanced CS digital broadcasting service received by the antenna 200B, and selects a channel based on the channel selection control signal. Other operations are similar to those of the channel selection/detection unit 131H and the channel selection/detection unit 131V, so detailed explanations are omitted. In addition, the TMCC decoding unit 132B, the demodulation unit 133B, and the stream reproduction unit 134B perform the same operations as the TMCC decoding unit 132H and the TMCC decoding unit 132V, the demodulation unit 133H and the demodulation unit 133V, and the stream reproduction unit 134V, respectively, so detailed explanations are omitted.

Figure 2F is a block diagram showing an example of a detailed configuration of the first decoder unit 140S.

The selection unit 141S selects and outputs one of the packet streams input from the first tuner/demodulation unit 130C, the second tuner/demodulation unit 130T, and the third tuner/demodulation unit 130L under the control of the main control unit 101. The packet streams input from the first tuner/demodulation unit 130C, the second tuner/demodulation unit 130T, and the third tuner/demodulation unit 130L are, for example, MPEG-2 TS. The CA descrambler 142S performs decryption processing of the encryption algorithm of a specified scrambling method based on various control information related to limited reception superimposed on the packet stream.

The demultiplexing unit 143S is a stream decoder, and separates and extracts video data, audio data, superimposed text data, subtitle data, program information data, etc., based on various control information contained in the input packet stream. The separated and extracted video data is distributed to the video decoder 145S, the separated and extracted audio data to the audio decoder 146S, and the separated and extracted superimposed text data, subtitle data, program information data, etc. to the data decoder 144S. The demultiplexing unit 143S may receive a packet stream (e.g., MPEG-2 PS, etc.) acquired from a server device on the Internet 800 via the LAN communication unit 121. The demultiplexing unit 143S can also output the packet streams input from the first tuner/demodulation unit 130C, the second tuner/demodulation unit 130T, or the third tuner/demodulation unit 130L to the outside via the digital interface 125, and can receive a packet stream acquired from the outside via the digital interface 125.

The video decoder 145S performs decoding of compressed and encoded video information, colorimetry conversion and dynamic range conversion of the decoded video information, etc., for the video data input from the demultiplexer 143S. It also performs resolution conversion (up/down conversion) and other processes based on the control of the main controller 101, and outputs video data at a resolution of UHD (3840 pixels horizontal x 2160 pixels vertical), HD (1920 pixels horizontal x 1080 pixels vertical), SD (720 pixels horizontal x 480 pixels vertical), etc., as appropriate. It may also output video data at other resolutions. The audio decoder 146S performs decoding of compressed and encoded audio information, etc. It also performs downmixing and other processes based on the control of the main controller 101, and outputs audio data with a number of channels such as 22.2ch, 7.1ch, 5.1ch, or 2ch. Note that a plurality of video decoders 145S and audio decoders 146S may be provided in order to simultaneously perform multiple decoding processes of video data and audio data.

The data decoder 144S performs processes such as generating an EPG based on program information data, generating a data broadcast screen based on BML data, and controlling an integrated application based on a broadcast communication integration function. The data decoder 144S has a BML browser function that executes BML documents, and the data broadcast screen generation process is executed by the BML browser function. The data decoder 144S also performs processes such as decoding superimposed data to generate superimposed information and decoding subtitle data to generate subtitle information.

The superimposing unit 147S, the superimposing unit 148S, and the superimposing unit 149S each perform a superimposing process of the video data output from the video decoder 145S and the EPG or data broadcast screen output from the data decoder 144S. The synthesis unit 151S performs a process of synthesizing the audio data output from the audio decoder 146S and the audio data reproduced by the data decoder 144S. The selection unit 150S selects the resolution of the video data based on the control of the main control unit 101. Note that the functions of the superimposing unit 147S, the superimposing unit 148S, the superimposing unit 149S, and the selection unit 150S may be integrated with the video selection unit 191. The function of the synthesis unit 151S may be integrated with the audio selection unit 194.

Figure 2G is a block diagram showing an example of a detailed configuration of the second decoder unit 140U.

The selection unit 141U selects and outputs one of the packet streams input from the second tuner/demodulation unit 130T, the third tuner/demodulation unit 130L, and the fourth tuner/demodulation unit 130B under the control of the main control unit 101. The packet streams input from the second tuner/demodulation unit 130T, the third tuner/demodulation unit 130L, and the fourth tuner/demodulation unit 130B are, for example, MMT packet streams or TLVs including MMT packet streams. They may also be MPEG-2 TS format packet streams that employ HEVC (High Efficiency Video Coding) or the like as the video compression method. The CA descrambler 142U performs decryption processing of the encryption algorithm of a predetermined scrambling method based on various control information related to limited reception superimposed on the packet stream.

The demultiplexing unit 143U is a stream decoder, and separates and extracts video data, audio data, superimposed text data, subtitle data, program information data, etc., based on various control information contained in the input packet stream. The separated and extracted video data is distributed to the video decoder 145U, the separated and extracted audio data to the audio decoder 146U, and the separated and extracted superimposed text data, subtitle data, program information data, etc. to the multimedia decoder 144U. The demultiplexing unit 143U may receive a packet stream (e.g., MPEG-2 PS or MMT packet stream, etc.) acquired from a server device on the Internet 800 via the LAN communication unit 121. The demultiplexing unit 143U can also output the packet streams input from the second tuner/demodulation unit 130T, the third tuner/demodulation unit 130L, or the fourth tuner/demodulation unit 130B to the outside via the digital interface 125, and can receive a packet stream acquired from the outside via the digital interface 125.

The multimedia decoder 144U performs processes such as generating an EPG based on program information data, generating a multimedia screen based on multimedia data, and controlling an integrated application based on a broadcast/communication integrated function. The multimedia decoder 144U has an HTML browser function that executes HTML documents, and the multimedia screen generation process is executed by the HTML browser function.

The video decoder 145U, the audio decoder 146U, the superimposition unit 147U, the superimposition unit 148U, the superimposition unit 149U, the synthesis unit 151U and the selection unit 150U are components that have the same functions as the video decoder 145S, the audio decoder 146S, the superimposition unit 147S, the superimposition unit 148S, the superimposition unit 149S, the synthesis unit 151S and the selection unit 150S, respectively. If the S at the end of the reference numbers is replaced with a U in the explanation of video decoder 145S, audio decoder 146S, superimposition unit 147S, superimposition unit 148S, superimposition unit 149S, synthesis unit 151S, and selection unit 150S in FIG. 2F, the explanation becomes that of video decoder 145U, audio decoder 146U, superimposition unit 147U, superimposition unit 148U, superimposition unit 149U, synthesis unit 151U, and selection unit 150U in FIG. 2G, and a separate detailed explanation will be omitted.

[Software configuration of broadcast receiving device]
2H is a software configuration diagram of the broadcast receiving device 100, and shows an example of the software configuration in the storage (accumulation) unit 110 (or ROM 103, the same below) and RAM 104. A basic operation program 1001, a receiving function program 1002, a browser program 1003, a content management program 1004, and other operation programs 1009 are stored in the storage (accumulation) unit 110. The storage (accumulation) unit 110 also includes a content storage area 1011 for storing content data such as moving images, still images, and audio, an authentication information storage area 1012 for storing authentication information used for communication and cooperation with external mobile terminal devices and server devices, and a various information storage area 1019 for storing various other information.

The basic operation program 1001 stored in the storage (accumulation) unit 110 is expanded in the RAM 104, and the main control unit 101 executes the expanded basic operation program to form a basic operation control unit 1101. The reception function program 1002, browser program 1003, and content management program 1004 stored in the storage (accumulation) unit 110 are each expanded in the RAM 104, and the main control unit 101 executes each of the expanded operation programs to form a reception function control unit 1102, a browser engine 1103, and a content management unit 1104. The RAM 104 also includes a temporary storage area 1200 that temporarily holds data created when each operation program is executed as necessary.

In the following, for ease of explanation, the process in which the main control unit 101 controls each operation block by expanding the basic operation program 1001 stored in the storage unit 110 into the RAM 104 and executing it will be described as the basic operation control unit 1101 controlling each operation block. Similar descriptions will be used for the other operation programs.

The reception function control unit 1102 performs basic control of the broadcast reception function and broadcast communication cooperation function of the broadcast receiving device 100. In particular, the channel selection/demodulation unit 1102a mainly controls channel selection processing, TMCC information acquisition processing, demodulation processing, etc. in the first tuner/demodulation unit 130C, the second tuner/demodulation unit 130T, the third tuner/demodulation unit 130L, the fourth tuner/demodulation unit 130B, etc. The stream playback control unit 1102b mainly controls hierarchical division processing, error correction decoding processing, energy despreading processing, stream playback processing, etc. in the first tuner/demodulation unit 130C, the second tuner/demodulation unit 130T, the third tuner/demodulation unit 130L, the fourth tuner/demodulation unit 130B, etc. The AV decoding unit 1102c mainly controls the demultiplexing process (stream decoding process), the video data decoding process, the audio data decoding process, etc. in the first decoder unit 140S and the second decoder unit 140H, etc. The multimedia (MM) data reproducing unit 1102d mainly controls the BML data reproducing process, the superimposed text data decoding process, the subtitle data decoding process, the control process of the communication-linked application in the first decoder unit 140S, the HTML data reproducing process, the multimedia screen generating process, the control process of the communication-linked application in the second decoder unit 140H, etc. The EPG generating unit 1102e mainly controls the EPG generating process and the display process of the generated EPG in the first decoder unit 140S and the second decoder unit 140H. The presentation processing unit 1102f controls colorimetry conversion processing, dynamic range conversion processing, resolution conversion processing, audio downmix processing, etc. in the first decoder unit 140S and the second decoder unit 140H, as well as controlling the video selection unit 191 and the audio selection unit 194, etc.

The BML browser 1103a and HTML browser 1103b of the browser engine 1103 interpret BML documents and HTML documents during the aforementioned BML data playback process and HTML data playback process, and perform data broadcast screen generation process and multimedia screen generation process.

The content management unit 1104 performs time schedule management and execution control when recording or viewing reservations for broadcast programs, copyright management when broadcast programs and recorded programs are output from the digital I/F 125 or the LAN communication unit 121, etc., and expiration date management of linked applications obtained based on the broadcast communication linkage function.

The operating programs may be stored in the storage unit 110 and/or ROM 103 before the product is shipped. After the product is shipped, the operating programs may be acquired from a server device on the Internet 800 via the LAN communication unit 121 or the like. In addition, the operating programs stored in a memory card, optical disk, or the like may be acquired via the extended interface unit 124 or the like. The operating programs may be newly acquired or updated via broadcast waves.

[Configuration of broadcasting station server]
3A shows an example of the internal configuration of the broadcast station server 400. The broadcast station server 400 is made up of a main control unit 401, a system bus 402, a RAM 404, a storage unit 410, a LAN communication unit 421, and a digital broadcast signal transmission unit 460.

The main control unit 401 is a microprocessor unit that controls the entire broadcasting station server 400 in accordance with a predetermined operation program. The system bus 402 is a communication path for transmitting and receiving various data, commands, etc. between the main control unit 401 and each operation block within the broadcasting station server 400. The RAM 404 serves as a work area when each operation program is executed.

The storage unit 410 stores a basic operation program 4001, a content management/distribution program 4002, and a content transmission program 4003, and further includes a content data storage area 4011 and a metadata storage area 4012. The content data storage area 4011 stores content data of each broadcast program broadcast by a broadcast station. The metadata storage area 4012 stores metadata such as the program title, program ID, program summary, cast, broadcast date and time, etc., of each broadcast program.

The basic operation program 4001, content management/distribution program 4002, and content sending program 4003 stored in the storage unit 410 are each expanded in the RAM 404, and the main control unit 401 executes the expanded basic operation program, content management/distribution program, and content sending program to form a basic operation control unit 4101, a content management/distribution control unit 4102, and a content sending control unit 4103.

In the following, for ease of explanation, the process in which the main control unit 401 controls each operation block by expanding the basic operation program 4001 stored in the storage unit 410 into the RAM 404 and executing it will be described as the basic operation control unit 4101 controlling each operation block. Similar descriptions will be used for the other operation programs.

The content management/distribution control unit 4102 manages the content data, metadata, etc. stored in the content data storage area 4011 and metadata storage area 4012, and controls the provision of the content data, metadata, etc. to the service provider based on a contract. Furthermore, the content management/distribution control unit 4102 also performs authentication processing of the service provider server 500 as necessary when providing the content data, metadata, etc. to the service provider.

The content transmission control unit 4103 performs time schedule management when transmitting the content data of the broadcast program stored in the content data storage area 4011 and the stream including the program title, program ID, and copy control information of the program content of the broadcast program stored in the metadata storage area 4012 via the digital broadcast signal transmission unit 460.

The LAN communication unit 421 is connected to the Internet 800, and communicates with the service provider server 500 and other communication devices on the Internet 800. The LAN communication unit 421 includes an encoding circuit, a decoding circuit, and the like. The digital broadcast signal sending unit 460 performs processing such as modulation on a stream composed of content data and program information data of each broadcast program stored in the content data storage area 4011, and sends it out as a digital broadcast wave via the radio tower 300.

[Configuration of service provider server]
3B shows an example of the internal configuration of the service provider server 500. The service provider server 500 is composed of a main control unit 501, a system bus 502, a RAM 504, a storage unit 510, and a LAN communication unit 521.

The main control unit 501 is a microprocessor unit that controls the entire service provider server 500 in accordance with a predetermined operation program. The system bus 502 is a communication path for sending and receiving various data, commands, etc. between the main control unit 501 and each operation block within the service provider server 500. The RAM 504 serves as a work area when each operation program is executed.

The storage unit 510 stores a basic operation program 5001, a content management/distribution program 5002, and an application management/distribution program 5003, and further includes a content data storage area 5011, a metadata storage area 5012, and an application storage area 5013. The content data storage area 5011 and the metadata storage area 5012 store content data and metadata provided by the broadcasting station server 400, or content produced by a service provider and metadata related to the content. The application storage area 5013 stores applications (operating programs and/or various data, etc.) required to realize each service of the broadcasting/communication cooperation system, for distribution in response to requests from each television receiver.

The basic operation program 5001, content management/distribution program 5002, and application management/distribution program 5003 stored in the storage unit 510 are each expanded in the RAM 504, and the main control unit 501 executes the expanded basic operation program, content management/distribution program, and application management/distribution program to form a basic operation control unit 5101, a content management/distribution control unit 5102, and an application management/distribution control unit 5103.

In the following, for ease of explanation, the process in which the main control unit 501 controls each operation block by expanding the basic operation program 5001 stored in the storage unit 510 into the RAM 504 and executing it will be described as the basic operation control unit 5101 controlling each operation block. Similar descriptions will be used for the other operation programs.

The content management/distribution control unit 5102 acquires content data, metadata, etc. from the broadcasting station server 400, manages the content data, metadata, etc. stored in the content data storage area 5011 and metadata storage area 5012, and controls the distribution of the content data, metadata, etc. to each television receiver. The application management/distribution control unit 5103 manages each application stored in the application storage area 5013, and controls the distribution of each application in response to a request from each television receiver. Furthermore, when distributing each application to each television receiver, the application management/distribution control unit 5103 also performs authentication processing of the television receiver as necessary.

The LAN communication unit 521 is connected to the Internet 800, and communicates with the broadcast station server 400 and other communication devices on the Internet 800. It also communicates with the broadcast receiving device 100 and the mobile information terminal 700 via the router device 800R. The LAN communication unit 521 includes an encoding circuit, a decoding circuit, etc.

[Digital broadcasting waves]
Here, an example of a digital broadcast wave received by the broadcast receiving device according to the embodiment of the present invention will be described.

The broadcast receiving device 100 is capable of receiving a terrestrial digital broadcasting service that shares at least some specifications with the ISDB-T (Integrated Services Digital Broadcasting for Terrestrial Television Broadcasting) system. Specifically, the dual-polarized terrestrial digital broadcasting that the second tuner/demodulator 130T can receive is an advanced terrestrial digital broadcasting that shares some specifications with the ISDB-T system. In addition, the hierarchical division multiplexed terrestrial digital broadcasting that the third tuner/demodulator 130L can receive is an advanced terrestrial digital broadcasting that shares some specifications with the ISDB-T system. The current terrestrial digital broadcasting that the first tuner/demodulator 130C can receive is the ISDB-T terrestrial digital broadcasting. In addition, the advanced BS digital broadcasting and advanced CS digital broadcasting that the fourth tuner/demodulator unit 130B can receive are digital broadcasting that differ from the ISDB-T system.

Here, the dual-polarized terrestrial digital broadcasting and hierarchical division multiplexing terrestrial digital broadcasting according to this embodiment adopts OFDM (Orthogonal Frequency Division Multiplexing), which is one of the multi-carrier methods, as the transmission method, just like the ISDB-T method. Since OFDM is a multi-carrier method, the symbol length is long, and it is effective to add a redundant portion in the time axis direction called a guard interval, and it is possible to reduce the effect of multipath within the range of the guard interval. Therefore, it is possible to realize a SFN (Single Frequency Network), which enables effective use of frequencies.

In the dual-polarized terrestrial digital broadcasting and hierarchical division multiplexing terrestrial digital broadcasting according to this embodiment, the OFDM carrier is divided into groups called segments, as in the ISDB-T system, and as shown in FIG. 4A, one channel bandwidth of a digital broadcasting service is composed of 13 segments. The center of the band is the position of segment 0, and segment numbers (0 to 12) are assigned sequentially above and below this. The transmission path coding of the dual-polarized terrestrial digital broadcasting and hierarchical division multiplexing terrestrial digital broadcasting according to this embodiment is performed in units of OFDM segments. For this reason, it is possible to define hierarchical transmission, and for example, within the bandwidth of one television channel, some OFDM segments can be assigned to fixed reception services and the rest to mobile reception services. In hierarchical transmission, each layer is composed of one or more OFDM segments, and parameters such as the carrier modulation method, the coding rate of the inner code, and the time interleave length can be set for each layer. The number of layers can be set arbitrarily, for example, up to a maximum of three layers. FIG. 4B shows an example of hierarchical allocation of OFDM segments when the number of layers is three or two. In the example of FIG. 4B(1), the number of layers is 3, with layer A consisting of 1 segment (segment 0), layer B consisting of 7 segments (segments 1-7), and layer C consisting of 5 segments (segments 8-12). In the example of FIG. 4B(2), the number of layers is 3, with layer A consisting of 1 segment (segment 0), layer B consisting of 5 segments (segments 1-5), and layer C consisting of 7 segments (segments 6-12). In the example of FIG. 4B(3), the number of layers is 2, with layer A consisting of 1 segment (segment 0), and layer B consisting of 12 segments (segments 1-12). The number of OFDM segments and transmission line coding parameters for each layer are determined according to the organization information and are transmitted by a TMCC signal, which is control information for assisting the operation of the receiver.

Note that the following is an example of a possible use case for the segment hierarchical allocation of (1), (2), and (3) in Figure 4B.

For example, the hierarchical allocation in FIG. 4B(1) can be used in the dual-polarized terrestrial digital broadcasting according to this embodiment, and the same segment hierarchical allocation can be used for both horizontal and vertical polarization. Specifically, the above one segment of horizontal polarization can be used as hierarchical A to transmit the current mobile reception service of terrestrial digital broadcasting. (Note that the same service for the mobile reception service of the current terrestrial digital broadcasting may be transmitted by the above one segment of vertical polarization. In this case, this is also treated as hierarchical A.) In addition, the above seven segments of horizontal polarization can be used as hierarchical B to transmit a terrestrial digital broadcasting service that transmits video with a maximum resolution of 1920 pixels horizontally by 1080 pixels vertically, which is the current terrestrial digital broadcasting. (Note that a terrestrial digital broadcasting service that transmits video with a maximum resolution of 1920 pixels horizontally by 1080 pixels vertically may transmit the same service using the above 7 segments of vertical polarization. In this case, this is also treated as hierarchical layer B.) Furthermore, a configuration may be made in which an advanced terrestrial digital broadcasting service capable of transmitting video with a maximum resolution of more than 1920 pixels horizontally by 1080 pixels vertically is transmitted using the above 5 segments of both horizontal and vertical polarization, totaling 10 segments, as hierarchical layer C. Details of this transmission will be described later. The transmission wave with this segment hierarchical allocation can be received, for example, by the second tuner/demodulator 130T of the broadcast receiving device 100.

For example, the hierarchical allocation in FIG. 4B(2) can be used as an example different from FIG. 4B(1) in the dual-polarized terrestrial digital broadcasting according to this embodiment, and the same segment hierarchical allocation can be used for both horizontal and vertical polarization. Specifically, the above one segment of horizontal polarization can be used to transmit the current mobile reception service of terrestrial digital broadcasting as the A hierarchical layer. (Note that the same service of the current mobile reception service of terrestrial digital broadcasting may be transmitted by the above one segment of vertical polarization. In this case, this is also treated as the A hierarchical layer.) Furthermore, the above five segments of both horizontal and vertical polarization, totaling 10 segments, may be configured to transmit an advanced terrestrial digital broadcasting service capable of transmitting video with a maximum resolution of more than 1920 pixels horizontally by 1080 pixels vertically as the B hierarchical layer. In addition, the above seven segments of horizontal polarization can be used to transmit the terrestrial digital broadcasting service that transmits video with a maximum resolution of 1920 pixels horizontally by 1080 pixels vertically, which is the current terrestrial digital broadcasting. (Note that a terrestrial digital broadcasting service that transmits video with a maximum resolution of 1920 pixels horizontal by 1080 pixels vertical may transmit the same service using the above seven segments of vertical polarization. In this case, this is also treated as hierarchical layer C.) Details of this transmission will be described later. The transmission wave with this segment hierarchical allocation can be received, for example, by the second tuner/demodulator 130T of the broadcast receiving device 100 of this embodiment.

For example, the hierarchical allocation of FIG. 4B (3) can be used in the hierarchical division multiplexing terrestrial digital broadcasting according to this embodiment and the current terrestrial digital broadcasting. Specifically, when used in hierarchical division multiplexing terrestrial digital broadcasting, the A hierarchical layer may be used to transmit the current terrestrial digital broadcasting mobile reception service in one segment in the figure. Furthermore, the B hierarchical layer may be configured to transmit an advanced terrestrial digital broadcasting service capable of transmitting video with a maximum resolution of more than 1920 pixels horizontally by 1080 pixels vertically in the 12 segments in the figure. The transmission wave of the segment hierarchical allocation can be received, for example, by the third tuner/demodulator 130L of the broadcast receiving device 100 of this embodiment. When used in the current terrestrial digital broadcasting, the A hierarchical layer may be used to transmit the current terrestrial digital broadcasting mobile reception service in one segment in the figure, and the B hierarchical layer may be used to transmit the current terrestrial digital broadcasting service that transmits video with a maximum resolution of 1920 pixels horizontally by 1080 pixels vertically in the 12 segments in the figure. The transmission wave of the segment hierarchical allocation can be received, for example, by the first tuner/demodulator unit 130C of the broadcast receiving device 100 of this embodiment.

Figure 4C shows an example of a broadcasting station system that realizes the generation process of OFDM transmission waves, which are digital broadcast waves of dual-polarized terrestrial digital broadcasting and hierarchical division multiplexing terrestrial digital broadcasting according to this embodiment. The information source coding unit 411 encodes video/audio/various data, etc. The multiplexing unit/limited reception processing unit 415 multiplexes the video/audio/various data, etc., encoded by the information source coding unit 411, and further performs processing corresponding to limited reception as appropriate to output as a packet stream. The information source coding unit 411 and the multiplexing unit/limited reception processing unit 415 can exist in parallel in multiple units, and generate multiple packet streams. The transmission path coding unit 416 re-multiplexes the multiple packet streams into one packet stream, performs transmission path coding processing, and outputs as an OFDM transmission wave. The configuration shown in Figure 4C is common to the ISDB-T system as a configuration that realizes the generation process of OFDM transmission waves, although the details of the information source coding and transmission path coding methods are different. Therefore, among the multiple information source coding units 411 and the multiplexing unit/conditional reception processing unit 415, some may be configured for ISDB-T type terrestrial digital broadcasting services, and some may be configured for advanced terrestrial digital broadcasting services, and the packet streams of the multiple different terrestrial digital broadcasting services may be multiplexed by the transmission path coding unit 416. When the multiplexing unit/conditional reception processing unit 415 is configured for ISDB-T type terrestrial digital broadcasting services, it is sufficient to generate MPEG-2TS, which is a stream of TSP (Transport Stream Packet) defined by MPEG-2 systems. Also, when the multiplexing unit/conditional reception processing unit 415 is configured for advanced terrestrial digital broadcasting services, it is sufficient to generate an MMT packet stream or a TLV stream including MMT packets, or a stream of TSP defined by other systems. Naturally, all of the multiple information source coding units 411 and the multiplexing unit/limited reception processing unit 415 can be configured for advanced terrestrial digital broadcasting services, and all packet streams multiplexed by the transmission path coding unit 416 can be packet streams for advanced terrestrial digital broadcasting services.

Figure 4D shows an example of the configuration of the transmission line coding unit 416.

First, FIG. 4D (1) will be described. FIG. 4D (1) shows the configuration of the transmission line coding unit 416 when only the OFDM transmission wave of the digital broadcasting of the current terrestrial digital broadcasting service is generated. The OFDM transmission wave transmitted in this configuration has, for example, the segment configuration of FIG. 4B (3). The packet stream input from the multiplexing unit/limited reception processing unit 415 and subjected to re-multiplexing processing is added with redundancy for error correction, and various interleaving processes such as byte interleaving, bit interleaving, time interleaving, and frequency interleaving are performed. After that, the pilot signal, TMCC signal, and AC signal are processed by IFFT (Inverse Fast Fourier Transform), and after a guard interval is added, the signal is converted into an OFDM transmission wave through orthogonal modulation. Note that the outer code processing, power dispersal processing, byte interleaving, inner code processing, and mapping processing are configured so that they can be processed separately for each layer such as the A layer and the B layer. (Note that while the current digital broadcasting service for terrestrial digital broadcasting has two layers for operational purposes, up to three layers can be transmitted, so an example of three layers is shown in FIG. 4D(1).) The mapping process is a carrier modulation process. Also, the packet stream input from the multiplexing unit/limited reception processing unit 415 may be multiplexed with information such as TMCC information, mode, and guard interval ratio. As mentioned above, the packet stream input to the transmission path coding unit 416 may be a TSP stream defined by MPEG-2 Systems. The OFDM transmission wave generated by the configuration of FIG. 4D(1) can be received, for example, by the first tuner/demodulation unit 130C of the broadcast receiving device 100 of this embodiment.

Next, FIG. 4D(2) will be described. FIG. 4D(2) shows the configuration of the transmission line coding unit 416 when generating OFDM transmission waves for dual-polarized terrestrial digital broadcasting according to this embodiment. The OFDM transmission waves transmitted in this configuration have, for example, the segment configuration of FIG. 4B(1) or (2). In FIG. 4D(2), the packet stream input from the multiplexing unit/limited reception processing unit 415 and subjected to re-multiplexing processing is subjected to various interleaving processes such as byte interleaving, bit interleaving, time interleaving, and frequency interleaving in addition to adding redundancy for error correction. After that, it is processed by IFFT together with the pilot signal, TMCC signal, and AC signal, and after guard interval addition processing, it is converted into an OFDM transmission wave through orthogonal modulation.

In the configuration example of FIG. 4D(2), the outer code processing, power dispersal processing, byte interleaving, inner code processing, mapping processing, and time interleaving are configured so that processing can be performed separately for each layer, such as layer A, layer B, and layer C. However, in the configuration example of FIG. 4D(2), not only horizontally polarized (H) OFDM transmission waves but also vertically polarized (V) OFDM transmission waves are generated, and the processing flow branches into two systems. When branching from the horizontally polarized (H) processing system to the vertically polarized (V) processing system, whether the same data as the horizontally polarized (H) processing system is branched to the vertically polarized (V) processing system, data different from the horizontally polarized (H) processing system is branched to the vertically polarized (V) processing system, or no data is branched to the vertically polarized (V) processing system can be made different for each layer in accordance with the segment configuration described in FIG. 4B(1) or (2).

The processing of the outer code, inner code, mapping, etc. shown in the configuration of FIG. 4D(2) can use processing compatible with the configuration of FIG. 4D(1), as well as more advanced processing not adopted in each processing of the configuration of FIG. 4D(1). Specifically, in the configuration of FIG. 4D(2), in the part where processing is performed for each layer, in the layer where the current terrestrial digital broadcasting mobile reception service and the current terrestrial digital broadcasting service that transmits video with a maximum resolution of 1920 pixels horizontal x 1080 pixels vertical are transmitted, processing of the outer code, inner code, mapping, etc. is performed in a manner compatible with the configuration of FIG. 4D(1). In contrast, in the configuration of FIG. 4D(2), in the part where processing is performed for each layer, in the layer where the advanced terrestrial digital broadcasting service that can transmit video with a maximum resolution of more than 1920 pixels horizontal x 1080 pixels vertical is transmitted, processing of the outer code, inner code, mapping, etc. can be configured to use more advanced processing not adopted in each processing of the configuration of FIG. 4D(1).

In addition, in the dual-polarized terrestrial digital broadcasting according to this embodiment, the allocation of the hierarchical layers and the terrestrial digital broadcasting services to be transmitted can be switched by the TMCC information described later, so it is desirable to configure the processing such as the outer code, inner code, and mapping applied to each layer to be switchable by the TMCC information.

For layers transmitting advanced terrestrial digital broadcasting services capable of transmitting video with a maximum resolution exceeding 1920 pixels horizontally by 1080 pixels vertically, byte interleaving, bit interleaving, and time interleaving may be performed in a manner compatible with current terrestrial digital broadcasting services, or different, more advanced processing may be performed. Alternatively, for layers transmitting advanced terrestrial digital broadcasting services, some interleaving may be omitted.

In addition, in the configuration of FIG. 4D(2), the input stream that is the source of the layer in which the current terrestrial digital broadcasting mobile reception service and the current terrestrial digital broadcasting service that transmits video with a maximum resolution of 1920 pixels horizontal by 1080 pixels vertical are transmitted may be a TSP stream defined by the MPEG-2 Systems adopted in the current terrestrial digital broadcasting among the packet streams input to the transmission path coding unit 416. The input stream that is the source of the layer in which the advanced terrestrial digital broadcasting service in the configuration of FIG. 4D(2) is transmitted may be a stream defined by a system other than the TSP stream defined by the MPEG-2 Systems, such as an MMT packet stream or a TLV including an MMT packet, among the packet streams input to the transmission path coding unit 416. However, a TSP stream defined by the MPEG-2 Systems may be adopted in the advanced terrestrial digital broadcasting service.

In the configuration of FIG. 4D(2) described above, until the OFDM transmission wave is generated from the input stream, the stream format and processing compatible with the current terrestrial digital broadcasting are maintained in the layer where the current terrestrial digital broadcasting mobile reception service and the current terrestrial digital broadcasting service that transmits video with a maximum resolution of 1920 pixels horizontal x 1080 pixels vertical are transmitted. As a result, even if a receiver for an existing terrestrial digital broadcasting service receives either the horizontally polarized OFDM transmission wave or the vertically polarized OFDM transmission wave generated in the configuration of FIG. 4D(2), the broadcast signal of the terrestrial digital broadcasting service can be correctly received and demodulated for the layer where the current terrestrial digital broadcasting mobile reception service and the current terrestrial digital broadcasting service that transmits video with a maximum resolution of 1920 pixels horizontal x 1080 pixels vertical are transmitted.

In addition, in the configuration of FIG. 4D(2), in a hierarchy that uses segments of both horizontally polarized OFDM transmission waves and vertically polarized OFDM transmission waves, it is possible to transmit an advanced terrestrial digital broadcasting service capable of transmitting video with a maximum resolution exceeding 1920 pixels horizontally by 1080 pixels vertically, and the broadcast signal of the advanced terrestrial digital broadcasting service can be received and demodulated by the broadcast receiving device 100 according to an embodiment of the present invention.

In other words, the configuration of FIG. 4D(2) can generate digital broadcast waves that can be suitably received and demodulated by broadcast receiving devices compatible with advanced terrestrial digital broadcast services, as well as by receiving devices for existing terrestrial digital broadcast services.

Next, FIG. 4D(3) will be described. FIG. 4D(3) shows the configuration of the transmission path coding unit 416 when generating OFDM transmission waves for hierarchical division multiplexing terrestrial digital broadcasting according to this embodiment. In FIG. 4D(3) as well, the packet stream input from the multiplexing unit/limited reception processing unit 415 and subjected to re-multiplexing processing is subjected to various interleaving processes such as byte interleaving, bit interleaving, time interleaving, and frequency interleaving in addition to adding redundancy for error correction. After that, IFFT processing is performed together with the pilot signal, TMCC signal, and AC signal, and after a guard interval is added, it is subjected to orthogonal modulation to become an OFDM transmission wave.

However, in the configuration of FIG. 4D(3), the modulated wave transmitted in the upper layer and the modulated wave transmitted in the lower layer are generated, and then multiplexed to generate an OFDM transmission wave, which is a digital broadcast wave. The processing system shown on the upper side of the configuration of FIG. 4D(3) is a processing system for generating the modulated wave transmitted in the upper layer, and the processing system shown on the lower side is a processing system for generating the modulated wave transmitted in the lower layer. The data transmitted through the processing system for generating the modulated wave transmitted in the upper layer of FIG. 4D(3) is the current terrestrial digital broadcasting mobile reception service and the current terrestrial digital broadcasting service that transmits video with a maximum resolution of 1920 pixels horizontal x 1080 pixels vertical, and the various processes in the processing system for generating the modulated wave transmitted in the upper layer of FIG. 4D(3) are the same as or compatible with the various processes in FIG. 4D(1). The modulated wave transmitted in the upper layer of FIG. 4D(3) has, for example, the segment configuration of FIG. 4B(3) like the transmission wave in FIG. 4D(1). Therefore, the modulated waves transmitted in the upper layer of FIG. 4D(3) are digital broadcast waves compatible with the current terrestrial digital broadcast mobile reception service and the current terrestrial digital broadcast service that transmits video with a maximum resolution of 1920 pixels horizontal by 1080 pixels vertical. In contrast, the data transmitted through the processing system for generating the modulated waves transmitted in the lower layer of FIG. 4D(3) is an advanced terrestrial digital broadcast service that can transmit video with a maximum resolution of more than 1920 pixels horizontal by 1080 pixels vertical, and can be configured to use more advanced processing than that used in the configuration of FIG. 4D(1) for processing such as outer coding, inner coding, and mapping.

The modulated wave transmitted in the lower layer of FIG. 4D(3) may be assigned to an advanced terrestrial digital broadcasting service capable of transmitting video with a maximum resolution of more than 1920 pixels horizontally by 1080 pixels vertically, with all 13 segments as layer A. Alternatively, the segment configuration of FIG. 4B(3) may be used to transmit a current terrestrial digital broadcasting mobile reception service in layer A of 1 segment, and an advanced terrestrial digital broadcasting service capable of transmitting video with a maximum resolution of more than 1920 pixels horizontally by 1080 pixels vertically in layer B of 12 segments. In the latter case, as in FIG. 4D(2), it is sufficient to configure the configuration so that processing can be switched for each layer, such as layer A and layer B, from outer code processing to time interleaving processing. As in the explanation of FIG. 4D(2), in the layer transmitting the current terrestrial digital broadcasting mobile reception service, processing compatible with the current terrestrial digital broadcasting must be maintained.

In the configuration of FIG. 4D (3), an OFDM transmission wave is generated, which is a terrestrial digital broadcast wave that is multiplexed with a modulated wave transmitted in an upper layer and a modulated wave transmitted in a lower layer. The technology for separating the modulated wave transmitted in the upper layer from the OFDM transmission wave is also installed in the receivers of existing terrestrial digital broadcast services, so that the broadcast signals of the current terrestrial digital broadcast mobile reception service and the current terrestrial digital broadcast service that transmits video with a maximum resolution of 1920 pixels horizontal x 1080 pixels vertical, which are included in the modulated wave transmitted in the upper layer, are correctly received and demodulated by the receivers of existing terrestrial digital broadcast services. In contrast, the broadcast signals of advanced terrestrial digital broadcast services that can transmit video with a maximum resolution of more than 1920 pixels horizontal x 1080 pixels vertical, which are included in the modulated wave transmitted in the lower layer, can be received and demodulated by the broadcast receiver 100 according to the embodiment of the present invention.

In other words, the configuration of FIG. 4D(3) can generate digital broadcast waves that can be suitably received and demodulated by broadcast receiving devices compatible with advanced terrestrial digital broadcast services, as well as by receiving devices for existing terrestrial digital broadcast services. Also, unlike the configuration of FIG. 4D(2), the configuration of FIG. 4D(3) does not require the use of multiple polarized waves, and can generate OFDM transmission waves that can be received more easily.

In the OFDM transmission wave generation process according to Fig. 4D(1), Fig. 4D(2), and Fig. 4D(3) of this embodiment, three modes with different numbers of carriers are prepared, taking into consideration the suitability to the distance between SFN stations and the resistance to Doppler shift in mobile reception. It is also possible to prepare other modes with different numbers of carriers. In a mode with a large number of carriers, the effective symbol length becomes longer, and if the guard interval ratio (guard interval length/effective symbol length) is the same, the guard interval length becomes longer, making it possible to provide resistance to multipath with long delay time differences. On the other hand, in a mode with a small number of carriers, the carrier interval becomes wider, making it possible to reduce the influence of inter-carrier interference due to Doppler shift that occurs in mobile reception, etc.

In the OFDM transmission wave generation process according to FIG. 4D(1), FIG. 4D(2), and FIG. 4D(3) of this embodiment, parameters such as the carrier modulation method, the coding rate of the inner code, and the time interleave length can be set for each layer consisting of one or more OFDM segments. FIG. 4E shows an example of transmission parameters for one segment of an OFDM segment identified by the mode of the system according to this embodiment. Note that the carrier modulation method in the figure refers to the modulation method of the "data" carrier. The SP signal, CP signal, TMCC signal, and AC signal adopt a modulation method different from the modulation method of the "data" carrier. Since these signals are signals for which resistance to noise is more important than the amount of information, a modulation method is adopted that maps to a small-value constellation (BPSK or DBPSK, i.e., two states) with fewer states than the modulation method of the "data" carrier (both QPSK or more, i.e., four states or more), thereby improving resistance to noise.

In addition, the numerical values of the carrier numbers are those when QPSK, 16QAM, 64QAM, etc. are set as the carrier modulation method on the left side of the diagonal line, and those when DQPSK is set as the carrier modulation method on the right side of the diagonal line. In the figure, the underlined parameters are parameters that are not compatible with the current terrestrial digital broadcasting mobile reception service. Specifically, the modulation methods of the "data" carrier, 256QAM, 1024QAM, and 4096QAM, are not adopted in the current terrestrial digital broadcasting service. Therefore, in the processing at the layer that requires compatibility with the current terrestrial digital broadcasting service in the OFDM broadcast wave generation processing related to Figures 4D (1), 4D (2), and 4D (3) of this embodiment, the modulation methods of the "data" carrier, 256QAM, 1024QAM, and 4096QAM are not used. For "data" carriers transmitted at a level corresponding to advanced terrestrial digital broadcasting services, in addition to modulation methods such as QPSK (4 states), 16QAM (16 states), and 64QAM (64 states) that are compatible with current terrestrial digital broadcasting services, it is also acceptable to apply even higher-level modulation methods such as 256QAM (256 states), 1024QAM (1024 states), and 4096QAM (4096 states). It is also acceptable to adopt modulation methods different from these modulation methods.

The modulation method for the pilot symbol (SP and CP) carriers can be BPSK (2 states), which is compatible with the current terrestrial digital broadcasting service. The modulation method for the AC carrier and TMCC carrier can be DBPSK (2 states), which is compatible with the current terrestrial digital broadcasting service.

In addition, the LDPC code is not used as an inner code processing method in the current terrestrial digital broadcasting service. Therefore, in the OFDM broadcast wave generation processing according to FIG. 4D(1), FIG. 4D(2), and FIG. 4D(3) of this embodiment, in the processing in the layer that requires compatibility with the current terrestrial digital broadcasting service, the LDPC code is not used. For data transmitted in the layer corresponding to the advanced terrestrial digital broadcasting service, the LDPC code may be applied as an inner code. In addition, the BCH code is not used as an outer code processing method in the current terrestrial digital broadcasting service. Therefore, in the OFDM broadcast wave generation processing according to FIG. 4D(1), FIG. 4D(2), and FIG. 4D(3) of this embodiment, in the processing in the layer that requires compatibility with the current terrestrial digital broadcasting service, the BCH code is not used. For data transmitted in the layer corresponding to the advanced terrestrial digital broadcasting service, the BCH code may be applied as an outer code.

Also, FIG. 4F shows an example of transmission signal parameters for one physical channel (6 MHz bandwidth) in the OFDM broadcast wave generation process according to FIG. 4D(1), FIG. 4D(2), and FIG. 4D(3) of this embodiment. In the OFDM broadcast wave generation process according to FIG. 4D(1), FIG. 4D(2), and FIG. 4D(3) of this embodiment, in order to maintain compatibility with the current terrestrial digital broadcast service, the parameters in FIG. 4F are basically compatible with the current terrestrial digital broadcast service. However, when all segments in the modulated wave transmitted in the lower layer of FIG. 4D(3) are assigned to an advanced terrestrial digital broadcast service, it is not necessary to maintain compatibility with the current terrestrial digital broadcast service in the modulated wave. Therefore, in this case, parameters other than those shown in FIG. 4F may be used for the modulated wave transmitted in the lower layer of FIG. 4D(3).

Next, the carriers of the OFDM transmission wave according to this embodiment will be described. The carriers of the OFDM transmission wave according to this embodiment include carriers that transmit data such as video and audio, carriers that transmit pilot signals (SP, CP, AC1, AC2) that serve as a demodulation reference, and carriers that transmit TMCC signals, which are information such as the carrier modulation format and convolutional coding rate. For these transmissions, a number of carriers equivalent to 1/9 of the number of carriers per segment are used. In addition, a concatenated code is used for error correction, and a shortened Reed-Solomon (204,188) code is used for the outer code, and a punctured convolutional code with a constraint length of 7 and a coding rate of 1/2 is used for the inner code. Both the outer code and the inner code may use coding different from the above. The information rate varies depending on parameters such as the carrier modulation format, the convolutional coding rate, and the guard interval ratio.

Furthermore, 204 symbols make up one frame, and each frame contains an integer number of TSPs. Transmission parameters are switched at the boundaries of these frames.

The pilot signals that serve as the basis for demodulation include SP (Scattered Pilot), CP (Continual Pilot), AC (Auxiliary Channel) 1, and AC2. Figure 4G shows an example of an arrangement image of pilot signals, etc., in a segment in the case of synchronous modulation (QPSK, 16QAM, 64QAM, 256QAM, 1024QAM, 4096QAM, etc.). SP is inserted into a segment of synchronous modulation and is transmitted once every 12 carriers in the carrier number (frequency axis) direction and once every 4 symbols in the OFDM symbol number (time axis) direction. Since the amplitude and phase of SP are known, it can be used as a basis for synchronous demodulation. Figure 4H shows an example of an arrangement image of pilot signals, etc., in a segment in the case of differential modulation (DQPSK, etc.). CP is a continuous signal inserted at the left end of a segment of differential modulation and is used for demodulation.

AC1 and AC2 carry information on the CP, and in addition to serving as pilot signals, are also used to transmit information for broadcasters. They may also be used to transmit other information.

The layout images shown in Figures 4G and 4H are examples for mode 3, with carrier numbers ranging from 0 to 431, but in modes 1 and 2, the carrier numbers are 0 to 107 and 0 to 215, respectively. The carriers transmitting AC1, AC2, and TMCC may be determined in advance for each segment. The carriers transmitting AC1, AC2, and TMCC are arranged randomly in the frequency direction to reduce the effects of periodic dips in the transmission path characteristics due to multipath.

[TMCC signal]
The TMCC signal transmits information (TMCC information) related to the demodulation operation of the receiver, such as the hierarchical structure and transmission parameters of the OFDM segment. The TMCC signal is transmitted by a carrier for TMCC transmission defined in each segment. FIG. 5A shows an example of bit allocation of the TMCC carrier. The TMCC carrier is composed of 204 bits (B0 to B203). B0 is a demodulation reference signal for the TMCC symbol, and has a predetermined amplitude and phase reference. B1 to B16 are synchronization signals, and are composed of 16-bit words. Two types of synchronization signals, w0 and w1, are defined, and w0 and w1 are sent alternately for each frame. B17 to B19 are used to identify the segment format, and identify whether each segment is a differential modulation section or a synchronous modulation section. B20 to B121 describe TMCC information. B122 to B203 are parity bits.

The TMCC information of the OFDM transmission wave according to this embodiment may be configured to include information for assisting the demodulation and decoding operations of the receiver, such as, for example, a system identification, a transmission parameter switching index, a start control signal (start flag for emergency warning broadcast), current information, next information, frequency conversion processing identification, physical channel number identification, main signal identification, 4K signal transmission layer identification, additional layer transmission identification, etc. The current information indicates the current layer configuration and transmission parameters, and the next information indicates the layer configuration and transmission parameters after switching. The transmission parameters are switched on a frame-by-frame basis. FIG. 5B shows an example of bit allocation of the TMCC information. FIG. 5C shows an example of the configuration of the transmission parameter information included in the current information/next information. The connected transmission phase correction amount is control information used in cases such as ISDB-TSB (ISDB for Terrestrial Sound Broadcasting) that uses a common transmission method, and a detailed description is omitted here.

Figure 5D shows an example of bit allocation for system identification. Two bits are allocated to the system identification signal. In the case of the current terrestrial digital television broadcasting system, "00" is set. In the case of a terrestrial digital audio broadcasting system that uses a common transmission method, "01" is set. In the case of an advanced terrestrial digital television broadcasting system such as dual-polarized terrestrial digital broadcasting or hierarchical division multiplexing terrestrial digital broadcasting according to this embodiment, "10" is set. In the advanced terrestrial digital television broadcasting system, 2K broadcast programs (broadcast programs with images of 1920 pixels horizontal x 1080 pixels vertical, which may include broadcast programs with images of lower resolution) and 4K broadcast programs (broadcast programs with images exceeding 1920 pixels horizontal x 1080 pixels vertical) can be transmitted simultaneously within the same service by broadcast wave transmission using the dual-polarized transmission method or the hierarchical division multiplexing method.

The transmission parameter switching index is used to notify the receiver of the switching timing by counting down when switching transmission parameters. This index is normally set to a value of "1111", and when switching transmission parameters, it is decremented by one for each frame starting from 15 frames before the switching. The switching timing is the next frame synchronization when "0000" is sent. After "0000", the index value returns to "1111". A countdown is performed when switching one or more of the parameters, such as the system identification of the TMCC information shown in FIG. 5B, the transmission parameters included in the current information/next information, the frequency conversion processing identification, the main signal identification, the 4K signal transmission layer identification, and the additional layer transmission identification, are switched. A countdown is not performed when switching only the start control signal of the TMCC information.

The start control signal (start flag for emergency alert broadcast) is set to "1" when start control is being performed on the receiver for emergency alert broadcast, and is set to "0" when start control is not being performed.

The partial reception flag for each current information/next information is set to "1" if the segment in the center of the transmission band is set for partial reception, and is set to "0" otherwise. When segment 0 is set for partial reception, its hierarchical layer is defined as hierarchical layer A. When next information does not exist, the partial reception flag is set to "1".

Figure 5E shows an example of bit allocation for the carrier modulation mapping method (data carrier modulation method) in each hierarchical transmission parameter for each current information/next information. When this parameter is "000", it indicates that the modulation method is DQPSK. When this parameter is "001", it indicates that the modulation method is QPSK. When this parameter is "010", it indicates that the modulation method is 16QAM. When this parameter is "011", it indicates that the modulation method is 64QAM. When this parameter is "100", it indicates that the modulation method is 256QAM. When this parameter is "101", it indicates that the modulation method is 1024QAM. When this parameter is "110", it indicates that the modulation method is 4096QAM. When there is no unused hierarchical layer or next information, this parameter is set to "111".

The coding rate, time interleaving length, and other settings may be set according to the organization information of each layer for each current information/next information. The number of segments indicates the number of segments in each layer with a 4-bit value. If there are no unused layers or next information, set "1111". Note that settings such as the mode and guard interval ratio are detected independently on the receiver side, so they do not need to be transmitted using TMCC information.

Figure 5F shows an example of bit allocation for the frequency conversion process identification. The frequency conversion process identification is set to "0" when the conversion unit 201T or 201L in Figure 2A performs the frequency conversion process (in the case of a dual-polarized transmission method) or the frequency conversion amplification process (in the case of a hierarchical division multiplexing transmission method) described below. If the frequency conversion process or the frequency conversion amplification process is not performed, it is set to "1". For example, this parameter may be configured to be set to "1" when sent from the broadcast station, and to be rewritten to "0" in the conversion unit 201T or 201L when the frequency conversion process or the frequency conversion amplification process is performed in the conversion unit 201T or 201L. In this way, if the bit of the frequency conversion process identification is "0" when received by the second tuner/demodulation unit 130T or the third tuner/demodulation unit 130L of the broadcast receiving device 100, it can be identified that the frequency conversion process or the like was performed after the OFDM transmission wave was sent from the broadcast station.

In the dual-polarized terrestrial digital broadcasting according to this embodiment, the frequency conversion process identification bit may be set or rewritten for each of the multiple polarized waves. For example, if both of the multiple polarized waves are not frequency converted by the conversion unit 201T in FIG. 2A, the frequency conversion process identification bit included in both OFDM transmission waves may be left as "1". If only one of the multiple polarized waves is frequency converted by the conversion unit 201T, the frequency conversion process identification bit included in the OFDM transmission wave of the frequency-converted polarized wave may be rewritten to "0" in the conversion unit 201T. If both of the multiple polarized waves are frequency converted by the conversion unit 201T, the frequency conversion process identification bit included in the OFDM transmission wave of both of the frequency-converted polarized waves may be rewritten to "0" in the conversion unit 201T. In this way, the broadcast receiving device 100 can identify whether or not frequency conversion has been performed for each of the multiple polarized waves.

The frequency conversion process identification bit is not defined in current terrestrial digital broadcasting, and is therefore ignored by terrestrial digital broadcasting receivers already in use by users. However, this bit may be introduced in a new terrestrial digital broadcasting service that transmits video with a maximum resolution of 1920 pixels horizontal by 1080 pixels vertical, which is an improvement over current terrestrial digital broadcasting. In this case, the first tuner/demodulator 130C of the broadcasting receiver 100 of the embodiment of the present invention may also be configured as a first tuner/demodulator compatible with the new terrestrial digital broadcasting service.

As a modified example, this parameter may be set to "0" in advance when sent from the broadcasting station, on the assumption that the OFDM transmission wave is subjected to frequency conversion processing or frequency conversion amplification processing in conversion unit 201T or conversion unit 201L in FIG. 2A. If the broadcast wave being received is not an advanced terrestrial digital broadcasting service, this parameter may be configured to be set to "1."

Figure 5G shows an example of bit allocation for physical channel number identification. The physical channel number identification is composed of a 6-bit code and identifies the physical channel number (13 to 52ch) of the broadcast wave to be received. If the broadcast wave to be received is not an advanced terrestrial digital broadcasting service, this parameter is set to "111111". The physical channel number identification bits are not defined in the current terrestrial digital broadcasting, and the current terrestrial digital broadcasting receiving device cannot obtain the physical channel number of the broadcast wave specified by the broadcasting station from the TMCC signal, AC signal, etc. In the broadcast receiving device 100 according to the embodiment of the present invention, the physical channel number set by the broadcasting station for the OFDM transmission wave can be grasped by using the physical channel number identification bits of the received OFDM transmission wave without demodulating carriers other than the TMCC signal and AC signal. Note that the physical channels 13ch to 52ch are pre-allocated to the frequency band of 470 to 710MHz with a bandwidth of 6MHz per channel. Therefore, the fact that the broadcast receiving device 100 can determine the physical channel number of an OFDM transmission wave based on the physical channel number identification bit means that it can determine the frequency band in which the OFDM transmission wave was transmitted over the air as a terrestrial digital broadcast wave.

In the dual-polarized terrestrial digital broadcasting according to this embodiment, in the generation process of the OFDM transmission wave on the broadcasting station side, the physical channel number identification bit is placed on each of the pairs of multiple polarized waves in the bandwidth that originally constitutes one physical channel, and the same physical number is assigned to each pair. Here, depending on the installation environment of the broadcasting receiving device 100, the conversion unit 201T in FIG. 2A may convert only the frequency of one of the multiple polarized waves. As a result, if the frequencies of the multiple polarized waves pairs differ when received by the broadcasting receiving device 100, the broadcasting receiving device will not be able to demodulate advanced terrestrial digital broadcasting using both polarized waves of the dual-polarized terrestrial digital broadcasting unless it can somehow grasp that the multiple polarized waves with different frequencies were originally a pair. Even in such a case, if the above-mentioned physical channel number identification bit is used, when transmission waves with the same value of the physical channel number identification bit exist at multiple different frequencies in the broadcasting receiving device 100, it can be identified as a transmission wave that was originally transmitted as a polarization pair that constituted one physical channel on the broadcasting station side. This makes it possible to achieve advanced demodulation of dual-polarized terrestrial digital broadcasting using multiple transmission waves that show the same value.

Figure 5H shows an example of bit allocation for main signal identification. In this example, the bit for the main signal identification is placed in bit B117.

When the OFDM transmission wave is a dual-polarized terrestrial digital broadcasting transmission wave, this parameter is set to "1" in the TMCC information of the transmission wave transmitted with the primary polarization. It is set to "0" in the TMCC information of the transmission wave transmitted with the secondary polarization. Note that a transmission wave transmitted with the primary polarization refers to a polarized signal, either a vertically polarized signal or a horizontally polarized signal, that has the same polarization direction as the polarization direction used for the transmission of the current terrestrial digital broadcasting service. That is, in areas where the current terrestrial digital broadcasting service uses horizontally polarized transmission, the horizontal polarization is the primary polarization and the vertical polarization is the secondary polarization for the dual-polarized terrestrial digital broadcasting service. Also, in areas where the current terrestrial digital broadcasting service uses vertically polarized transmission, the vertical polarization is the primary polarization and the horizontal polarization is the secondary polarization for the dual-polarized terrestrial digital broadcasting service.

In the broadcast receiving device 100 that receives the transmission wave of the dual-polarized terrestrial digital broadcasting according to the embodiment of the present invention, the main signal identification bit can be used to identify whether the received transmission wave was transmitted in the main polarization or in the secondary polarization at the time of transmission. For example, by using the process of identifying the main polarization and the secondary polarization, it becomes possible to perform an initial scan of the transmission wave transmitted in the main polarization first during the initial scan described below, and then perform an initial scan of the transmission wave transmitted in the secondary polarization after the initial scan of the transmission wave transmitted in the main polarization is completed.

A detailed configuration example of the hierarchical layers and segments of the dual-polarized terrestrial digital broadcasting according to this embodiment and the digital broadcasting service to be transmitted will be described later, but when a current terrestrial digital broadcasting service is transmitted using a hierarchical layer consisting of segments included only in the primary polarization and an advanced terrestrial digital broadcasting service is transmitted using a hierarchical layer including segments included in both the primary polarization and the secondary polarization, an initial scan of the transmission wave transmitted in the primary polarization may be performed first to complete the initial scan of the current terrestrial digital broadcasting service, and then an initial scan of the transmission wave transmitted in the secondary polarization may be performed to perform an initial scan of the advanced terrestrial digital broadcasting service. In this way, an initial scan of the advanced terrestrial digital broadcasting service can be performed after the completion of the initial scan of the current terrestrial digital broadcasting service, and the settings obtained by the initial scan of the current terrestrial digital broadcasting service can be reflected in the settings obtained by the initial scan of the advanced terrestrial digital broadcasting service, which is preferable.
The meanings of the main signal identification bits "1" and "0" may be reversed from those described above.

In addition, instead of the main signal identification bit, the polarization direction identification bit may be used as one parameter of the TMCC information. Specifically, the polarization direction identification bit may be set to "1" on the broadcasting station side for transmission waves transmitted with horizontal polarization, and the polarization direction identification bit may be set to "0" on the broadcasting station side for transmission waves transmitted with vertical polarization. In the broadcasting receiving device 100 that receives the transmission waves of the dual-polarized terrestrial digital broadcasting of the embodiment of the present invention, the polarization direction identification bit may be used to identify in which polarization direction the transmission waves being received were transmitted at the time of transmission. For example, by using the polarization direction identification process, it is possible to perform an initial scan of the transmission waves transmitted with horizontal polarization first during the initial scan described below, and then perform an initial scan of the transmission waves transmitted with vertical polarization after the initial scan of the transmission waves transmitted with horizontal polarization is completed. The effect of this process can be explained by replacing "primary polarization" with "horizontal polarization" and "secondary polarization" with "vertical polarization" in the section relating to the initial scan in the explanation of the main signal identification bits above, so a repeated explanation will be omitted.

Note that the definition of the polarization direction identification bits "1" and "0" may be reversed from that explained above.

In addition, instead of the above-mentioned main signal identification bit, the first signal/second signal identification bit may be used as one parameter of the TMCC information. Specifically, one of the horizontally polarized and vertically polarized waves is defined as the first polarization, the broadcast signal of the transmission wave transmitted in the first polarization is defined as the first signal, and the broadcast station side sets the first signal/second signal identification bit to "1". Also, the other polarization is defined as the second polarization, the broadcast signal of the transmission wave transmitted in the second polarization is defined as the second signal, and the broadcast station side sets the first signal/second signal identification bit to "0". In the broadcast receiving device 100 that receives the transmission wave of the dual-polarized terrestrial digital broadcasting of the embodiment of the present invention, the first signal/second signal identification bit can be used to identify in which polarization direction the transmission wave being received was transmitted at the time of transmission. Note that the first signal second signal identification bit is simply a change from the concepts of "primary polarization" and "secondary polarization" in the definition of the main signal identification bit described above to "first polarization" and "secondary polarization." The processing and effects in broadcast receiving device 100 can be understood by simply replacing "primary polarization" with "first polarization" and "secondary polarization" with "secondary polarization" in the parts related to the processing of broadcast receiving device 100 in the explanation of the main signal identification bit described above, so a repeated explanation will be omitted.

Note that the definition of the meaning of "1" and "0" in the first and second signal identification bits may be reversed from that explained above.

Next, in the transmission waves of the hierarchical division multiplexing terrestrial digital broadcasting according to this embodiment, the upper and lower layer identification bits may be used as one parameter of the TMCC information instead of the main signal identification bits described above. Specifically, in the TMCC information of the modulated waves transmitted in the upper layer, the upper and lower layer identification bits described above may be set to "1," and in the TMCC information of the transmission waves transmitted in the lower layer, the upper and lower layer identification bits described above may be set to "0." Also, if the broadcast waves being received are not an advanced terrestrial digital broadcasting service, this parameter may be set to "1."

In the hierarchical division multiplexing terrestrial digital broadcasting according to the present embodiment, in the generation process of the OFDM transmission wave on the broadcasting station side, the lower layer of the multiple modulated waves originally transmitted in the upper and lower layers of one physical channel may be frequency converted and signal amplified in the conversion unit 201L in FIG. 2A depending on the installation environment of the broadcast receiving device 100. When the broadcast receiving device 100 receives a transmission wave of hierarchical division multiplexing terrestrial digital broadcasting, it is possible to identify whether the modulated wave was originally transmitted in the upper layer or the lower layer based on the above-mentioned upper and lower layer identification bits. For example, this identification process allows the initial scan of the advanced terrestrial digital broadcasting service transmitted in the lower layer to be performed after the initial scan of the current terrestrial digital broadcasting service transmitted in the upper layer is completed, and the settings by the initial scan of the current terrestrial digital broadcasting service can be reflected in the settings by the initial scan of the advanced terrestrial digital broadcasting service. In addition, the third tuner/demodulation unit 130L of the broadcast receiving device 100 can be used to switch between the processing of the demodulation unit 133S and the demodulation unit 133L based on the identification result.

In the following description of the dual-polarized transmission system in each embodiment, unless otherwise specified, an example will be described in which the horizontal polarization is the primary polarization and the vertical polarization is the secondary polarization. However, the primary and secondary relationship between the horizontal polarization and the vertical polarization may be reversed.
FIG. 5I shows an example of bit allocation for 4K signal transmission hierarchy identification.

When the broadcast wave to be transmitted is the transmission wave of the dual-polarized terrestrial digital broadcasting service according to the present embodiment, the bit of the 4K signal transmission layer identification may indicate whether or not the 4K broadcast program is transmitted using both the horizontally polarized signal and the vertically polarized signal for each of the B and C layers. One bit is assigned to each of the B layer setting and the C layer setting. For example, when the bit of the 4K signal transmission layer identification for each of the B and C layers is "0", it may indicate that the 4K broadcast program is transmitted using both the horizontally polarized signal and the vertically polarized signal for the layer. When the bit of the 4K signal transmission layer identification for each of the B and C layers is "1", it may indicate that the 4K broadcast program is not transmitted using both the horizontally polarized signal and the vertically polarized signal for the layer. In this way, the broadcast receiving device 100 can use the bit of the 4K signal transmission layer identification to identify whether or not the 4K broadcast program is transmitted using both the horizontally polarized signal and the vertically polarized signal for each of the B and C layers.

Furthermore, when the broadcast waves to be transmitted are those of the hierarchical division multiplexing terrestrial digital broadcasting service of this embodiment, the bit of the 4K signal transmission hierarchical identification may indicate whether or not a 4K broadcast program is to be transmitted in the lower hierarchy. When this parameter B119 is "0", the 4K broadcast program is transmitted in the lower hierarchy. When this parameter B119 is "1", the 4K broadcast program is not transmitted in the lower hierarchy. In this way, the broadcast receiving device 100 can use the bit of the 4K signal transmission hierarchical identification to identify whether or not a 4K broadcast program is to be transmitted in the lower hierarchy.

When this parameter is "0", in addition to the basic modulation method shown in FIG. 5C, the NUC (Non-Uniform Constellation) modulation method can be used as the carrier modulation mapping method. In this case, the current/next information of the transmission parameter additional information for the B/C layers can be transmitted using AC1, etc.

Also, if the broadcast waves being transmitted are not an advanced terrestrial digital broadcasting service, these parameters may be set to "1."

Note that the definitions of the bits "0" and "1" of the 4K signal transmission layer identification described above may be reversed.

Figure 5J shows an example of bit allocation for additional layer transmission identification. The additional layer transmission identification bit may indicate whether the broadcast wave being transmitted is the dual-polarized terrestrial digital broadcasting service of this embodiment, and whether layers B and C of the transmission wave transmitted in the secondary polarization are to be used as virtual layers D and E, respectively.

For example, in the example shown in the figure, the bit placed in B120 is the D hierarchical layer transmission identification bit, and when this parameter is "0", the B hierarchical layer transmitted with the secondary polarization is used as the virtual D hierarchical layer. To be precise, this means that among the segments transmitted with the secondary polarization, a group of segments having the same segment number as a segment belonging to the B hierarchical layer transmitted with the primary polarization are treated as the D hierarchical layer, which is a different layer from the B hierarchical layer transmitted with the primary polarization. When this parameter is "1", the B hierarchical layer transmitted with the secondary polarization is not used as the virtual D hierarchical layer, but is used as the B hierarchical layer.

For example, the bit placed in B121 is the E hierarchical layer transmission identification bit, and when this parameter is "0", the C hierarchical layer transmitted with the secondary polarization is used as the virtual E hierarchical layer. To be precise, this means that, among the segments transmitted with the secondary polarization, a group of segments having the same segment number as a segment belonging to the C hierarchical layer transmitted with the primary polarization is treated as the E hierarchical layer, which is a different layer from the C hierarchical layer transmitted with the primary polarization. When this parameter is "1", the C hierarchical layer transmitted with the secondary polarization is not used as the virtual E hierarchical layer, but is used as the C hierarchical layer.

In this way, the broadcast receiving device 100 can use the additional layer transmission identification bits (layer D transmission identification bit and/or layer E transmission identification bit) to identify the presence or absence of layers D and E transmitted in the secondary polarization. That is, in the terrestrial digital broadcasting of this embodiment, by using the additional layer transmission identification parameters shown in Figure 5J, it is possible to operate new layers (layers D and E in the example of Figure 5J) beyond the number of layers currently limited to three (layers A, B, and C) in terrestrial digital broadcasting.

When this parameter is "0", it is possible to make the parameters shown in FIG. 5C, such as the carrier modulation mapping method, the coding rate, and the length of time interleaving, different between the virtual D layer/virtual E layer and the B layer/C layer. In this case, if the current/next information for parameters such as the carrier modulation mapping method, the convolution coding rate, and the length of time interleaving for the virtual D layer/virtual E layer are transmitted using AC information (e.g. AC1), the broadcast receiving device 100 can grasp the parameters such as the carrier modulation mapping method, the convolution coding rate, and the length of time interleaving for the virtual D layer/virtual E layer.

As a modified example, when the bit of the additional layer transmission identification (layer D transmission identification bit and/or layer E transmission identification bit) is "0", the transmission parameters of layers B and/or C of the current information/next information of the TMCC information transmitted by the secondary polarization may be switched to the meaning of the transmission parameters of the virtual layer D and/or virtual layer E. In this case, when the virtual layer D and/or virtual layer E are used, layers A, B, and C are used in the primary polarization, and the transmission parameters of these layers may be transmitted in the current information/next information of the TMCC information transmitted by the primary polarization. In addition, layers A, D, and E are used in the secondary polarization, and the transmission parameters of these layers may be transmitted in the current information/next information of the TMCC information transmitted by the secondary polarization. Even in this case, the broadcast receiving device 100 can grasp parameters such as the carrier modulation mapping method, convolutional coding rate, and time interleaving length related to the virtual layer D/virtual layer E.

In addition, if the broadcast wave being transmitted is not an advanced terrestrial digital broadcasting service, or if it is an advanced terrestrial digital broadcasting service but uses a hierarchical division multiplexing transmission method, this parameter may be configured to be set to "1."

Note that the additional layer transmission identification parameters may be stored in both the TMCC information of the primary polarization and the TMCC information of the secondary polarization, but as long as they are stored in at least the TMCC information of the secondary polarization, all of the above processes can be realized.

In addition, the definitions of "0" and "1" in the additional layer transmission identification bits described above may be reversed from that described above.

Note that, if the above-mentioned 4K signal transmission layer identification parameter indicates that a 4K broadcast program is to be transmitted on layer B, even if the above-mentioned D layer transmission identification bit indicates that layer B is to be used as the virtual D layer, the broadcast receiving device 100 may be configured to ignore the D layer transmission identification bit. Similarly, if the above-mentioned 4K signal transmission layer identification parameter indicates that a 4K broadcast program is to be transmitted on layer C, even if the E layer transmission identification bit indicates that layer C is to be used as the virtual E layer, the broadcast receiving device 100 may be configured to ignore the E layer transmission identification bit. By clarifying the priority of the bits used in the judgment process in this way, it is possible to prevent conflicts in the judgment process in the broadcast receiving device 100.

In addition, in the transmitted broadcast waves, the above-mentioned frequency conversion process identification bits, physical channel number identification bits, main signal identification bits, 4K signal transmission identification bits, additional layer transmission identification bits, etc., should be set as a general rule to "1" if the above-mentioned system identification parameter is not "10". Even if the system identification parameter is not "10" but, due to some problem, the frequency conversion process identification bits, physical channel number identification bits, main signal identification bits, 4K signal transmission identification bits, and additional layer transmission identification bits are exceptionally not "1", the broadcast receiving device 100 may be configured to ignore the bits that are not "1" and determine that all of these bits are "1".

Figure 5K shows an example of the "coding rate" bits shown in Figure 5C, i.e., the bit allocation for identifying the coding rate for error correction.

In the current 2K terrestrial digital broadcasting system, an identification bit is transmitted that transmits a coding rate dedicated to the "convolutional code". However, in the digital broadcasting according to this embodiment, the 4K advanced terrestrial digital broadcasting service can be broadcast together with the 2K terrestrial digital broadcasting service. And, as already explained, the 4K advanced terrestrial digital broadcasting service can use an LDPC code as the inner code.

Therefore, unlike the current 2K terrestrial digital broadcasting system, the error correction coding rate identification bits in this embodiment shown in Figure 5K are configured to be compatible with LDPC codes, rather than being coding rate identification bits dedicated to convolutional codes.

Here, whether the inner code of the target terrestrial digital broadcasting service is a convolutional code or an LDPC code, the number of bits can be saved by using the bits that are placed in a common range as the identification bits for the coding rate transmission. Furthermore, even if the same identification bits are used, by setting the coding rate independently for when the inner code of the target terrestrial digital broadcasting service is a convolutional code and when it is an LDPC code, the digital broadcasting system can adopt a selection of coding rates that are suitable for each coding method.

Specifically, in the example of FIG. 5K, when the identification bits are '000', it indicates that if the inner code is a convolutional code, the coding rate is 1/2, and if the inner code is an LDPC code, the coding rate is 2/3. When the identification bits are '001', it indicates that if the inner code is a convolutional code, the coding rate is 2/3, and if the inner code is an LDPC code, the coding rate is 3/4. When the identification bits are '010', it indicates that if the inner code is a convolutional code, the coding rate is 3/4, and if the inner code is an LDPC code, the coding rate is 5/6. When the identification bits are '011', it indicates that if the inner code is a convolutional code, the coding rate is 5/6, and if the inner code is an LDPC code, the coding rate is 2/16. When the identification bits are '100', it indicates that if the inner code is a convolutional code, the coding rate is 7/8, and if the inner code is an LDPC code, the coding rate is 6/16. When the identification bits are '101', it indicates that if the inner code is a convolutional code, the coding rate is undefined, and if the inner code is an LDPC code, the coding rate is 10/16. If the identification bits are "110", it indicates that if the inner code is a convolutional code, it is undefined, and if the inner code is an LDPC code, the coding rate is 14/16. If there are no unused layers or next information, this parameter is set to "111".

The identification of whether the inner code of the target terrestrial digital broadcasting service is a convolutional code or an LDPC code may be performed using the result of identifying whether the terrestrial digital broadcasting service is a current terrestrial digital broadcasting service or an advanced terrestrial digital broadcasting service. The identification may be performed using the identification bit described in FIG. 5D or FIG. 5I. Here, if the target terrestrial digital broadcasting service is a current terrestrial digital broadcasting service, the inner code may be identified as a convolutional code. Also, if the target terrestrial digital broadcasting service is an advanced terrestrial digital broadcasting service, the inner code may be identified as an LDPC code.

As another example of identifying whether the inner code of the target terrestrial digital broadcasting service is a convolutional code or an LDPC code, the identification may be based on an error correction method identification bit, which will be described later in FIG. 6I.

The error correction coding rate identification bits shown in Figure 5K described above are advantageous because they can accommodate multiple inner code methods while preventing an increase in the number of identification bits.

In addition, in an advanced terrestrial digital broadcasting service using a dual-polarized transmission method, the TMCC information of the transmission wave transmitted with horizontal polarization and the TMCC information of the transmission wave transmitted with vertical polarization may be the same or different. Similarly, in an advanced terrestrial digital broadcasting service using a hierarchical division multiplexing transmission method, the TMCC information of the transmission wave transmitted in the upper layer and the TMCC information of the transmission wave transmitted in the lower layer may be the same or different. In addition, the aforementioned frequency conversion processing identification parameters, main signal identification parameters, additional layer transmission identification, etc. may be written only in the TMCC information of the transmission wave transmitted with the secondary polarization or the transmission wave transmitted in the lower layer.

In the above description, an example has been described in which the frequency conversion process identification parameter, the main signal identification parameter, the polarization direction identification parameter, the first signal/second signal identification parameter, the upper and lower layer identification parameter, the 4K signal transmission layer identification parameter, and the additional layer transmission identification parameter are included in a TMCC signal (TMCC carrier) and transmitted. However, these parameters may also be included in an AC signal (AC carrier) and transmitted. In other words, these parameters may be transmitted in a signal of a carrier (TMCC carrier, AC carrier, etc.) modulated by a modulation method that performs mapping with a smaller number of states than the modulation method of the data carrier.

[AC signal]
The AC signal is an additional information signal related to broadcasting, and includes additional information related to the transmission control of modulated waves or earthquake warning information. The earthquake warning information is transmitted using the AC carrier of segment 0. On the other hand, the additional information related to the transmission control of modulated waves can be transmitted using any AC carrier. FIG. 6A shows an example of bit allocation of an AC signal. The AC signal is composed of 204 bits (B0 to B203). B0 is a demodulation reference signal for the AC symbol, and has a predetermined amplitude and phase reference. B1 to B3 are signals for identifying the configuration of the AC signal. B4 to B203 are used to transmit additional information related to the transmission control of modulated waves or earthquake warning information.

Figure 6B shows an example of bit allocation for AC signal configuration identification. When transmitting earthquake motion warning information using B4 to B203 of the AC signal, this parameter is set to "001" or "110". The configuration identification parameter ("001" or "110") when transmitting earthquake motion warning information is the same code as the first three bits (B1 to B3) of the TMCC signal synchronization signal, and is sent alternately for each frame at the same timing as the TMCC signal. Also, if this parameter has a value other than the above, it indicates that additional information related to the transmission control of the modulated wave is being transmitted using B4 to B203 of the AC signal. Additional information related to the transmission control of the modulated wave may also be transmitted using B4 to B203 of the AC signal. In this case, the configuration identification parameter of the AC signal is sent alternately between "000" and "111", or "010" and "101", or "011" and "100" for each frame.

AC signals B4 to B203 are used to transmit additional information regarding the transmission control of modulated waves or to transmit earthquake motion warning information.

The transmission of additional information related to the transmission control of the modulated wave may be performed using various bit configurations. For example, the frequency conversion process identification, physical channel number identification, main signal identification, 4K signal transmission layer identification, additional layer transmission identification, etc. described in the description of the TMCC signal may be transmitted by allocating bits to additional information related to the transmission control of the modulated wave of the AC signal instead of or in addition to the TMCC signal. In this way, the broadcast receiving device 100 can use these parameters to perform various identification processes already described in the description of the TMCC signal. In addition, the current/next information of the transmission parameter additional information related to the transmission layer of the 4K broadcast program when any parameter of the 4K signal transmission layer identification is "0", or the transmission parameter related to the virtual D layer/virtual E layer when any parameter of the additional layer transmission identification is "0" may be assigned. In this way, the broadcast receiving device 100 can obtain the transmission parameters of each layer using these parameters, and the demodulation process of each layer can be controlled.

The earthquake motion warning information may be transmitted according to the bit allocation shown in FIG. 6C. The earthquake motion warning information is composed of a synchronization signal, a start/end flag, an update flag, a signal identification, earthquake motion warning details, a CRC, a parity bit, etc. The synchronization signal is composed of a 13-bit code, and is the same code as the 13 bits (B4 to B16) of the synchronization signal of the TMCC signal excluding the first 3 bits. When the configuration identification of the AC signal indicates that earthquake motion warning information is to be transmitted, the 16-bit code combining the configuration identification and the synchronization signal becomes a 16-bit synchronization word that is the same as the synchronization signal of the TMCC. The start/end flag is composed of a 2-bit code as a flag for the start timing/end timing of the earthquake motion warning information. The start/end flag is changed from "11" to "00" at the start of the transmission of the earthquake motion warning information, and is changed from "00" to "11" at the end of the transmission of the earthquake motion warning information. The update flag is composed of a 2-bit code, and is incremented by 1 with the initial value being 00 each time a change occurs in the content of the series of earthquake warning detail information transmitted when the start/end flag is 00. After 11, it returns to 00. If the start/end flag is 11, the update flag will also be 11.

Figure 6D shows an example of bit allocation for signal identification. Signal identification is composed of a 3-bit code and is used to identify the type of earthquake motion warning detail information. When this parameter is "000", it means "earthquake motion warning detail information (applicable area)". When this parameter is "001", it means "earthquake motion warning detail information (no applicable area)". When this parameter is "010", it means "test signal for earthquake motion warning detail information (applicable area)". When this parameter is "011", it means "test signal for earthquake motion warning detail information (no applicable area)". When this parameter is "111", it means "no earthquake motion warning detail information". When the start/end flag is "00", the signal identification is "000", "001", "010", or "011". When the start/end flag is "11", the signal identification is "111".

The earthquake motion warning detail information is composed of an 88-bit code. When the signal identification is "000", "001", "010", or "011", the earthquake motion warning detail information transmits information related to the current time when the earthquake motion warning information is sent, information indicating the area that is the subject of the earthquake motion warning, and information such as the latitude/longitude/seismic intensity of the epicenter of the earthquake that is the subject of the earthquake motion warning. An example of bit allocation of the earthquake motion warning detail information when the signal identification is "000", "001", "010", or "011" is shown in Figure 6E. Also, when the signal identification is "111", it is possible to transmit a code for identifying the broadcasting company using the bits of the earthquake motion warning detail information. An example of bit allocation of the earthquake motion warning detail information when the signal identification is "111" is shown in Figure 6F.

The CRC is a code generated using a predetermined generating polynomial for B21 to B111 of the earthquake warning information. The parity bit is a code generated by a shortened code (187, 105) of the difference set cyclic code (273, 191) for B17 to B121 of the earthquake warning information.

The broadcast receiving device 100 can perform various controls to deal with emergency situations using the parameters related to earthquake motion warnings described in Figures 6C, 6D, 6E, and 6F. For example, it is possible to perform control to present information related to earthquake motion warnings, control to switch low-priority display content to a display related to earthquake motion warnings, and control to end the display of an application and switch to a display related to earthquake motion warnings or broadcast program video.

Figure 6G shows an example of bit allocation of additional information related to the transmission control of modulated waves. The additional information related to the transmission control of modulated waves is composed of a synchronization signal, current information, next information, parity bits, etc. The synchronization signal is composed of a 13-bit code, and is the same code as the 13 bits (B4 to B16) excluding the first 3 bits of the synchronization signal of the TMCC signal. When the configuration identification of the AC signal indicates that additional information related to the transmission control of modulated waves is to be transmitted, the 16-bit code combining the configuration identification and the synchronization signal becomes a 16-bit synchronization word conforming to the TMCC synchronization signal. The current information indicates the current information of the transmission parameter additional information when transmitting a 4K broadcast program on the B or C layer, and the transmission parameters related to the virtual D or E layer. The next information indicates the information after switching of the transmission parameter additional information when transmitting a 4K broadcast program on the B or C layer, and the transmission parameters related to the virtual D or E layer.

In the example of FIG. 6G, B18 to B30 of the current information are the current information of the B layer transmission parameter additional information, and indicate the current information of the transmission parameter additional information when transmitting a 4K broadcast program on the B layer. Also, B31 to B43 of the current information are the current information of the C layer transmission parameter additional information, and indicate the current information of the transmission parameter additional information when transmitting a 4K broadcast program on the C layer. Also, B70 to B82 of the next information are the information after the transmission parameters of the B layer transmission parameter additional information are switched, and indicate the information after the transmission parameters of the transmission parameter additional information when transmitting a 4K broadcast program on the B layer. Also, B83 to B95 of the next information are the information after the transmission parameters of the C layer transmission parameter additional information are switched, and indicate the information after the transmission parameters of the transmission parameter additional information when transmitting a 4K broadcast program on the C layer. Here, the transmission parameter additional information is a transmission parameter related to modulation that is added to the transmission parameters of the TMCC information shown in FIG. 5C to expand the specifications. The specific contents of the transmission parameter additional information will be described later.

In the example of Figure 6G, current information B44 to B56 is current information on transmission parameters for the virtual D hierarchical layer when the virtual D hierarchical layer is being operated. Current information B57 to B69 is current information on transmission parameters for the virtual E hierarchical layer when the virtual E hierarchical layer is being operated. Furthermore, next information B96 to B108 is information after switching of transmission parameters for the virtual D hierarchical layer when the virtual D hierarchical layer is being operated. Current information B109 to B121 is information after switching of transmission parameters for the virtual E hierarchical layer when the virtual E hierarchical layer is being operated. The parameters stored in the transmission parameters for the virtual D hierarchical layer and the transmission parameters for the virtual E hierarchical layer may be the same as those shown in Figure 5C.

The virtual D layer and virtual E layer are layers that do not exist in current terrestrial digital broadcasting. It is not easy to increase the number of bits in the TMCC information in Figure 5B because it is necessary to maintain compatibility with current terrestrial digital broadcasting. Therefore, in an embodiment of the present invention, the transmission parameters for the virtual D layer and virtual E layer are stored in the AC information as shown in Figure 6G, rather than in the TMCC information.

This makes it possible to transmit modulation-related information for the new virtual D and E layers to the receiving device while maintaining compatibility of the TMCC information with the current terrestrial digital broadcasting. This makes it possible to set the transmission parameters of the virtual D and E layers of the transmission waves transmitted in the secondary polarization to be different from the transmission parameters of the B and C layers of the transmission waves transmitted in the primary polarization when using the B and C layers of the transmission waves transmitted in the secondary polarization as the virtual D and E layers of the broadcast waves of the dual-polarized terrestrial digital broadcasting service according to this embodiment.

When the virtual D hierarchical layer or virtual E hierarchical layer is not used, the information on the transmission parameters for the unused hierarchical layers can be ignored by the broadcast receiving device 100 without any problem. For example, when the additional hierarchical layer transmission identification parameter in the TMCC information in FIG. 5J indicates "1" for the virtual D hierarchical layer or virtual E hierarchical layer (indicating that the virtual D hierarchical layer/virtual E hierarchical layer is not used), the broadcast receiving device 100 can be configured to ignore any value contained in the transmission parameters shown in FIG. 6G for the unused virtual D hierarchical layer or virtual E hierarchical layer.

Next, we will explain the details of the transmission parameter additional information described in Figure 6G.

Figure 6H shows a specific example of the transmission parameter additional information. The transmission parameter additional information can include parameters for an error correction method, parameters for a constellation format, etc.

The error correction method indicates the setting of what coding method is used as the error correction method for the inner code and outer code when transmitting a 4K broadcast program (advanced terrestrial digital broadcasting service) on the B or C layer. Figure 6I shows an example of bit allocation for the error correction method. If this parameter is "000", a convolutional code is used as the inner code and a shortened RS code is used as the outer code when transmitting a 4K broadcast program on the B or C layer. If this parameter is "001", an LDPC code is used as the inner code and a BCH code is used as the outer code when transmitting a 4K broadcast program on the B and C layers. Other combinations may also be set and selected.

In addition, when transmitting 4K broadcast programs in the B and C layers, it is possible to adopt not only a uniform constellation but also a non-uniform constellation (NUC) as the carrier modulation mapping method. Figure 6J shows an example of bit allocation in the constellation format. If this parameter is "000", the carrier modulation mapping method selected by the transmission parameters of the TMCC information is applied in a uniform constellation. If this parameter is any of "001" to "111", the carrier modulation mapping method selected by the transmission parameters of the TMCC information is applied in a non-uniform constellation. Note that when applying a non-uniform constellation, the optimal value of the non-uniform constellation differs depending on the type of error correction method and its coding rate, etc. Therefore, when the parameter of the constellation format is any of "001" to "111", the broadcast receiving device 100 of this embodiment may determine the non-uniform constellation to be used in the demodulation process based on the parameters of the carrier modulation mapping method, the parameters of the error correction method, and the parameters of the coding rate. This determination can be made by, for example, referring to a specific table that is pre-stored in the broadcast receiving device 100.

[Transmission method 1 for advanced terrestrial digital broadcasting services]
In order to realize 4K (3840 pixels horizontal x 2160 pixels vertical) broadcasting while maintaining the viewing environment of the current terrestrial digital broadcasting service, a dual-polarized transmission method will be described as an example of a transmission method for advanced terrestrial digital broadcasting services according to an embodiment of the present invention. The dual-polarized transmission method according to an embodiment of the present invention is a method that shares some specifications with the current terrestrial digital broadcasting method. For example, 13 segments within a band of about 6 MHz corresponding to one physical channel are divided, and 7 segments are assigned to the transmission of 2K (1920 pixels horizontal x 1080 pixels vertical) broadcast programs, 5 segments are assigned to the transmission of 4K broadcast programs, and 1 segment is assigned to mobile reception (so-called one-segment broadcasting). Furthermore, the 5 segments for 4K broadcasting use not only horizontally polarized signals but also vertically polarized signals to secure a transmission capacity of a total of 10 segments by MIMO (Multiple-Input Multiple-Output) technology. In addition, for 2K broadcast programs, image quality is maintained by optimizing the latest MPEG-2 Video compression technology, etc., so that they can be received by current television receivers, and for 4K broadcast programs, image quality is ensured by optimizing HEVC compression technology, which is more efficient than MPEG-2 Video, and by multi-value modulation, etc. In addition, the number of segments assigned to each broadcast may be different from that described above.

Figure 7A shows an example of a dual-polarized transmission method for an advanced terrestrial digital broadcasting service according to an embodiment of the present invention. A frequency band of 470 to 710 MHz is used to transmit broadcast waves for the terrestrial digital broadcasting service. There are 40 physical channels in the frequency band, from 13 to 52 ch, and each physical channel has a bandwidth of 6 MHz. In the dual-polarized transmission method according to an embodiment of the present invention, both horizontally polarized and vertically polarized signals are used within one physical channel.

Figure 7A shows two examples of allocation of 13 segments, (1) and (2). In the example (1), a 2K broadcast program is transmitted using segments 1 to 7 (layer B) of the horizontally polarized signal. A 4K broadcast program is transmitted using a total of 10 segments, segments 8 to 12 (layer C) of the horizontally polarized signal and segments 8 to 12 (layer C) of the vertically polarized signal. Segments 1 to 7 (layer B) of the vertically polarized signal may be used to transmit the same broadcast program as the 2K broadcast program transmitted by segments 1 to 7 (layer B) of the horizontally polarized signal. Alternatively, segments 1 to 7 (layer B) of the vertically polarized signal may be used to transmit a broadcast program different from the 2K broadcast program transmitted by segments 1 to 7 (layer B) of the horizontally polarized signal. Alternatively, segments 1 to 7 (layer B) of the vertically polarized signal may be used to transmit other data or may be unused. Identification information on how to use segments 1 to 7 (B layer) of the vertically polarized signal can be transmitted to the receiving device side using the 4K signal transmission layer identification parameter of the TMCC signal and the additional layer transmission identification parameter, as already described. In the broadcast receiving device 100, these parameters can identify how to handle segments 1 to 7 (B layer) of the vertically polarized signal. In addition, a 2K broadcast program transmitted using the B layer of the horizontally polarized signal and a 4K broadcast program transmitted using the C layer of both horizontally and vertically polarized signals may be simulcasts that transmit broadcast programs of the same content at different resolutions, or may transmit broadcast programs of different content. Segment 0 of both horizontally and vertically polarized signals transmits the same OneSeg broadcast program.

The example (2) in FIG. 7A is a modified example different from (1). In the example (2), a 4K broadcast program is transmitted using a total of 10 segments, segments 1 to 5 (layer B) of the horizontally polarized signal and segments 1 to 5 (layer B) of the vertically polarized signal. A 2K broadcast program is transmitted using segments 6 to 12 (layer C) of the horizontally polarized signal. In the example (2), segments 6 to 12 (layer C) of the vertically polarized signal may be used to transmit the same broadcast program as the 2K broadcast program transmitted by segments 6 to 12 (layer C) of the horizontally polarized signal. Segments 6 to 12 (layer C) of the vertically polarized signal may be used to transmit a different broadcast program from the 2K broadcast program transmitted by segments 6 to 12 (layer C) of the horizontally polarized signal. Segments 6 to 12 (layer C) of the vertically polarized signal may be used to transmit other data transmissions or may be unused. These identification information are also the same as in the example (1), so a repeated explanation is omitted.

Note that in both of the examples (1) and (2) in Figure 7A, the horizontal polarization is the main polarization, but depending on the operation, the horizontal and vertical polarizations may be reversed.

Figure 7B shows an example of the configuration of a broadcasting system for an advanced terrestrial digital broadcasting service using a dual-polarized transmission method according to an embodiment of the present invention. This shows both the transmitting system and the receiving system of an advanced terrestrial digital broadcasting service using a dual-polarized transmission method. The configuration of a broadcasting system for an advanced terrestrial digital broadcasting service using a dual-polarized transmission method is basically the same as the configuration of the broadcasting system shown in Figure 1, but the radio tower 300T, which is a broadcasting station facility, is a dual-polarized transmitting antenna that can simultaneously transmit horizontally polarized signals and vertically polarized signals. Also, in the example of Figure 7B, only the tuning/detection unit 131H and tuning/detection unit 131V of the second tuner/demodulation unit 130T of the broadcasting receiving device 100 are shown, and other operating units are omitted.

The horizontally polarized signal sent from the radio tower 300T is received by the horizontally polarized receiving element of the antenna 200T, which is a polarized dual-receiving antenna, and is input to the channel selection/detection unit 131H from the connector 100F1 via the coaxial cable 202T1. On the other hand, the vertically polarized signal sent from the radio tower 300T is received by the vertically polarized receiving element of the antenna 200T, and is input to the channel selection/detection unit 131V from the connector 100F2 via the coaxial cable 202T2. An F-type connector is generally used for the connector that connects the antenna (coaxial cable) to the television receiver.

Here, the user may mistakenly connect the coaxial cable 202T1 to the connector unit 100F2 and the coaxial cable 202T2 to the connector unit 100F1. In this case, there is a possibility that the tuning/detection unit 131H and the tuning/detection unit 131V may have a problem such as being unable to identify whether the input broadcast signal is a horizontally polarized signal or a vertically polarized signal. In order to prevent the above-mentioned problem, it is possible to use a connector unit with a different shape from the F-type connector of the connector unit of the coaxial cable 202T1 and the connector unit 100F1 that transmits a horizontally polarized signal on one side of the connector unit that connects the antenna (coaxial cable) and the television receiver, for example, the coaxial cable 202T2 and the connector unit 100F2 that transmits a vertically polarized signal. Alternatively, the tuning/detection unit 131H and the tuning/detection unit 131V may be controlled to identify whether the input broadcast signal is a horizontally polarized signal or a vertically polarized signal by referring to the main signal identification of the TMCC information of each input signal and operate accordingly.

Figure 7C shows an example of a configuration example of a broadcasting system for advanced terrestrial digital broadcasting services using a dual-polarized transmission method according to an embodiment of the present invention, which is different from the above. As shown in Figure 7B, the broadcasting receiver 100 has two connectors for inputting broadcasting signals, and two coaxial cables are used to connect the antenna 200T and the broadcasting receiver 100. This may not be ideal in terms of equipment costs and handling during cable wiring. Therefore, in the configuration shown in Figure 7C, the horizontally polarized signal received by the horizontally polarized receiving element of the antenna 200T and the vertically polarized signal received by the vertically polarized receiving element of the antenna 200T are input to the converter 201T, and the converter 201T and the broadcasting receiver 100 are connected by a single coaxial cable 202T3. The broadcasting signal input from the connector 100F3 is split and input to the tuning/detection unit 131H and the tuning/detection unit 131V. The connector unit 100F3 may have the function of supplying operating power to the conversion unit 201T.

The conversion unit 201T may belong to the equipment of the environment in which the broadcast receiving device 100 is installed (for example, an apartment building). Alternatively, it may be configured as an integrated device with the antenna 200T and installed in a house or the like. The conversion unit 201T performs frequency conversion processing on either the horizontally polarized signal received by the horizontally polarized wave receiving element of the antenna 200T or the vertically polarized signal received by the vertically polarized wave receiving element of the antenna 200T. This processing makes it possible to separate the horizontally polarized signal and the vertically polarized signal transmitted from the radio tower 300T to the antenna 200T using horizontally polarized waves and vertically polarized waves of the same frequency band into different frequency bands and transmit them simultaneously to the broadcast receiving device 100 through a single coaxial cable 202T3. If necessary, frequency conversion processing may be performed on both the horizontally polarized signal and the vertically polarized signal, but in this case, the frequency bands of the two signals after frequency conversion must be different from each other. In addition, the broadcast receiving device 100 may be provided with one broadcast signal input connector unit 100F3.

Figure 7D shows an example of frequency conversion processing. In this example, frequency conversion processing is performed on a vertically polarized signal. Specifically, of the horizontally polarized signal and vertically polarized signal transmitted in the frequency band of 470-710 MHz (corresponding to UHF ch13-52), the frequency band of the vertically polarized signal is converted from 470-710 MHz to 770-1010 MHz. This processing allows signals transmitted using horizontally polarized and vertically polarized waves of the same frequency band to be simultaneously transmitted to the broadcast receiving device 100 via a single coaxial cable 202T3 without mutual interference. Note that frequency conversion processing may also be performed on the horizontally polarized signal.

Furthermore, it is preferable to perform the frequency conversion process on the signal transmitted in the secondary polarization depending on the result of referring to the main signal identification in the TMCC information. As explained using FIG. 5H, the signal transmitted in the primary polarization is more likely to include the current terrestrial digital broadcasting service than the signal transmitted in the secondary polarization. Therefore, in order to more appropriately maintain compatibility with the current terrestrial digital broadcasting service, it is preferable to frequency convert the signal transmitted in the secondary polarization without frequency converting the signal transmitted in the primary polarization.

In addition, when a signal transmitted in the secondary polarization is frequency converted, it is desirable to make the frequency band of the converted signal higher than that of the signal transmitted in the primary polarization. This allows the initial scan of the broadcast receiving device 100 to be performed before the initial scan of the signal transmitted in the primary polarization by starting from the low frequency side and proceeding to the high frequency side. This makes it possible to more suitably perform processes such as reflecting the settings from the initial scan of the current terrestrial digital broadcasting service in the settings from the initial scan of an advanced terrestrial digital broadcasting service.

Frequency conversion processing may be performed on all physical channels used in advanced terrestrial digital broadcasting services, but may also be performed only on physical channels that use a dual-polarized transmission method for signal transmission.

It is preferable that the frequency band after the frequency conversion process is between 710 and 1032 MHz. That is, when trying to simultaneously receive terrestrial digital broadcasting services and BS/CS digital broadcasting services, it is possible to mix the broadcast signal of the terrestrial digital broadcasting service received by antenna 200T and the broadcast signal of the BS/CS digital broadcasting service received by antenna 200B and transmit them to the broadcast receiving device 100 via a single coaxial cable. In this case, since the BS/CS-IF signal uses a frequency band of about 1032 to 2150 MHz, if the frequency band after the frequency conversion process is set to be between 710 and 1032 MHz, it is possible to avoid interference between the horizontally polarized signal and the vertically polarized signal, while also avoiding interference between the broadcast signal of the terrestrial digital broadcasting service and the broadcast signal of the BS/CS digital broadcasting service. In addition, when taking into consideration the reception of retransmitted broadcast signals by cable television (Community Antenna TV or Cable TV: CATV) stations, since the frequency band below 770 MHz (the band equivalent to UHF ch 62 or less) is used for television broadcast distribution by cable television stations, it is more preferable to set the frequency band after the frequency conversion process to between 770 and 1032 MHz, which is above the band equivalent to UHF ch 62.

In addition, it is preferable to set the bandwidth of the area between the frequency band before and after the frequency conversion process (part a in the figure) to be an integer multiple of the bandwidth of one physical channel (6 MHz). This has the advantage that frequency setting control is easier when, for example, the broadcast receiving device 100 performs frequency scanning of the broadcast signal of the frequency band before and after the frequency conversion process all at once.

As described above, in the dual-polarized transmission method according to the embodiment of the present invention, both horizontally polarized and vertically polarized signals are used to transmit 4K broadcast programs. Therefore, in order to correctly play back 4K broadcast programs, it is necessary for the receiving side to correctly grasp the combination of physical channels of broadcast signals transmitted with horizontal polarization and broadcast signals transmitted with vertical polarization. Even if a frequency conversion process is performed and a broadcast signal transmitted with horizontal polarization and a broadcast signal transmitted with vertical polarization for the same physical channel are input to the receiving device as signals of different frequency bands, the broadcast receiving device 100 of this embodiment can correctly grasp the combination of broadcast signals transmitted with horizontal polarization and broadcast signals transmitted with vertical polarization for the same physical channel by appropriately referring to the parameters of the TMCC information shown in Figures 5F to 5J (e.g., main signal identification and physical channel number identification). As a result, the broadcast receiving device 100 of this embodiment can appropriately receive, demodulate, and play back 4K broadcast programs.

Note that the examples in Figures 7B, 7C, and 7D all explain cases where horizontal polarization is the primary polarization, but depending on the operation, the horizontal and vertical polarizations may be reversed.

As described above, the terrestrial digital broadcasting waves transmitted by the dual-polarized transmission method described above can be received and played back by the second tuner/demodulator 130T of the broadcast receiving device 100, but can also be received by the first tuner/demodulator 130C of the broadcast receiving device 100. When the terrestrial digital broadcasting waves are received by the first tuner/demodulator 130C, the broadcasting signals of the terrestrial digital broadcasting waves that are transmitted at the layer of the advanced terrestrial digital broadcasting service are ignored, but the broadcasting signals that are transmitted at the layer of the current terrestrial digital broadcasting service are played back.

<Pass-through transmission method for advanced terrestrial digital broadcasting services>
The broadcast receiving device 100 is capable of receiving signals transmitted by a pass-through transmission method. The pass-through transmission method is a method in which a broadcast signal received by a cable television station or the like is sent to a CATV distribution system in the same frequency as the signal method, or after frequency conversion.

There are two types of pass-through methods: (1) a method in which the transmission signal band of each digital terrestrial broadcasting signal output from a terrestrial receiving antenna is extracted and its level is adjusted, and the signal is transmitted to the CATV facility at the same frequency as the transmission signal frequency; and (2) a method in which the transmission signal band of each digital terrestrial broadcasting signal output from a terrestrial receiving antenna is extracted and its level is adjusted, and the signal is transmitted to the CATV facility at a frequency of the VHF band, MID band, SHB band, or UHF band set by the CATV facility manager. The equipment constituting the receiving amplifier for performing signal processing of the first method, or the equipment constituting the receiving amplifier and frequency converter for performing signal processing of the second method, is an OFDM signal processor (OFDM-SP).

Figure 7E shows an example of a system configuration when the first pass-through transmission method is applied to an advanced terrestrial digital broadcasting service using a dual-polarized transmission method. Figure 7E shows a cable television station's head-end equipment 400C and a broadcast receiving device 100. Figure 7F shows an example of the frequency conversion process in this case. The notation (H・V) in Figure 7F indicates the state of a broadcast signal in which both a horizontally polarized broadcast signal and a vertically polarized broadcast signal exist in the same frequency band, the notation (H) indicates a broadcast signal transmitted with horizontal polarization, and the notation (V) indicates a broadcast signal transmitted with vertical polarization. The notations in the following Figures 7H and 7I have the same meaning.

When the pass-through transmission of the first method is applied to the advanced terrestrial digital broadcasting service of the dual-polarized transmission method of the embodiment of the present invention, the broadcast signal transmitted with horizontal polarization is subjected to signal band extraction and level adjustment in the cable television station's head-end equipment 400C, and is sent out at the same frequency as the transmission signal frequency. On the other hand, the broadcast signal transmitted with vertical polarization is subjected to signal band extraction and level adjustment in the cable television station's head-end equipment 400C, and is sent out after frequency conversion processing similar to that described in FIG. 7D (processing of converting the broadcast signal transmitted with vertical polarization to a frequency band higher than the frequency band of 470 to 770 MHz, which is the band corresponding to UHF 13ch to 62ch). This processing prevents the frequency bands of the broadcast signal transmitted with horizontal polarization and the broadcast signal transmitted with vertical polarization from overlapping, making it possible to transmit the signal over a single coaxial cable (or optical fiber cable). The transmitted signal can be received by the broadcast receiving device 100 of this embodiment. In the broadcast receiving device 100 of this embodiment, the process of receiving and demodulating the broadcast signal transmitted with horizontal polarization and the broadcast signal transmitted with vertical polarization contained in the signal is the same as that described in FIG. 7D, so a repeated description will be omitted.

Figure 7G shows an example of a system configuration in which the second pass-through transmission method is applied to an advanced terrestrial digital broadcasting service using a dual-polarized transmission method. Figure 7G shows a cable television station's head-end equipment 400C and a broadcast receiving device 100. Figure 7H also shows an example of the frequency conversion process that is performed in this case.

When the pass-through transmission of the second method is applied to the advanced terrestrial digital broadcasting service of the dual-polarized transmission method of the embodiment of the present invention, the broadcast signal transmitted with horizontal polarization is subjected to signal band extraction and level adjustment in the cable television station's head-end equipment 400C, and frequency conversion processing to the frequency set by the CATV facility manager is performed before transmission. On the other hand, the broadcast signal transmitted with vertical polarization is subjected to signal band extraction and level adjustment in the cable television station's head-end equipment 400C, and frequency conversion processing similar to that described in FIG. 7D (processing of converting the broadcast signal transmitted with vertical polarization to a frequency band higher than the frequency band of 470 to 770 MHz, which is the band of UHF 13ch to 62ch) is performed before transmission. The frequency conversion processing shown in FIG. 7H is different from that in FIG. 7F, in that the broadcast signal transmitted with horizontal polarization is not limited to the frequency band of 470 to 770 MHz, which is the band of UHF 13ch to 62ch, but is expanded to a lower frequency band and rearranged in the range of 90 to 770 MHz. This process prevents the frequency bands of the broadcast signals transmitted with horizontal polarization and those transmitted with vertical polarization from overlapping, making it possible to transmit the signals using a single coaxial cable (or optical fiber cable). The transmitted signals can be received by the broadcast receiving device 100 of this embodiment. The process of receiving and demodulating the broadcast signals transmitted with horizontal polarization and those transmitted with vertical polarization contained in the signal in the broadcast receiving device 100 of this embodiment is the same as that described in FIG. 7D, so a repeated description will be omitted.

As another modification of the frequency conversion process of the cable television station's head-end equipment 400C in FIG. 7G, the broadcast signal at the time of pass-through output after frequency conversion may be changed from the state shown in FIG. 7H to the state shown in FIG. 7I. In this case, the signal band extraction and level adjustment may be performed on both the broadcast signal transmitted with horizontal polarization and the broadcast signal transmitted with vertical polarization, and the frequency conversion process may be performed to the frequency set by the CATV facility manager before transmission. In the example of FIG. 7I, frequency conversion is performed so that both the broadcast signal transmitted with horizontal polarization and the broadcast signal transmitted with vertical polarization are rearranged in the range of 90 to 770 MHz (VHF1ch to UHF62ch), and since the frequency band beyond UHF62ch is not used, the frequency band utilization efficiency of the broadcast signal is higher than that of FIG. 7H.

In addition, since the band in which the broadcast signals are rearranged is wider than the 470-710 MHz frequency band, which is the band of UHF 13ch-52ch during antenna reception, it is also possible to alternately rearrange broadcast signals transmitted with horizontal polarization and broadcast signals transmitted with vertical polarization, as shown in the example of FIG. 7I. In this case, as shown in the example of FIG. 7I, if pairs of broadcast signals transmitted with horizontal polarization and broadcast signals transmitted with vertical polarization that were on the same physical channel during antenna reception are rearranged alternately in the order of the physical channels during antenna reception, when the broadcast receiving device 100 of this embodiment performs an initial scan from the low frequency side, it is possible to proceed with initial setup of pairs of broadcast signals transmitted with horizontal polarization and broadcast signals transmitted with vertical polarization that were originally on the same physical channel in order of the originally same physical channel, and the initial scan can be performed efficiently.

Note that the examples in Figures 7E, 7F, 7G, 7H, and 7I all describe cases where horizontal polarization is the primary polarization, but depending on the application, the horizontal and vertical polarizations may be reversed.

As described above, the terrestrial digital broadcasting waves of the dual-polarized transmission method using the pass-through transmission method described above can be received and played back by the second tuner/demodulator 130T of the broadcast receiving device 100, but can also be received by the first tuner/demodulator 130C of the broadcast receiving device 100. When the terrestrial digital broadcasting waves are received by the first tuner/demodulator 130C, the broadcasting signals of the terrestrial digital broadcasting waves that are transmitted at the layer of the advanced terrestrial digital broadcasting service are ignored, but the broadcasting signals that are transmitted at the layer of the current terrestrial digital broadcasting service are played back.

[Transmission method 2 for advanced terrestrial digital broadcasting services]
In order to realize 4K broadcasting while maintaining the viewing environment of the current terrestrial digital broadcasting service, a hierarchical division multiplexing transmission method will be described as an example of an advanced terrestrial digital broadcasting service transmission method according to an embodiment of the present invention that is different from the above. The hierarchical division multiplexing transmission method according to an embodiment of the present invention is a method that shares some specifications with the current terrestrial digital broadcasting method. For example, the broadcast waves of a 4K broadcasting service, which has a low signal level, are multiplexed and transmitted on the same channel as the broadcast waves of a current 2K broadcasting service. Note that the reception level of the 4K broadcasting is suppressed to a required C/N or less, and the 2K broadcasting is received as usual. For 4K broadcasting, the transmission capacity is expanded by modulation multi-value, etc., and the 2K broadcasting wave is canceled using a reception technology corresponding to LDM (hierarchical division multiplexing) technology, and reception is performed with the remaining 4K broadcasting wave.

Figure 8A shows an example of a hierarchical division multiplexing transmission method in an advanced terrestrial digital broadcasting service according to an embodiment of the present invention. The upper layer is composed of modulated waves of the current 2K broadcasting, and the lower layer is composed of modulated waves of the 4K broadcasting. The upper layer and the lower layer are multiplexed and output as a composite wave in the same frequency band. For example, the upper layer may use 64QAM or the like as a modulation method, and the lower layer may use 256QAM or the like as a modulation method. Note that the 2K broadcast program transmitted using the upper layer and the 4K broadcast program transmitted using the lower layer may be simulcasts that transmit broadcast programs of the same content at different resolutions, or may transmit broadcast programs of different content. Here, the upper layer is transmitted at high power, and the lower layer is transmitted at low power. Note that the difference (power difference) between the modulated wave level of the upper layer and the modulated wave level of the lower layer is called the injection level (IL), which is a value set by the broadcasting station. The injection level is typically expressed as a logarithmic relative ratio (dB) of the difference in modulated wave levels (difference in power).

Figure 8B shows an example of the configuration of a broadcasting system for an advanced terrestrial digital broadcasting service using a hierarchical division multiplexing transmission method according to an embodiment of the present invention. The configuration of a broadcasting system for an advanced terrestrial digital broadcasting service using a hierarchical division multiplexing transmission method is basically the same as the configuration of the broadcasting system shown in Figure 1, but the radio tower 300L, which is a broadcasting station facility, is a transmitting antenna that sends out a broadcast signal that is a multiplex of 2K broadcasting on the upper layer and 4K broadcasting on the lower layer. Also, in the example of Figure 8B, only the tuning/detection unit 131L of the third tuner/demodulation unit 130L of the broadcast receiving device 100 is shown, and other operating units are omitted.

The broadcast signal received by the antenna 200L is input from the connector 100F4 to the channel selection/detection unit 131L via the conversion unit (converter) 201L and the coaxial cable 202L. Here, in the above configuration, when the broadcast signal is transmitted from the antenna 200L to the broadcast receiving device 100, the conversion unit 201L may perform frequency conversion and amplification processing on the broadcast signal, as shown in FIG. 8C. That is, if the antenna 200L is installed on the roof of an apartment building or the like, and the broadcast signal is transmitted to the broadcast receiving device 100 in each room via the long coaxial cable 202L, the broadcast signal may be attenuated, and the channel selection/detection unit 131L may be unable to properly receive the 4K broadcast waves, especially in the lower hierarchical layers.

Therefore, in order to prevent the above-mentioned problem, the conversion unit 201L performs a frequency conversion and amplification process on the 4K broadcast signal of the lower layer. The frequency conversion and amplification process converts the frequency band of the 4K broadcast signal of the lower layer from a frequency band of 470 to 710 MHz (a band corresponding to UHF 13ch to 52ch) to, for example, a frequency band of 770 to 1010 MHz, which exceeds the band corresponding to UHF 62ch. Furthermore, a process is performed to amplify the 4K broadcast signal of the lower layer to a signal level at which the influence of attenuation in the cable is not a problem. By performing such a process, it is possible to avoid the influence of attenuation of the broadcast signal during transmission over the coaxial cable while avoiding interference between the 2K broadcast signal and the 4K broadcast signal. Note that, when the influence of attenuation is not a problem, such as when the cable length of the coaxial cable 202L is short, the conversion unit 201L and the frequency conversion and amplification process may be unnecessary.

Furthermore, the frequency band after the frequency conversion and amplification process is preferably between 710 and 1032 MHz, which exceeds the band corresponding to UHF 52ch, or between 770 and 1032 MHz, which exceeds the band corresponding to UHF 62ch (in the case of retransmission by a cable television station, etc.), the bandwidth of the area between the frequency band before the conversion and the frequency band after the conversion by the frequency conversion and amplification process is preferably set to be an integer multiple of the bandwidth of one physical channel (6 MHz), and the frequency conversion and amplification process may be performed only on physical channels that use signal transmission by the hierarchical division multiplexing transmission method. All of these are the same as the explanation of this embodiment related to frequency conversion already explained, so a repeated explanation will be omitted.

The broadcast receiving device 100 of this embodiment can identify whether the received broadcast signal is a broadcast signal transmitted in a lower layer or an upper layer by using the upper/lower layer identification bit of the TMCC information described in FIG. 5H. The broadcast receiving device 100 of this embodiment can also identify whether the received broadcast signal is a broadcast signal that has been frequency converted after antenna reception by using the frequency conversion processing identification bit of the TMCC information described in FIG. 5F. The broadcast receiving device 100 of this embodiment can also identify whether the received broadcast signal transmits a 4K program in a lower layer by using the 4K signal transmission layer identification bit of the TMCC information described in FIG. 5I. These identification processes can be performed by demodulating the data carrier and referring to the control information contained in the stream, but this requires demodulation of the data carrier, which makes the process complicated. Since the identification process is simpler and faster by referring to the parameters of the TMCC information described above, it is possible to speed up the initial scan of the broadcast receiving device 100, for example.

As already explained, the channel selection/detection unit 131L of the third tuner/demodulation unit 130L of the broadcast receiving device 100 according to the embodiment of the present invention has a receiving function compatible with LDM (hierarchical division multiplexing) technology, so the conversion unit 201L shown in FIG. 8C is not necessarily required between the antenna 200L and the broadcast receiving device 100.

As mentioned above, the terrestrial digital broadcasting waves transmitted by the hierarchical division multiplexing transmission method described above can be received and played by the third tuner/demodulator 130L of the broadcast receiving device 100, but can also be received by the first tuner/demodulator 130C of the broadcast receiving device 100. When the terrestrial digital broadcasting waves are received by the first tuner/demodulator 130C, the broadcasting signals of the terrestrial digital broadcasting waves that are transmitted at the hierarchical level of the advanced terrestrial digital broadcasting service are ignored, but the broadcasting signals that are transmitted at the hierarchical level of the current terrestrial digital broadcasting service are played.

[MPEG-2 TS format]
The broadcasting system of this embodiment is compatible with MPEG-2 TS, which is adopted in current terrestrial digital broadcasting services, etc., as a media transport method for transmitting data such as video and audio. Specifically, the method of the stream transmitted by the OFDM transmission wave of FIG. 4D(1) is MPEG-2 TS, and the method of the stream transmitted in the hierarchical layer where the current terrestrial digital broadcasting service is transmitted among the OFDM transmission waves of FIG. 4D(2) and FIG. 4D(3) is MPEG-2 TS. Also, the method of the stream obtained by demodulating the transmission wave in the first tuner/demodulator 130C of the broadcast receiving device 100 of FIG. 2 is MPEG-2 TS. Also, the method of the stream corresponding to the hierarchical layer where the current terrestrial digital broadcasting service is transmitted among the stream obtained by demodulating the transmission wave in the second tuner/demodulator 130T is MPEG-2 TS. Similarly, among the streams obtained by demodulating the transmission wave in the third tuner/demodulator 130L, the format of the stream corresponding to the layer at which the current terrestrial digital broadcasting service is transmitted is MPEG-2 TS.

MPEG-2 TS is characterized by multiplexing the video, audio, and other components that make up a program together with control signals and a clock into a single packet stream. As the clock is also treated as a single packet stream, it is suitable for transmitting a single piece of content over a single transmission path with guaranteed transmission quality, and is therefore adopted in many current digital broadcasting systems. It is also possible to achieve two-way communication via two-way networks such as fixed and mobile networks, and is compatible with broadcasting and communication linkage systems that link digital broadcasting services with functions that utilize broadband networks, and combine digital broadcasting services with the acquisition of additional content via broadband networks, calculation processing in server devices, and presentation processing in linkage with mobile terminal devices.

Figure 9A shows an example of a protocol stack for a transmission signal in a broadcasting system that uses MPEG-2 TS. In MPEG-2 TS, PSI, SI, and other control signals are transmitted in section format.

[Control signal for broadcasting system using MPEG-2 TS format]
The control information in the MPEG-2 TS format includes tables used mainly for program sequence information and tables used for other purposes. Tables are transmitted in section format, and descriptors are placed within the tables.

<Tables used in program service information>
9B shows a list of tables used in the program sequence information of the MPEG-2 TS broadcasting system. In this embodiment, the following tables are used for the program sequence information.

(1) Program Association Table (PAT)
(2) CAT (Conditional Access Table)
(3) PMT (Program Map Table)
(4) NIT (Network Information Table)
(5) SDT (Service Description Table)
(6) BAT (Bouquet Association Table)
(7) EIT (Event Information Table)
(8) RST (Running Status Table)
(9) Time and Date Table (TDT)
(10) Time Offset Table (TOT)

(11) Local Event Information Table (LIT)
(12) ERT (Event Relation Table)
(13) ITT (Index Transmission Table)
(14) PCAT (Partial Content Announcement Table)
(15) ST (Stuffing Table)
(16) BIT (Broadcaster Information Table)
(17) NBIT (Network Board Information Table)
(18) Linked Description Table (LDT)
(19) AMT (Address Map Table)
(20) INT (IP/MAC Notification Table)
(21) Tables set by business operators

<Tables used in digital broadcasting>
9C shows a list of tables used for information other than program sequence information in the MPEG-2 TS broadcasting system. In this embodiment, the following tables are used for information other than program sequence information.

(1) ECM (Entitlement Control Message)
(2) EMM (Entitlement Management Message)
(3) Download Control Table (DCT)
(4) DLT (Download Table)
(5) Discontinuity Information Table (DIT)
(6) SIT (Selection Information Table)
(7) SDTT (Software Download Trigger Table)
(8) Common Data Table (CDT)
(9) DSM-CC Section (10) AIT (Application Information Table)
(11) DCM (Download Control Message)
(12) DMM (Download Management Message)
(13) Tables set by operators

<Descriptors used in program service information>
9D, 9E, and 9F show a list of descriptors used in program sequence information of an MPEG-2 TS broadcasting system. In this embodiment, the following descriptors are used in the program sequence information.

(1) Conditional Access Descriptor
(2) Copyright Descriptor
(3) Network Name Descriptor
(4) Service List Descriptor
(5) Stuffing Descriptor
(6) Satellite Delivery System Descriptor
(7) Terrestrial Delivery System Descriptor
(8) Bouquet Name Descriptor
(9) Service Descriptor
(10) Country Availability Descriptor

(11) Linkage Descriptor
(12) NVOD Reference Descriptor
(13) Time Shifted Service Descriptor
(14) Short Event Descriptor
(15) Extended Event Descriptor
(16) Time Shifted Event Descriptor
(17) Component Descriptor
(18) Mosaic Descriptor
(19) Stream Identifier Descriptor
(20) CA Identifier Descriptor

(21) Content Descriptor
(22) Parental Rating Descriptor
(23) Hierarchical Transmission Descriptor
(24) Digital Copy Control Descriptor
(25) Emergency Information Descriptor
(26) Data Component Descriptor
(27) System Management Descriptor
(28) Local Time Offset Descriptor
(29) Audio Component Descriptor
(30) Target Region Descriptor

(31) Hyperlink Descriptor
(32) Data Content Descriptor
(33) Video Decode Control Descriptor
(34) Basic Local Event Descriptor
(35) Reference Descriptor
(36) Node Relation Descriptor
(37) Short Node Information Descriptor
(38) STC Reference Descriptor
(39) Partial Reception Descriptor
(40) Series Descriptor

(41) Event Group Descriptor
(42) SI Transmission Parameter Descriptor
(43) Broadcaster Name Descriptor
(44) Component Group Descriptor
(45) SI Prime TS Descriptor
(46) Board Information Descriptor
(47) LDT Linkage Descriptor
(48) Connected Transmission Descriptor
(49) TS Information Descriptor
(50) Extended Broadcaster Descriptor

(51) Logo Transmission Descriptor
(52) Content Availability Descriptor
(53) Carousel Compatible Composite Descriptor
(54) Conditional Playback Descriptor
(55) AVC Video Descriptor
(56) AVC Timing and HRD Descriptor
(57) Service Group Descriptor
(58) MPEG-4 Audio Descriptor
(59) MPEG-4 Audio Extension Descriptor
(60) Registration Descriptor

(61) Data Broadcast Id Descriptor
(62) Access Control Descriptor
(63) Area Broadcasting Information Descriptor
(64) Material Information Descriptor
(65) HEVC Video Descriptor
(66) Hierarchy Descriptor
(67) Hybrid Information Descriptor
(68) Scrambler Descriptor
(69) Descriptors set by carriers

<Descriptors used in digital broadcasting>
9G shows a list of descriptors used for information other than program sequence information in the MPEG-2 TS broadcasting system. In this embodiment, the following descriptors are used for information other than program sequence information.

(1) Partial Transport Stream Descriptor
(Partial Transport Stream Descriptor)
(2) Network Identification Descriptor
(3) Partial Transport Stream Time Descriptor
(Partial Transport Stream Time Descriptor)
(4) Download Content Descriptor
(5) CA EMM TS Descriptor
(6) CA Contract Information Descriptor
(7) CA Service Descriptor
(8) Carousel Identifier Descriptor
(9) Association Tag Descriptor
(10) Extended Association Tag Descriptor
(Deferred Association tags Descriptor)
(11) Network Download Content Descriptor
(Network Download Content Descriptor)
(12) Download Protection Descriptor
(13) CA Startup Descriptor
(14) Descriptors set by carriers

<Descriptors used in INT>
A list of the descriptors used in the INT of the MPEG-2 TS broadcasting system is shown in Fig. 9H. In this embodiment, the following descriptors are used in the INT. Note that the above-mentioned descriptors used in the program sequence information and descriptors used for other than the program sequence information are not used in the INT.

(1) Target Smartcard Descriptor
(2) Target IP Address Descriptor
(3) Target IPv6 Address Descriptor
(4) IP/MAC Platform Name Descriptor
(5) IP/MAC Platform Provider Name Descriptor
(IP/MAC Platform Provider Name Descriptor)
(6) IP/MAC Stream Location Descriptor
(7) Descriptors set by carriers

<Descriptors used in AIT>
Fig. 9I shows a list of the descriptors used in the AIT of the MPEG-2 TS broadcasting system. In this embodiment, the following descriptors are used in the AIT. Note that the above-mentioned descriptors used in the program sequence information and descriptors used for purposes other than the program sequence information are not used in the INT.

(1) Application Descriptor
(2) Transport Protocol Descriptor
(3) Simple Application Location Descriptor
(Simple Application Location Descriptor)
(4) Application Boundary Authority Setting Descriptor
(Application Boundary and Permission Descriptor)
(5) Autostart Priority Descriptor
(6) Cache Control Info Descriptor
(7) Randomized Latency Descriptor
(8) External Application Control Descriptor
(External Application Control Descriptor)
(9) Playback Application Descriptor
(10) Simple Recording/Playback Application Location Descriptor
(Simple Playback Application Location Descriptor)
(11) Application Expiration Descriptor
(12) Descriptors set by carriers

[MMT method]
The broadcasting system of this embodiment can also support the MMT method as a media transport method for transmitting data such as video and audio. Specifically, among the OFDM transmission waves in FIG. 4D(2) and FIG. 4D(3), the method of the stream transmitted in the layer where the advanced terrestrial digital broadcasting service is transmitted is the MMT method in principle. Also, among the streams obtained by demodulating the transmission wave in the second tuner/demodulation unit 130T of the broadcast receiving device 100 in FIG. 2, the method of the stream corresponding to the layer where the advanced terrestrial digital broadcasting service is transmitted is the MMT method in principle. Similarly, among the streams obtained by demodulating the transmission wave in the third tuner/demodulation unit 130L, the method of the stream corresponding to the layer where the advanced terrestrial digital broadcasting service is transmitted is the MMT method in principle. Note that, as a modified example, an MPEG-2 TS stream may be used in the advanced terrestrial digital broadcasting service. Also, the method of the stream obtained by demodulating the transmission wave in the fourth tuner/demodulation unit 130B is the MMT method.

The MMT method is a newly developed media transport method because the MPEG-2 TS method has limitations in its functionality in response to changes in the content distribution environment, such as the recent diversification of content, the diversification of devices that use content, the diversification of transmission paths for distributing content, and the diversification of content storage environments.

The video and audio signals of a broadcast program are encoded as MFU (Media Fragment Unit)/MPU (Media Processing Unit), loaded on the MMTP (MMT Protocol) payload, packetized as MMTP packets, and transmitted as IP packets. In addition, the signals of data content and subtitles related to the broadcast program are also in MFU/MPU format, loaded on the MMTP payload, packetized as MMTP packets, and transmitted as IP packets.

For transmitting MMTP packets, UDP/IP (User Datagram Protocol/Internet Protocol) is used on the broadcast transmission path, and UDP/IP or TCP/IP (Transmission Control Protocol/Internet Protocol) is used on the communication line. In addition, the TLV multiplexing method may be used on the broadcast transmission path for efficient transmission of IP packets.

Figure 10A shows the MMT protocol stack on a broadcast transmission path. Figure 10B shows the MMT protocol stack on a communication line. The MMT method provides a mechanism for transmitting two types of control information: MMT-SI and TLV-SI. MMT-SI is control information that indicates the configuration of a broadcast program, etc. It is formatted as an MMT control message, placed on the MMTP payload, packetized as an MMTP packet, and transmitted in an IP packet. TLV-SI is control information related to multiplexing of IP packets, and provides information for channel selection and information on the correspondence between IP addresses and services.

[Control signal of broadcasting system using MMT method]
As mentioned above, in the MMT method, TLV-SI and MMT-SI are prepared as control information. TLV-SI is composed of tables and descriptors. Tables are transmitted in section format, and descriptors are placed in tables. MMT-SI is composed of three layers: messages that store tables and descriptors, tables with elements and attributes that indicate specific information, and descriptors that indicate more detailed information.

<Tables used in TLV-SI>
10C shows a list of tables used in the TLV-SI of the MMT broadcasting system. In this embodiment, the following tables are used as the TLV-SI tables.

(1) Network Information Table for TLV
(2) Address Map Table
(3) Tables set by operators

<Descriptors used in TLV-SI>
10D shows a list of descriptors used in the TLV-SI of the MMT broadcasting system. In this embodiment, the following descriptors are used as the TLV-SI descriptors.

(1) Service List Descriptor
(2) Satellite Delivery System Descriptor
(3) System Management Descriptor
(4) Network Name Descriptor
(5) Remote Control Key Descriptor
(6) Descriptors set by operators

<Messages used in MMT-SI>
10E shows a list of messages used in MMT-SI of the MMT broadcasting system. In this embodiment, the following messages are used as MMT-SI messages.

(1) PA (Package Access) message (2) M2 section message (3) CA message (4) M2 short section message (5) Data transmission message (6) Message set by the carrier

<Tables used in MMT-SI>
10F shows a list of tables used in MMT-SI of the MMT broadcasting system. In this embodiment, the following tables are used as MMT-SI tables.

(1) MPT (MMT Package Table)
(2) PLT (Package List Table)
(3) LCT (Layout Configuration Table)
(4) ECM (Entitlement Control Message)
(5) EMM (Entitlement Management Message)
(6) Conditional Access Table (MH)
(7) DCM (Download Control Message)
(8) DMM (Download Management Message)
(9) MH-Event Information Table (MH-EIT)
(10) MH-AIT (MH-Application Information Table)

(11) MH-BIT (MH-Broadcaster Information Table)
(12) MH-SDTT (MH-Software Download Trigger Table)
(13) MH-SDT (MH-Service Description Table)
(14) MH-TOT (MH-Time Offset Table)
(15) MH-CDT (MH-Common Data Table)
(16) DDM table (Data Directory Management Table)
(17) Data Asset Management Table (DAM Table)
(18) DCC Table (Data Content Configuration Table)
(19) EMT (Event Message Table)
(20) Tables set by operators

<Descriptors used in MMT-SI>
10G, 10H, and 10I show a list of descriptors used in MMT-SI of the MMT broadcasting system. In this embodiment, the following descriptors are used as MMT-SI descriptors.

(1) Asset Group Descriptor
(2) Event Package Descriptor
(3) Background Color Descriptor
(4) MPU Presentation Region Descriptor
(5) MPU Timestamp Descriptor
(6) Dependency Descriptor
(7) Access Control Descriptor
(8) Scrambler Descriptor
(9) Message Authentication Method Descriptor
(10) Emergency Information Descriptor

(11) MH-MPEG-4 Audio Descriptor
(12) MH-MPEG-4 Audio Extension Descriptor
(MH-MPEG-4 Audio Extension Descriptor)
(13) MH-HEVC Descriptor
(14) MH-Linkage Descriptor
(15) MH-Event Group Descriptor
(16) MH-Service List Descriptor
(17) MH-Short Event Descriptor
(18) MH-Extended Event Descriptor
(19) Video Component Descriptor
(20) MH-Stream Identifier Descriptor

(21) MH-Content Descriptor
(22) MH-Parental Rating Descriptor
(23) MH-Audio Component Descriptor
(24) MH-Target Region Descriptor
(25) MH-Series Descriptor
(26) MH-SI Parameter Descriptor
(27) MH-Broadcaster Name Descriptor
(28) MH-Service Descriptor
(29) IP Data Flow Descriptor
(30) MH-CA Startup Descriptor

(31) MH-Type Descriptor
(32) MH-Info Descriptor
(33) MH-Expire Descriptor
(34) MH-CompressionType Descriptor
(MH-Compression Type Descriptor)
(35) MH-Data Component Descriptor
(36) UTC-NPT Reference Descriptor
(37) Event Message Descriptor
(38) MH-Local Time Offset Descriptor
(39) MH-Component Group Descriptor
(40) MH-Logo Transmission Descriptor

(41) MPU Extended Timestamp Descriptor
(42) MPU Download Content Descriptor
(43) MH-Network Download Content Descriptor
(MH-Network Download Content Descriptor)
(44) Application Descriptor (MH-Application Descriptor)
(45) MH-Transport Protocol Descriptor
(46) MH-Simple Application Location Descriptor
(MH-Simple Application Location Descriptor)
(47) Application Boundary Authority Setting Descriptor
(MH-Application Boundary and Permission Descriptor)
(48) MH-Autostart Priority Descriptor
(49) MH-Cache Control Info Descriptor
(50) MH-Randomized Latency Descriptor

(51) Linked PU Descriptor
(52) Locked Cache Descriptor
(53) Unlocked Cache Descriptor
(54) MH-DL Protection Descriptor
(55) Application Service Descriptor
(56) MPU Node Descriptor
(57) PU Structure Descriptor
(58) MH-Hierarchy Descriptor
(59) Content Copy Control Descriptor
(60) Content Usage Control Descriptor

(61) Emergency News Descriptor
(62) MH-CA Contract Info Descriptor
(63) MH-CA Service Descriptor
(64) MH-External Application Control Descriptor
(MH-External Application Control Descriptor)
(65) MH-Recording/Playback Application Descriptor
(MH-Playback Application Descriptor)
(66) MH-Simple Recording and Playback Application Location Descriptor
(MH-Simple Playback Application Location Descriptor)
(67) MH-Application Expiry Descriptor
(MH-Application Expiration Descriptor)
(68) Related Broadcaster Descriptor
(69) Multimedia Service Descriptor
(70) Descriptors set by carriers

<Relationship between data transmission and each control information in the MMT system>
FIG. 10J shows the relationship between data transmission and representative tables in an MMT broadcasting system.

In an MMT broadcasting system, data can be transmitted via multiple routes, such as a TLV stream via a broadcast transmission path and an IP data flow via a communication line. The TLV stream includes TLV-SI such as TLV-NIT and AMT, and an IP data flow, which is a data flow of IP packets. The IP data flow includes video assets including a series of video MPUs and audio assets including a series of audio MPUs. It may also include subtitle assets including a series of subtitle MPUs, superimposition assets including a series of superimposition MPUs, and data assets including a series of data MPUs. These various assets are associated on a package-by-package basis by the MPT (MMT package table) stored in the PA message and transmitted. Specifically, the package ID and the asset ID of each asset included in the package can be associated and described in the MPT.

The assets constituting the package may be only assets in the TLV stream, but as shown in Fig. 10J, they may also include assets transmitted in the IP data flow of the communication line. This can be achieved by including location information of each asset contained in the package in the MPT, so that the broadcast receiving device 100 can grasp the reference destination of each asset. The location information of each asset may be as follows:
It is possible to specify various data transmitted via various transmission paths, such as (1) data multiplexed into the same IP data flow as the MPT, (2) data multiplexed into an IPv4 data flow, (3) data multiplexed into an IPv6 data flow, (4) data multiplexed into the MPEG2-TS of a broadcast, (5) data multiplexed in MPEG2-TS format within an IP data flow, and (6) data at a specified URL.

MMT broadcasting systems also have the concept of an event. An event is a concept that indicates a so-called program that is handled by the MH-EIT that is included in the M2 section message and sent. Specifically, in a package pointed to by an event package descriptor stored in the MH-EIT, a series of data included in a period of time from the disclosure time stored in the MH-EIT is the data included in the concept of the event. The MH-EIT can be used in the broadcast receiving device 100 for various processes on an event basis (for example, program guide generation process, control of recording and viewing reservations, copyright management process such as temporary storage, etc.).

[Channel setting process for broadcast receiving device]
<Initial scan>
In the current terrestrial digital broadcasting, the network ID is different for each sending master, and the NIT generally does not include information on other stations. Therefore, the broadcast receiving device 100 of the embodiment of the present invention, which has compatibility with the current terrestrial digital broadcasting, needs to have a function of searching (scanning) all receivable channels at the receiving point for the terrestrial digital broadcasting of the embodiment of the present invention (advanced terrestrial digital broadcasting, or terrestrial digital broadcasting in which advanced terrestrial digital broadcasting and current terrestrial digital broadcasting are simultaneously transmitted in different layers), and creating a service list (receivable frequency table) based on the service ID. In addition, in areas where the same network ID can be received on different physical channels by MFN (Multi Frequency Network), it is sufficient to basically operate to select a channel with a good reception C/N or BER (Bit Error Rate) and store it in the service list.

In addition, in the case of advanced BS digital broadcasting or advanced CS digital broadcasting received by the fourth tuner/demodulator 130B of the broadcast receiver 100 in the embodiment of the present invention, the broadcast receiver 100 only needs to acquire and store the service list stored in the TLV-NIT, and there is no need to create a service list. Therefore, for advanced BS digital broadcasting or advanced CS digital broadcasting received by the fourth tuner/demodulator 130B, initial scanning and rescanning, which will be described later, are not required.

<Rescan>
The broadcast receiving device 100 according to the embodiment of the present invention has a rescanning function in preparation for cases where a new station opens, a new relay station is installed, the receiving point of a television receiver is changed, etc. When changing existing information, the broadcast receiving device 100 can notify the user of this fact.

<Example of operation during initial/rescan>
11A shows an example of an operation sequence of a channel setting process (initial/rescan) of the broadcast receiving device 100 according to an embodiment of the present invention. Note that while the figure shows an example in which MPEG-2 TS is used as the media transport method, the process is basically the same when the MMT method is used.

In the channel setting process, the reception function control unit 1102 first sets the residential area (selects the area where the broadcast receiving device 100 is installed) based on the user's instruction (S101). At this time, instead of the user's instruction, the residential area may be automatically set based on the installation location information of the broadcast receiving device 100 acquired by a predetermined process. As an example of the installation location information acquisition process, information may be acquired from the network to which the LAN communication unit 121 is connected, or information on the installation location may be acquired from an external device to which the digital I/F unit 125 is connected. Next, the initial value of the frequency range to be scanned is set, and an instruction is given to the tuner/demodulator (when the first tuner/demodulator 130C, the second tuner/demodulator 130T, and the third tuner/demodulator 130L are not distinguished, this is described as such. The same applies below) to tune to the set frequency (S102).

The tuner/demodulator performs tuning based on the instruction (S103), and if it is successful in locking onto the set frequency (S103: Yes), it proceeds to processing of S104. If it is not successful in locking (S103: No), it proceeds to processing of S111. In processing of S104, it checks the C/N (S104), and if a C/N of a predetermined level or higher is obtained (S104: Yes), it proceeds to processing of S105 and performs reception confirmation processing. If a C/N of a predetermined level or higher is not obtained (S104: No), it proceeds to processing of S111.

In the reception confirmation process, the reception function control unit 1102 first obtains the BER of the received broadcast wave (S105). Next, the NIT is obtained and compared to confirm whether the NIT is valid data or not (S106). If the NIT obtained in the process of S106 is valid data, the reception function control unit 1102 obtains information such as the transport stream ID and original network ID from the NIT. In addition, it obtains distribution system information related to the physical conditions of the broadcast transmission path corresponding to each transport stream ID/original network ID from the terrestrial distribution system descriptor. It also obtains a list of service IDs from the service list descriptor.

Next, the reception function control unit 1102 checks whether the transport stream ID acquired in the process of S106 has already been acquired by checking the service list stored in the receiving device (S107). If the transport stream ID acquired in the process of S106 has not already been acquired (S107: No), the various information acquired in the process of S106 is associated with the transport stream ID and added to the service list (S108). If the transport stream ID acquired in the process of S106 has already been acquired (S107: Yes), the BER acquired in the process of S105 is compared with the BER when the transport stream ID already listed in the service list was acquired (S109). As a result, if the BER acquired in the process of S105 is better (S109: Yes), the service list is updated with the various information acquired in the process of S106 (S110). If the BER acquired in the process of S105 is not better (S109: No), the various information acquired in the process of S106 is discarded.

In addition, when creating (adding/updating) the service list described above, a remote control key ID may be obtained from the TS information descriptor, and a representative service for each transport stream may be associated with a remote control key. This process enables one-touch channel selection, which will be described later.

When the reception confirmation process is completed, the reception function control unit 1102 checks whether the current frequency setting is the final value of the frequency range to be scanned (S111). If the current frequency setting is not the final value of the frequency range to be scanned (S111: No), the frequency value set in the tuner/demodulator is increased (S112) and the processes of S103 to S110 are repeated. If the current frequency setting is the final value of the frequency range to be scanned (S111: Yes), the process proceeds to S113.

In the process of S113, the service list created (added/updated) in the above process is presented to the user as a result of the channel setting process (S113). Also, if there is duplication of remote control keys, the user may be notified of this and prompted to change the remote control key settings (S114). The service list created/updated in the above process is stored in a non-volatile memory such as the ROM 103 or storage (accumulation) unit 110 of the broadcast receiving device 100.

Figure 11B shows an example of the data structure of an NIT. In the figure, "transportrt_stream_id" corresponds to the transport stream ID mentioned above, and "original_network_id" corresponds to the original network ID. Also, Figure 11C shows an example of the data structure of a terrestrial distribution system descriptor. In the figure, "guard_interval", "transmission_mode", "frequency", etc. correspond to the distribution system information mentioned above. Figure 11D shows an example of the data structure of a service list descriptor. In the figure, "service_id" corresponds to the service ID mentioned above. Figure 11E shows an example of the data structure of a TS information descriptor. In the figure, "remote_control_key_id" corresponds to the remote control key ID mentioned above.

The broadcast receiving device 100 may be controlled to change the frequency range to be scanned as appropriate depending on the broadcast service being received. For example, when the broadcast receiving device 100 is receiving broadcast waves of the current terrestrial digital broadcast service, it is controlled to scan a frequency range of 470 to 770 MHz (corresponding to physical channels 13ch to 62ch). That is, the initial value of the frequency range is set to 470 to 476 MHz (center frequency 473 MHz), the final value of the frequency range is set to 764 to 770 MHz (center frequency 767 MHz), and in the process of S112, the frequency value is increased by +6 MHz.

In addition, when the broadcast receiving device 100 is receiving broadcast waves including an advanced terrestrial digital broadcasting service, it is controlled to scan the frequency range of 470 to 1010 MHz (because there is a possibility that the frequency conversion process shown in FIG. 7D or the frequency conversion amplification process shown in FIG. 8C is being performed). That is, the initial value of the frequency range is set to 470 to 476 MHz (center frequency 473 MHz), the final value of the frequency range is set to 1004 to 1010 MHz (center frequency 1007 MHz), and in the process of S112, it is controlled to increase the frequency value by +6 MHz. Note that even if the broadcast receiving device 100 is receiving an advanced terrestrial digital broadcasting service, if it is determined that the above-mentioned frequency conversion process or frequency conversion amplification process is not being performed, it is sufficient to control to scan only the frequency range of 470 to 770 MHz. The selection control of the frequency range to be scanned can be performed by the broadcast receiving device 100 based on the system identification and frequency conversion process identification of the TMCC information.

In addition, when the broadcasting system according to the embodiment of the present invention has the configuration shown in FIG. 7C, for example, and the broadcast receiving device 100 is receiving an advanced terrestrial digital broadcasting service using a dual-polarized transmission method, one of the tuning/detection unit 131H and the tuning/detection unit 131V may scan the frequency range of 470 to 770 MHz, and the other may scan the frequency range of 770 to 1010 MHz (when the transmission wave is subjected to frequency conversion processing with the polarization detected by the other tuning/detection unit). By controlling in this manner based on the system identification and frequency conversion processing identification of the TMCC information, it is possible to omit scanning in unnecessary frequency ranges, and to reduce the time required for channel setting. Furthermore, in this case, the operation sequence of FIG. 11A may be performed in parallel in both the tuning/detection unit 131H and the tuning/detection unit 131V, and the loop of frequency up S112 in the operation sequence of FIG. 11A may be synchronized. In this case, if the pair of horizontally polarized and vertically polarized signals transmitted on the same physical channel is configured to be received in parallel in the frequency-up loop of the operation sequence of FIG. 11A at the same timing, the control information and the like within the packet stream of the advanced terrestrial digital service transmitted by the pair of horizontally polarized and vertically polarized signals can be decoded and acquired during the loop processing. This is preferable because it allows for efficient scanning and service list creation.

Similarly, if the broadcast receiving device 100 has the configuration shown in FIG. 8B and further has a so-called double tuner configuration (for example, a configuration having multiple third tuner/demodulators 130L) that is further equipped with multiple tuner/demodulators (channel selection/detection units), and is receiving an advanced terrestrial digital broadcasting service using a hierarchical division multiplexing transmission method, one of the dual tuners may be configured to scan the frequency range of 470 to 770 MHz, and the other to scan the frequency range of 770 to 1010 MHz (if frequency conversion and amplification processing has been performed). By controlling in this way, it is possible to reduce the time required for channel setting, as described above.

As explained in Figures 8A, 8B, and 8C, in the configuration shown in Figure 8B, the terrestrial digital broadcasting service transmitted in either the upper or lower hierarchy is the current terrestrial digital broadcasting service. Therefore, for example, the first tuner/demodulator 130C may scan the frequency range in which the current terrestrial digital broadcasting service is transmitted, between the frequency range of 470 to 770 MHz and the frequency range of 770 to 1010 MHz, and the third tuner/demodulator 130L may scan the other frequency range in parallel. In this case, as with the parallel scanning by the double tuners of the third tuner/demodulator 130L described above, it is possible to reduce the time required for channel setting. Whether the current terrestrial digital broadcasting service or the advanced terrestrial digital broadcasting service is being transmitted in the 470-770 MHz frequency range or the 770-1010 MHz frequency range can be identified by receiving signals at two points (one point for each frequency range, for example, 470-476 MHz (center frequency 473 MHz) and 770-776 MHz (center frequency 773 MHz)) using the third tuner/demodulator 130L before starting the initial scan/rescan operation sequence, acquiring the TMCC information transmitted at each frequency, and referencing the parameters (for example, system identification parameters) stored in the TMCC information.

In the case of an advanced terrestrial digital broadcasting service using a dual-polarized transmission method, for example, in the case of a channel having a broadcast program that transmits using both horizontally polarized and vertically polarized signals, such as a 4K broadcast program on the C hierarchical division example (1) shown in FIG. 7A, the same transport ID is detected by scanning both the 470-770 MHz frequency range and the 770-1010 MHz frequency range, and this is recorded in the service list as one channel. In the case of a 2K broadcast program on the B hierarchical division example shown in the same figure, if the same broadcast program is transmitted on the B hierarchical division example of the horizontally polarized signal and the B hierarchical division example of the vertically polarized signal, even if the same transport ID is detected, it is sufficient to store it in the service list as one channel. In other words, if the same broadcast program is transmitted on the same hierarchical division example that transmits with different polarizations, it is recognized as being merged into one channel and not as separate channels. In this way, it is possible to avoid user confusion caused by the existence of the exact same broadcast program on different channels in the channel selection process using the service list.

In contrast, in an advanced terrestrial digital broadcasting service using dual-polarized transmission, if different broadcast programs are transmitted on layer B of the horizontally polarized signal and layer B of the vertically polarized signal (when layer B of the vertically polarized signal is treated as a virtual layer D), they are stored in the service list as different channels. Whether the same broadcast program is transmitted on layer B of the horizontally polarized signal and layer B of the vertically polarized signal can be identified by the broadcast receiving device 100 by referring to the additional layer transmission identification parameter of the TMCC information, etc.

[Channel selection process of broadcast receiving device]
The broadcast receiving device 100 according to the embodiment of the present invention has a program selection function, such as one-touch channel selection using a one-touch key on a remote control, channel up/down channel selection using a channel up/down key on a remote control, and direct channel selection by directly inputting a three-digit number using a numeric keypad on a remote control. Any of the channel selection functions may be performed using information stored in the service list generated by the above-mentioned initial scan/rescan. After channel selection, information on the selected channel (three-digit number used for direct channel selection, branch number, TS name, service name, logo, video resolution information (such as distinction between UHD, HD, and SD), presence or absence of video resolution up/down conversion, number of audio channels, presence or absence of audio downmix, etc.) is displayed by a banner display or the like. In this way, the user can visually obtain information on the channel after selection and can confirm whether the desired channel has been selected. An example of processing in each channel selection method is described below.

<Example of one-touch channel selection processing>
(1) By pressing a one-touch key on the remote control, the service with the "service_id" specified by the "remote_control_key_id" is selected.
(2) Set the last mode and display channel information after channel selection.

<Example of up-down channel selection using channel up-down buttons>
(1) By pressing the channel up/down keys on the remote control, channels are selected in the order of the three-digit numbers used for direct channel selection.
(1-1) When the up key is pressed, the adjacent service with the three-digit number above is selected. However, if the current three-digit number is the maximum value in the service list, the service with the minimum number is selected.
(1-2) When the down key is pressed, the adjacent service with the three-digit number below is selected. However, if the current three-digit number is the minimum number in the service list, the service with the maximum number is selected.
(2) Set the last mode and display channel information after channel selection.

<Example of direct channel selection processing>
(1) When direct channel selection is selected, the device waits for the input of a three-digit number.
(2-1) If the input of the three-digit number is not completed within a predetermined time (approximately five seconds), the normal mode is restored and channel information of the currently selected service is displayed.
(2-2) When the input of the three-digit number is completed, a check is made to see if the channel exists in the service list of the receivable frequency table, and if not, a message such as "This channel does not exist" is displayed.
(3) If the channel exists, a channel selection process is performed, the last mode is set, and the channel information after the channel selection is displayed.

The channel selection operation is performed based on the SI, and if it is determined that a broadcast is out of service, the device may have a function to notify the user by displaying that fact.

<Remote control for broadcast receiver>
FIG. 12A shows an example of the external appearance of a remote control (remote controller) used to input operation instructions to the broadcast receiving device 100 according to an embodiment of the present invention.

The remote control 180R includes a power key 180R1 for turning the power of the broadcast receiving device 100 on/off (standby on/off), cursor keys (up, down, left, right) 180R2 for moving the cursor up, down, left, and right, a decision key 180R3 for deciding the item at the cursor position as the selected item, and a back key 180R4.

The remote control 180R also has a network switching key (advanced digital terrestrial broadcasting, digital terrestrial broadcasting, advanced BS broadcasting, BS, CS) 180R5 for switching the broadcast network received by the broadcast receiving device 100. The remote control 180R also has one-touch keys (1-12) 180R6 used for one-touch channel selection, channel up/down keys 180R7 used for channel up/down channel selection, and a 10 key used to input a three-digit number when selecting a channel directly. In the example shown in the figure, the 10 key also serves as the one-touch key 180R6, and when selecting a channel directly, a three-digit number can be input by operating the one-touch key 180R6 after pressing the direct key 180R8.

The remote control 180R also includes an EPG key 180R9 for displaying a program guide, and a menu key 180RA for displaying a system menu. The program guide and system menu can be operated in detail using the cursor keys 180R2, the enter key 180R3, and the back key 180R4.

The remote control 180R also includes a d key 180RB for use with data broadcasting services, multimedia services, etc., a link key 180RC for displaying broadcasting and communication linkage services and a list of compatible applications, and color keys (blue, red, green, yellow) 180RD. For data broadcasting services, multimedia services, broadcasting and communication linkage services, etc., detailed operations are possible with the cursor keys 180R2, the enter key 180R3, the back key 180R4, and the color keys 180RD.

The remote control 180R also has a video key 180RE for selecting a related video, an audio key 180RF for switching between audio ES and two languages, and a subtitle key 180RG for switching subtitles on/off and switching subtitle languages. The remote control 180R also has a volume key 180RH for increasing/decreasing the volume of the audio output, and a mute key 180RI for switching the audio output on/off.

<Example of network switching using advanced digital terrestrial key>
The remote control 180R of the broadcast receiving device 100 according to the embodiment of the present invention includes an "advanced terrestrial digital key", a "terrestrial digital key", an "advanced BS key", a "BS key" and a "CS key" as the network switching key 180R5. Here, the "advanced terrestrial digital key" and the "terrestrial digital key" may be configured so that, for example, in the case where simulcast of 4K broadcast programs and 2K broadcast programs is carried out in different layers in an advanced terrestrial digital broadcasting service, when the "advanced terrestrial digital key" is pressed, the selection of the 4K broadcast program is prioritized when selecting a channel, and when the "terrestrial digital key" is pressed, the selection of the 2K broadcast program is prioritized when selecting a channel. By controlling in this way, for example, when there are many errors in the transmission wave of a 4K broadcast program in a situation where a 4K broadcast program can be received, it is possible to perform control such as forcibly selecting a 2K broadcast program by pressing the "terrestrial digital key".

<Screen display example when selecting a station>
As described above, the broadcast receiving device 100 of an embodiment of the present invention has a function of displaying information about the selected channel by displaying a banner, etc., when a channel is selected by one-touch channel selection, channel up/down selection, direct channel selection, etc.

FIG. 12B shows an example of a banner display when selecting a channel. Banner display 192A1 is an example of a banner display displayed when a 2K broadcast program is selected, and may display, for example, the program name, the program start time/end time, the network type, the number of the direct channel selection key on the remote control, the service logo, and a three-digit number. Banner display 192A2 is an example of a banner display displayed when a 4K broadcast program is selected, and may display, for example, the same information as in banner display 192A1 described above, as well as a symbolic mark for "advanced" indicating that the program being received is a 4K broadcast program. In addition, when resolution conversion processing, downmix processing, etc., have been performed, a display indicating this may be displayed. In the example of banner display 192A2, as an example, it displays that downconversion processing from UHD resolution to HD resolution and downmix processing from 22.2ch to 5.1ch have been performed.

By displaying these on the broadcast receiving device 100, when the same content is being broadcast simultaneously as broadcast programs of different quality, such as a 2K broadcast program and a 4K broadcast program, through simulcasting or the like, the user can easily understand which broadcast program is being displayed.

According to a system for an advanced digital broadcasting service having some or all of the functions according to the embodiments of the present invention described above, it is possible to provide transmission and reception technologies for an advanced digital broadcasting service with higher functionality that also takes into account compatibility with current digital broadcasting services. In other words, it is possible to provide technology for more optimally transmitting or receiving an advanced digital broadcasting service.

Example 2
A second embodiment of the present invention will be described. The second embodiment of the present invention is configured to enable the injection level to be changed in the digital broadcasting system according to the first embodiment. Differences from the first embodiment will be described below. Other configurations, processes, and operations other than those described below are the same as those of the first embodiment, and therefore will not be described again.

In the first embodiment, the hierarchical division multiplexing transmission method shown in FIG. 8A was described as an example of a transmission method for realizing 4K broadcasting while maintaining the viewing environment of the current terrestrial digital broadcasting service. As described above, the difference (difference in transmission power) between the modulation wave level of the upper layer and the modulation wave level of the lower layer is called the injection level (IL), and is a value specified by the broadcasting station. As described above, the injection level is generally expressed as a logarithmic relative ratio (dB) of the difference in modulation wave level (difference in power). It is known that the reception range of the lower layer modulation wave varies depending on the modulation wave level and injection level of the upper layer modulation wave, and that the reception range of the lower layer modulation wave expands when the injection level is reduced. The relationship between the injection level and the modulation wave level will be described in detail later. Note that a change in the injection level can also be expressed as a change in the transmission power difference between the upper layer modulation wave and the lower layer modulation wave.

Figure 13 shows an example of the reception range of an advanced terrestrial digital broadcasting service using the hierarchical division multiplexing transmission method according to this embodiment. In Figure 13 (1), a transmission wave of the hierarchical division multiplexing method is transmitted from a radio tower 30300, and broadcast receiving devices 30101, 30102, 30103, and 30104 having the same configuration as the broadcast receiving device 100 are installed. Inside the upper hierarchical reception range 30910, it is possible to receive the upper hierarchical modulated wave and display the broadcast program. Similarly, inside the lower hierarchical reception range 30900, it is possible to receive the lower hierarchical modulated wave and display the broadcast program. Since the inside of the lower hierarchical reception range 30900 is included in the upper hierarchical reception range 30910, it is also possible to receive the upper hierarchical modulated wave and display the broadcast program. When a 2K broadcast program is transmitted in the upper hierarchical layer and a 4K broadcast program is transmitted in the lower hierarchical layer, the broadcast receiving device 30101 can receive the lower hierarchical modulated wave and display the 4K broadcast program. Furthermore, broadcast receiving device 30101 can receive upper hierarchical modulated waves and display 2K broadcast programs. However, broadcast receiving devices 30102 and 30103 can only receive upper hierarchical modulated waves and cannot correctly receive lower hierarchical modulated waves. Therefore, they can only display 2K broadcast programs and cannot display 4K broadcast programs. Furthermore, broadcast receiving device 30104 is outside the reception range of both the upper and lower hierarchical layers, and is therefore unable to receive 2K broadcast programs on the upper hierarchical layer and is unable to receive 4K broadcast programs on the lower hierarchical layer.

Figure 13 (2) shows an example of the reception range when the injection level is changed to a lower level. When the injection level is changed to a lower level, the lower hierarchical reception range 30900 expands to the changed lower hierarchical reception range 30901. Therefore, the broadcast receiving device 30102 can now receive 4K broadcast programs transmitted using lower hierarchical modulated waves. Meanwhile, the reception status of the receiving devices 30101, 30103, and 30104 does not change. At this time, in order for the broadcast receiving device 30102 to display the 4K broadcast program, it is necessary to perform a rescan, which is a reception setting process, to acquire new control information related to the reception of the 4K broadcast program and store it in the memory of the receiving device, etc.

Figure 14 shows an example of a modulated wave in the hierarchical division multiplexing transmission method according to this embodiment.

First, FIG. 14 (1) shows an example of a modulated wave transmitted from a radio tower 30300, in which an upper hierarchical modulated wave 30110 and a lower hierarchical modulated wave 30120 are multiplexed, and the injection level at this time is injection level 30112. The upper hierarchical modulated wave required C/N 30111 and the lower hierarchical modulated wave required C/N 30121 are C/Ns at which the broadcast receiving device 100 can receive and display a broadcast program without error, and are values derived from the modulation parameters of each modulated wave, i.e., the carrier modulation mapping method, error correction method, coding rate, and constellation format. In order for the broadcast receiving device 100 to receive and display a broadcast program without error, the injection level 30112 is specified as a value obtained by adding a margin to the upper hierarchical modulated wave required C/N 30111. In addition, the lower layer hierarchical modulated wave C/N 30122 is defined as the difference between the modulated wave level of the lower layer modulated wave 30120 and the noise floor 30000, and has a value greater than the lower layer hierarchical modulated wave required C/N 30121.

Figure 14 (3) shows an example of a modulated wave received by the broadcast receiving device 30101. The position of the broadcast receiving device 30101 is located away from the radio tower 30300. Therefore, the modulated wave transmitted from the radio tower 30300 is attenuated and becomes the upper hierarchical modulated wave 30310 and the lower hierarchical modulated wave 30320. The injection level 30112, the required C/N of the upper hierarchical modulated wave 30111, and the required C/N of the lower hierarchical modulated wave 30121 are the same as those in Figure 14 (1). Due to attenuation, the modulated wave level of the lower hierarchical modulated wave 30320 is lower than the modulated wave level of the lower hierarchical modulated wave 30120 in Figure 14 (1). Similarly, the lower hierarchical modulated wave C/N 30322 is smaller than the lower hierarchical modulated wave C/N 30122 in Figure 14 (2). However, because the injection level 30112 is greater than the upper hierarchical modulated wave required C/N 30111, the broadcast receiving device 30101 can receive and display the 2K broadcast program transmitted by the upper hierarchical modulated wave 30310. Also, because the lower hierarchical modulated wave C/N 30322 is attenuated but still greater than the lower hierarchical modulated wave required C/N 30121, the broadcast receiving device 30101 can receive and display the 4K broadcast program transmitted by the lower hierarchical modulated wave 30320.

Figure 14 (5) shows an example of a modulated wave received by broadcast receiving device 30102. The position of broadcast receiving device 30102 is further away from radio tower 30300 than the position of broadcast receiving device 30101. Therefore, the modulated wave transmitted from radio tower 30300 is attenuated and becomes upper hierarchical modulated wave 30510 and lower hierarchical modulated wave 30520. Injection level 30112, required C/N for upper hierarchical modulated wave 30111, and required C/N for lower hierarchical modulated wave 30121 are the same as in Figure 14 (1). Due to attenuation, the modulated wave level of lower hierarchical modulated wave 30520 is lower than the modulated wave level of lower hierarchical modulated wave 30320 in Figure 14 (3). Similarly, lower hierarchical modulated wave C/N 30522 becomes even smaller than lower hierarchical modulated wave C/N 30322. Here, since the injection level 30112 is greater than the upper hierarchical modulated wave required C/N 30111, the broadcast receiving device 30102 can receive and display the 2K broadcast program transmitted by the upper hierarchical modulated wave 30310. However, as a result of the above-mentioned attenuation of the modulated wave level of the lower hierarchical modulation 30520, the lower hierarchical modulated wave C/N 30522 becomes smaller than the lower hierarchical modulated wave required C/N 30121. Therefore, the broadcast receiving device 30102 cannot receive and display the 4K broadcast program transmitted by the lower hierarchical modulated wave 30520.

Next, FIG. 14 (2) shows an example of modulated waves transmitted from a radio tower 30300 when the injection level is changed on the broadcasting station side. When changing the injection level shown in FIG. 14, the upper hierarchical modulated wave 30210 has the same modulated wave level as the upper hierarchical modulated wave 30110 in FIG. 14 (1) before the injection level is changed, but the modulation parameters of the modulated wave are changed so that the upper hierarchical modulated wave required C/N 30211 is smaller than the upper hierarchical modulated wave required C/N 30111 in FIG. 14 (1) before the injection level is changed. In addition, the lower hierarchical modulated wave C/N 30222 is set larger than the lower hierarchical modulated wave C/N 30122. Furthermore, the injection level 30212 is set smaller than the injection level 30112.

Figure 14 (4) shows an example of a modulated wave received by the broadcast receiving device 30101 when the modulated wave of Figure 14 (2) is transmitted. The position of the broadcast receiving device 30101 is located away from the radio tower 30300. Therefore, the modulated wave transmitted from the radio tower 30300 is attenuated and becomes the upper hierarchical modulated wave 30410 and the lower hierarchical modulated wave 30420. Here, since the injection level 30212 is greater than the upper hierarchical modulated wave required C/N 30211, the broadcast receiving device 30101 can receive and display the 2K broadcast program transmitted by the upper hierarchical modulated wave 30410. Also, since the lower hierarchical modulated wave C/N 30422 is attenuated but still greater than the lower hierarchical modulated wave required C/N 30221, the broadcast receiving device 30101 can receive and display the 4K broadcast program transmitted by the lower hierarchical modulated wave 30420.

Figure 14 (6) shows an example of a modulated wave received by broadcast receiving device 30102 when the modulated wave of Figure 14 (2) is transmitted. The position of broadcast receiving device 30102 is further away from radio tower 30300 than the position of broadcast receiving device 30101. Therefore, the modulated wave transmitted from radio tower 30300 is attenuated and becomes upper hierarchical modulated wave 30610 and lower hierarchical modulated wave 30620. Here, since injection level 30212 is greater than upper hierarchical modulated wave required C/N 30211, broadcast receiving device 30102 can receive and display the 2K broadcast program transmitted by upper hierarchical modulated wave 30610. In addition, lower hierarchical modulated wave C/N 30622 is even smaller than lower hierarchical modulated wave C/N 30422 of Figure 14 (4). However, in the example of FIG. 14(6), unlike FIG. 14(5) before the injection level change, the lower hierarchical modulated wave C/N 30222 of the modulated wave transmitted from the radio tower 30300 is higher than the lower hierarchical modulated wave C/N 30122 before the injection level change. Therefore, the lower hierarchical modulated wave C/N 30622 is maintained higher than the lower hierarchical modulated wave required C/N 30221. In other words, due to the above-mentioned injection level change, the broadcast receiving device 30102 has transitioned from a state in which it was unable to receive and display the 4K broadcast program transmitted by the lower hierarchical modulated wave 30520 to a state in which it is able to receive and display the 4K broadcast program transmitted by the lower hierarchical modulated wave 30620. Therefore, the broadcast receiving device 30102 can newly display the 4K broadcast program by performing a rescan.

As explained above using Figures 13 and 14, by changing the injection level, it is possible to expand the installation range of receiving devices capable of receiving broadcast programs transmitted by lower hierarchical modulated waves. Also, if we focus on receiving devices installed at specific locations, by changing the injection level, it is possible to transition from a state in which broadcast programs transmitted by lower hierarchical modulated waves could not be received or displayed to a state in which broadcast programs transmitted by lower hierarchical modulated waves can be received and displayed.

<Transmission of injection level identification>
Next, a technique for more appropriately transitioning the reception state of a broadcast program in a receiving device due to the change in the injection level will be described. First, transmission of the injection level identification will be described.

First, we will explain the technology for transmitting injection level parameters and other information in an AC signal that transmits additional information related to the transmission control of modulated waves.

Figure 15 shows a specific example of the transmission parameter additional information. In the first embodiment, Figure 6H was used to show an example of transmitting parameters of an error correction method and parameters in a constellation format. Figure 15 of the second embodiment is an example different from Figure 6H of the first embodiment, which is a specific example of the transmission parameter additional information. In the example of Figure 15, parameters such as an injection level can be included.

Next, Fig. 16A and Fig. 16B show examples of bit allocation for injection level state identification. Both Fig. 16A and Fig. 16B identify which of multiple different injection level states the injection level is in. However, the examples of Fig. 16A and Fig. 16B show examples in which each injection level state is defined differently.

First, the example of Figure 16A will be described. If this parameter is "000", hierarchical division multiplexing transmission is not applied. If this parameter is any of "001" to "111", hierarchical division multiplexing transmission is applied, and the injection level state indicates which of the first to seventh states the injection level state is. The injection level itself is expressed in dB. In the example of Figure 16A, the injection level identification bit is set and transmitted depending on which of the ranges shown in the figure the injection level of the target transmission wave falls within. The broadcast receiving device obtains the injection level state identification bit of Figure 16A, and based on this, it can determine in which range the injection level of the target transmission wave falls.

Next, an example of FIG. 16B will be described. If this parameter is "000", hierarchical division multiplex transmission is not applied. If this parameter is any of "001" to "111", hierarchical division multiplex transmission is applied, and the state of the injection level indicates which of the first state to the seventh state is in. Here, unlike the example of FIG. 16A, the injection levels indicated by the first state to the seventh state indicate a predetermined dB level, rather than a range indicated in dB. In this case, the injection level of the transmission wave that can be set by the broadcasting station is limited to these multiple options, but the precision of the injection level value indicated by the identification bit in FIG. 16B is high. The broadcast receiving device obtains the injection level state identification bit, and based on this, it can grasp what value the injection level of the target transmission wave is.

In the examples of FIG. 16A and FIG. 16B, the meaning of the injection level state from the first state to the seventh state does not necessarily mean that the first state transitions one state at a time. For example, when a new digital broadcast service of a 4K broadcast program is started by a lower hierarchical modulation wave, the injection level state does not necessarily have to start from the first state, and may start from the second state, for example. The injection level state may also be changed one state at a time, but may also be changed from the first state to the third state or the fifth state. These may be set according to the policy of the broadcasting station. However, changes that increase the injection level, such as changing from the fifth state to the fourth state, should be avoided. This is because this is a change that narrows the reception range of the 4K broadcast program transmitted by the lower hierarchical modulation wave, and there is a risk of causing a disadvantage to the user. In other words, the injection level state from the first state to the seventh state shown in the examples of FIG. 16A and FIG. 16B can be said to be states that transition irreversibly in the digital broadcasting system.

In the examples of Figures 16A and 16B, the injection level is expressed with a resolution of about seven states, taking bit efficiency into consideration. In contrast, as another modification of the identification bits for the injection level state, the number of identification bits may be increased to directly express the injection level as a value in dB units that indicates the modulated wave level difference. In this case, the broadcasting station can increase the number of options for the injection level of the transmission wave that can be set, and the precision of the injection level value that can be grasped by the broadcast receiving device can be increased.

As yet another variation of the injection level state identification bit, a method may be used to calculate the modulated wave level difference using a predefined formula in which the value of the transmitted bit is used as a variable.

In addition, an identification bit for the injection level state may be included in the TMCC information and transmitted.

By using the injection level state identification bit described above, changes to the injection level can be conveniently communicated from the broadcasting station to the broadcast receiving device.

<Rescan>
The broadcast receiving device 100 according to the second embodiment of the present invention has a new rescanning function to appropriately handle changes in the injection level, as will be described below.

In the following description, the term "injection level" may be read as "injection level state". The reason is as follows. As already explained in the description of the identification bit of the injection level state in FIG. 16, in the broadcast receiving device 100, there are cases where the injection level value can be identified as it is, and cases where the state can be identified with a certain range of values. In the latter case, even if the injection level is changed, if it is within a certain range, the state of the injection level is determined to be "unchanged". Therefore, in the broadcast receiving device 100, when the injection level value can be identified as it is, in the following description, "change of injection level" can be considered as it is. In addition, in the broadcast receiving device 100, when the change in the injection level is identified as a change in "state" unit with a certain range, in the following description, "injection level" is read as "injection level state".

Figure 17 shows an example of the rescanning operation sequence of the broadcast receiving device 100 in the second embodiment of the present invention. Note that while the figure shows an example in which MPEG-2 TS is used as the media transport method, the process is basically the same when the MMT method is used.

First, as a prerequisite process, when creating a service list in the initial scan process, the tuner/demodulator acquires the AC information of this embodiment, and the injection level included in the AC information is stored for each channel in the non-volatile memory of the ROM 103 or in the various information storage area 1019 of the storage unit 110. Note that if the injection level is transmitted using TMCC, the AC information can be read as TMCC information.

The broadcast receiving device 100 acquires AC information in the tuner/demodulator (S30001). Next, the injection level (the injection level stored at the time of the initial scan or the latest rescan) stored in the non-volatile memory of the ROM 103 or the various information storage area 1019 is compared with the injection level included in the acquired AC information to detect whether there has been a change and determine the need for rescanning (S30002). If the injection levels are the same, the injection level has not been changed and the process ends. If a small change in the injection level is detected, this means that the lower hierarchical reception range has expanded. In this case, there is a possibility that the device has transitioned to a state in which it is possible to receive a broadcast program transmitted by a lower hierarchical modulated wave, so it is determined that rescanning is necessary and the process proceeds to S30003.

In the process of S30003, it is confirmed whether a 4K broadcast service list already exists for the received channel. If it exists, it indicates that the broadcast receiving device 100 has been able to receive lower-level modulated waves even before the expansion of the lower-level reception range, and rescanning is not necessary, so the process ends. If the 4K broadcast service list does not exist, the broadcast receiving device 100 may be newly included in the lower-level reception range, so the process proceeds to S30004. The order of the processes of S30002 and S30003 may be reversed. The branch judgment process by the process of S30003 has the effect of omitting a new rescan when a 4K broadcast service list already exists, thereby reducing the frequency of rescans based on a change in the injection level. However, without using the process of S30003, when there is a change in the injection level, it may be configured to perform a rescan every time even if the 4K broadcast service list already exists. In this case, the effect is that the current 4K broadcast reception status can be more accurately reflected in the service list.

Next, in the process of S30004, the process waits until a state where rescanning is possible is reached. Specifically, for the third tuner/demodulation unit 130L, if the user is watching or recording and the tuner/demodulation unit is operating, rescanning is not performed. If the tuner/demodulation unit is not operating, for example, transitioning to a standby state, the process proceeds to S30005. Note that if there are multiple third tuner/demodulation units 130L in the broadcast receiving device 100, even if there is a tuner/demodulation unit that is operating because the user is watching or recording, if the other tuner/demodulation units are not operating and are in a standby state, rescanning can be performed using the tuner/demodulation unit in the standby state. Next, in the process of S30005, a scan of the 4K broadcasting service transmitted by the lower hierarchical modulation wave is performed using the third tuner/demodulation unit 130L. Note that the time to perform the scan may be predefined by the broadcast receiving device 100, or the user may be able to set the scan time.

Next, it is confirmed whether a new 4K broadcast service list has been added (whether a new 4K broadcast service has been added) as a result of the scan (S30006). If a service list has not been added (if a new 4K broadcast service has not been added), the broadcast receiving device 100 is not included in the new reception range even after the lower hierarchical reception range is expanded by changing the injection level. Therefore, the process ends. If a service list has been added, the service list added as a result of rescanning is presented to the user (S30007). If a service list is added by performing a scan during standby, when the user turns the device ON, a message that 4K broadcast service reception is now possible is displayed first, and the added service list may also be displayed. Note that if a 4K broadcast service list can be created, 4K broadcast reception is possible, so the process of S30007 is not necessarily required.

According to the example described using FIG. 17, the broadcast receiving device 100 can detect a change in the injection level and use this as a trigger to start a rescan. This makes it possible to start a rescan more appropriately. Note that the "rescan start" in the expression "rescan start trigger" may mean the start of a rescan by the processing of S30005, but may also mean starting to wait until a state in which rescanning is possible in the processing of S30004 is reached. This is the same in all of the explanations of the modified examples of the "rescan start trigger" described below. In addition, in both the example of FIG. 17 and other examples described below, the situation in which a "rescan start trigger" occurs has the same meaning as the broadcast receiving device 100 recognizing or identifying that a "rescan" is necessary. Therefore, in both the example of FIG. 17 and other examples described below, in a situation in which a "rescan start trigger" occurs, the broadcast receiving device 100 recognizes or identifies that a "rescan" is necessary.

<Rescan due to detection of change in upper hierarchical modulation parameters>
In the above description of FIG. 17, a change in the injection level is detected in step S30002, and the rescan is started using this as a trigger. In contrast, as another modified example, the trigger for starting the rescan may be detection of a change in the modulation parameters of the upper hierarchical modulated wave, rather than detection of a change in the injection level. This is because when changing the injection level, it is necessary to change the required C/N of the upper hierarchical modulated wave. For example, in the examples of FIG. 14(1) and FIG. 14(2), in order to change the injection level from injection level 30112 to level 30212, the required C/N of the upper hierarchical modulated wave is changed from the required C/N of the upper hierarchical modulated wave 30111 to 30211. When detection of a change in the modulation parameters of the upper hierarchical modulated wave is used as a trigger for starting the rescan, the modulation parameters of the upper hierarchical modulated wave are obtained from the TMCC information and/or AC information during the initial scan or rescan, and stored in the non-volatile memory of the ROM 103 or the various information storage area 1019 of the storage unit 110. Thereafter, the modulation parameters of the upper hierarchical modulated wave newly acquired from the newly received TMCC information and/or AC information are compared with the modulation parameters of the upper hierarchical modulated wave stored in the non-volatile memory of the ROM 103 or the various information storage area 1019 of the storage unit 110 to detect whether there has been a change. If the result of this detection process shows that there has been a change in the modulation parameters of the upper hierarchical modulated wave, rescanning can be started.

As described above, the broadcast receiving device 100 can detect changes in the modulation parameters of the upper hierarchical modulated wave and use this as a trigger to start a rescan. This makes it possible to start a rescan more appropriately.

<Rescan due to detection of increase in modulated wave level>
In the above description of Fig. 17, a change in the injection level is detected in process S30002, and this is used as a trigger to start rescanning. In contrast, as another variation of the "trigger to start rescanning", the need for rescanning may be determined by detecting an increase in the level of modulated waves received by the broadcast receiving device 100. The modulated waves received by the broadcast receiving device 100 increase when the level output of the modulated waves transmitted from the radio tower 30300 is increased. Alternatively, the level may increase even if the transmission environment between the radio tower 30300 and the broadcast receiving device 100 is improved.

Figure 18 shows an example of a modulated wave before and after the modulated wave level is increased. Figure 18 (1) shows the same modulated wave as Figure 14 (1). Figure 18 (2) shows a modulated wave when only the modulated wave level is increased without changing the modulation parameters or injection level. The upper hierarchical modulated wave 30110 has a modulated wave level increased to become the upper hierarchical modulated wave 30710. The lower hierarchical modulated wave 30120 has a modulated wave level increased to become the lower hierarchical modulated wave 30720. The lower hierarchical modulated wave C/N 30122 also increases to become the lower hierarchical modulated wave C/N 30722. On the other hand, the upper hierarchical modulated wave required C/N 30111 and the lower hierarchical modulated wave required C/N 30121 do not change. In principle, the injection level 30112, which is a value indicating the difference in signal levels in a relative ratio (dB), also does not change.

Figure 18 (3) shows the modulated wave received by the broadcast receiving device 30102, which is the same as that in Figure 14 (5). As mentioned above, in the state of Figure 14 (5), the lower hierarchical modulated wave C/N 30522 is smaller than the lower hierarchical modulated wave required C/N 30121, and the broadcast receiving device 30102 cannot receive and display the 4K broadcast program transmitted by the lower hierarchical modulated wave 30520.

Figure 18 (4) shows the modulated wave received by the broadcast receiving device 30102 when transmitting the modulated wave of Figure 18 (2) with an increased modulated wave level. The upper hierarchical modulated wave 30810 and the lower hierarchical modulated wave 30820 have higher modulated wave levels than the upper hierarchical modulated wave 30510 and the lower hierarchical modulated wave 30520 of Figure 18 (3), respectively. In addition, the injection level 30112 does not change in principle, but the lower hierarchical modulated wave C/N 30822 increases more than the lower hierarchical modulated wave C/N 30522 of Figure 18 (3). In the example of Figure 18 (4), the lower hierarchical modulated wave C/N 30822 is greater than the lower hierarchical modulated wave required C/N 30121. That is, the example in FIG. 18(4) shows that the broadcast receiving device 30102 has transitioned from a state in which it was unable to receive and display a 4K broadcast program transmitted by the lower hierarchical modulated wave 30520 to a state in which it is able to receive and display a 4K broadcast program transmitted by the lower hierarchical modulated wave 30820. In this state, the broadcast receiving device 30102 can newly display the 4K broadcast program by performing a rescan. Therefore, it is sufficient to detect this state transition and use it as a trigger to start a rescan.

Specifically, instead of detecting a change in the injection level in process S30002 of FIG. 17, it is sufficient to detect that the lower hierarchical modulated wave C/N 30822 has become larger than the lower hierarchical modulated wave required C/N 30121, and use this as a trigger to start a rescan. To perform this detection, the broadcast receiving device 100 needs to know both the lower hierarchical modulated wave C/N 30822 and the lower hierarchical modulated wave required C/N 30121.

First, since the lower hierarchical modulated wave C/N 30822 cannot be detected directly, the lower hierarchical modulated wave C/N 30822 is calculated using other detectable values. An example of a method for calculating the lower hierarchical modulated wave C/N 30822 is described below. First, the upper hierarchical modulated wave C/N 30832 is detected in the third tuner/demodulator 130L. The upper hierarchical modulated wave C/N 30832 is the difference between the modulated wave level of the upper hierarchical modulated wave 30810 and the noise floor 30000, and is therefore equal to the sum of the injection level 30112 and the lower hierarchical modulated wave C/N 30822. Therefore, the lower hierarchical modulated wave C/N 30822 can be calculated by subtracting the injection level 30112 from the detected upper hierarchical modulated wave C/N 30832.

Next, the required C/N 30121 for the lower hierarchical modulation wave cannot be obtained directly. Therefore, for example, the required C/N 30121 for the lower hierarchical modulation wave required for transmitting a 4K broadcast program can be estimated in advance and stored in the non-volatile memory of the ROM 103 in the broadcast receiving device 100 or in the various information storage area 1019.

As another example of acquiring the required C/N 30121 for the lower hierarchical modulated wave, the value of the required C/N 30121 for the lower hierarchical modulated wave may be transmitted using the TMCC signal, AC signal, or free space in the packet stream of the higher hierarchical modulated wave, and the broadcast receiving device 100 may acquire it. In this case, the required C/N 30121 for the lower hierarchical modulated wave may not be transmitted directly, but the modulation parameters of the lower hierarchical modulated wave may be transmitted, and the required C/N 30121 for the lower hierarchical modulated wave may be derived based on the modulation parameters acquired by the broadcast receiving device 100. In this case, the broadcast receiving device 100 may derive the required C/N 30121 for the lower hierarchical modulated wave using a calculation formula or lookup table provided in advance and the acquired modulation parameters.

Then, the required C/N 30121 of the lower hierarchical modulated wave obtained in this manner or stored in advance in the non-volatile memory of ROM 103 or the various information storage area 1019 is compared with the lower hierarchical modulated wave C/N 30822 calculated in the above-mentioned calculation process, and it is detected that the lower hierarchical modulated wave C/N 30822 has become larger than the required C/N 30121 of the lower hierarchical modulated wave.

According to the example described using FIG. 18, an increase in the modulated wave level received by the broadcast receiving device 100 can be detected and used as a trigger to start a rescan. This makes it possible to start a rescan more appropriately.

<Rescan due to detection of 4K broadcast>
As another modification of the judgment method in the process S30002 of FIG. 17, regardless of whether the injection level is changed or not, when the 4K service list does not exist, the third tuner/demodulator 130L may intermittently repeat the reception process of the lower hierarchical modulated wave, and judge the necessity of rescanning based on whether the lower hierarchical modulated wave can be received. If reception of the lower hierarchical modulated wave is confirmed, it is judged that the broadcast receiving device 100 has newly been included in the receivable range, and the process proceeds to process S30004, and it is sufficient to wait until it is in a state where rescanning is possible. The reception process of the lower hierarchical modulated wave that is intermittently repeated may be performed periodically, such as every other day, or may be performed under non-periodic conditions.

<Rescan based on modification date or time information>
As another modification of the determination method in process S30002 of FIG. 17, the broadcast receiving device 100 may acquire the injection level change date (or the injection level change time including the injection level change date) and perform a rescan when the injection level change date (or the injection level change time) is reached. This is also another modification of the "trigger for starting a rescan". First, the injection level change date is stored in the TMCC information and/or AC information and transmitted. For example, the injection level change date information (or the injection level change time information including the injection level change date information) may be transmitted using the undefined area of the transmission parameter additional information shown in FIG. 15. The transmitted information is acquired by the third tuner/demodulation unit 130L of the broadcast receiving device 100. The broadcast receiving device 100 may determine that a rescan is necessary when the current date (or the current time) managed by the current time information or the like reaches the injection level change date (or the injection level change time). If it is determined by this process that rescanning is necessary, then process S30004 may be started.

As described above, by comparing the injection level change date acquired by the broadcast receiving device 100 with the current date, it is possible to use the fact that the current date has reached the injection level change date as a trigger for starting a rescan. Alternatively, by comparing the injection level change time acquired by the broadcast receiving device 100 with the current time, it is possible to use the fact that the current time has reached the injection level change time as a trigger for starting a rescan. This makes it possible to start a rescan more appropriately.

The broadcast receiving device 100 can obtain the current date and time from MH-TOT or the like transmitted via broadcast waves.

In this way, the injection level change date or injection level change time can be used as a trigger for starting a rescan. This allows the broadcast receiving device 100 to know the injection level change date or injection level change time in advance, making it possible to start a rescan more appropriately.

<Displaying a question to the user asking whether to start rescanning>
As a modified example of the process S30004 in Fig. 17, it is also possible to change to a process that immediately notifies the user of the need for rescanning, without waiting for the rescanning possible state. Specifically, instead of entering a standby state in the process S30004, a display is displayed explaining the possibility of receiving 4K broadcast programs and the need for rescanning. This may be configured to allow the user to select whether or not to start rescanning. If the user selects to start rescanning, the rescanning process is immediately started, and if the user does not select to start, the process returns to the rescanning possible state standby process S30004.

In this way, the user's selection in response to the inquiry presented to the user about whether or not to start a rescan can be used as a trigger to start a rescan. This makes it possible to start a rescan more conveniently, reflecting the user's convenience.

Example 3
<Frequency interleaving in broadcast station systems>
A third embodiment of the present invention will be described. The third embodiment of the present invention is configured to enable the operational settings of frequency interleaving and deinterleaving to be changed in the digital broadcasting system according to the first embodiment. Differences from the first embodiment will be described below. Other configurations, processes, and operations other than those described below are the same as those of the first embodiment, and therefore will not be described again.

The configuration of the frequency interleaving included in the transmission line coding unit 416 in FIG. 4D is shown in FIG. 19A. In segment division, data segment numbers 0 to 12 are assigned in the order of the partial receiving unit, the modulation unit of segment type 1, and the modulation unit of segment type 2. Note that the modulation unit of segment type 1 was a differential modulation unit dedicated to differential modulation (segment with carrier modulation specified as DQPSK) in the conventional frequency interleaving configuration, but in this embodiment, it has been expanded to be compatible with differential modulation and synchronous modulation. Note that the modulation unit of segment type 2 is a synchronous modulation unit dedicated to synchronous modulation (segment with carrier modulation specified as QPSK, 16QAM, and 64QAM, or 256QAM, 1024QAM, and 4096QAM). The partial modulation unit performs intra-segment carrier rotation and intra-segment carrier randomization, i.e., intra-segment interleaving. The modulation unit of segment type 1 and the modulation unit of segment type 2 perform inter-segment interleaving and intra-segment interleaving, respectively.

The relationship between the hierarchical structure and data segments is that the data segments of each layer are arranged consecutively in numerical order, with the layers containing the smallest data segment numbers being layer A, layer B, and layer C. In addition, in a conventional frequency interleaving configuration, even if the layers are different, inter-segment interleaving is performed on data segments belonging to the same type of modulation section. Typically, layers B and C transmit broadcast programs with a resolution of 2K or higher, so synchronous modulation with a large transmission capacity is used. Therefore, in a conventional frequency interleaving configuration, in this case, both layers B and C are processed by the synchronous modulation section, so interleaving is performed between segments with layers B and C mixed together.

Figure 20 (1) shows an example of hierarchical transmission. Let us assume that hierarchical layer A is data for partial reception, hierarchical layer B is synchronous modulation data using 5 segments, and hierarchical layer C is synchronous modulation data using 7 segments. In this case, hierarchical layer A is subjected to only intra-segment interleaving in one segment with segment number 0, and hierarchical layers B and C are subjected to inter-segment and intra-segment interleaving in 12 segments with segment numbers 1 to 12, generating a signal with a transmission spectrum. This transmission spectrum corresponds to the horizontal polarization of the example of 13-segment allocation in the dual-polarized transmission method shown in Figure 7A (2). On the other hand, an image of hierarchical transmission for the vertical polarization shown in Figure 7A (2) is shown in Figure 20 (3). In the example shown in Figure 7A (2), the vertical polarization is composed only of hierarchical layer B using 5 segments, and the signal has a transmission spectrum in which the carrier of hierarchical layer B is interleaved in 12 segments with segment numbers 1 to 12.

From the transmission spectra shown in Figures 20 (1) and 20 (3), it can be seen that the vertically polarized layer B uses the same segment and the same frequency as the horizontally polarized layers B and C. For this reason, when conventional frequency interleaving is applied, there is a problem that interference occurs between the horizontally polarized and vertically polarized waves. In particular, current terrestrial digital broadcast receivers only receive the C layer of 2K broadcasts transmitted with horizontal polarization, but do not anticipate interference from vertical polarization, which degrades the reception performance of the C layer.

Therefore, in an embodiment of the present invention, even if layers B and C are synchronously modulated, inter-segment interleaving between layers B and C is not performed, and interleaving is performed only within the layers. That is, in the frequency interleaving shown in FIG. 19A, when layers B and C are both synchronously modulated, layer B performs synchronous modulation using a modulation section of segment format 1, and layer C performs synchronous modulation using a modulation section of segment format 2 that is different from the modulation section of segment format 1. Inter-segment interleaving is performed independently by the modulation section of segment format 1 and the modulation section of the modulation section of segment format 2. In this way, inter-segment interleaving that mixes layers B and C is not performed.

Figure 20 (2) shows an image of hierarchical transmission when the same data as in Figure 20 (1) is processed with the B hierarchical layer being modulated (synchronous modulation) in the modulation section of segment format 1 and the C hierarchical layer being modulated (synchronous modulation) in the modulation section of segment format 2. The modulation section of segment format 1 and the modulation section of segment format 2 are each subjected to inter-segment interleaving independently, so a transmission spectrum is generated in which the B hierarchical layer is assigned to segment numbers 1 to 5 and the C hierarchical layer is assigned to segment numbers 6 to 12. This transmission spectrum corresponds to the horizontal polarization of the example of 13-segment assignment in the dual-polarized transmission method shown in Figure 7A (2). On the other hand, Figure 20 (4) shows an image of hierarchical transmission when the same processing is performed on the vertical polarization shown in Figure 7A (2). The vertical polarization becomes a signal with a transmission spectrum in which the B hierarchical layer is assigned to the five segments of segment numbers 1 to 5.

In this way, in the frequency interleaving of this embodiment, different frequency interleaving processing units are used for layers B and C, so layers B and C are transmitted using completely different frequency bands. Therefore, layer C, which is transmitted with horizontal polarization, is not subject to interference from vertical polarization, and there is no degradation in the reception performance of layer C of current terrestrial digital broadcasting receivers that only receive layer C of 2K broadcasts transmitted with horizontal polarization.

In this embodiment of the present invention, to achieve the above operation, in the transmission path coding unit 416 shown in FIG. 4D, the frequency interleaving unit processes layer B as modulation (synchronous modulation) in the modulation unit of segment format 1, and layer C as modulation (synchronous modulation) in the modulation unit of segment format 2. In addition, in the mapping unit, layers B and C are each processed as synchronous modulation. Furthermore, to achieve this processing, in this embodiment, the definition of the segment format identification value of bit allocation B17-B19 included in the TMCC information shown in FIG. 5A is expanded as shown in FIG. 5L. Different values are then assigned to layers B and C.

In the definition of the segment format identification value of B17-B19 in FIG. 5L, "111" means segment format 1, which means synchronous modulation in broadcasting including advanced terrestrial digital broadcasting services (4K broadcasting) using a dual-polarized transmission method, and means differential modulation in other broadcasting such as current 2K broadcasting. "000" means segment format 2, which means synchronous modulation in broadcasting including advanced terrestrial digital broadcasting services (4K broadcasting) using a dual-polarized transmission method, and means synchronous modulation in other broadcasting such as current 2K broadcasting. By configuring in this way, when transmitting using both horizontal polarization and vertical polarization in layer B using a dual-polarized transmission method as in FIG. 7A(2), "111" indicating segment format 1 is set in the segment format identification of bit allocation B17-B19 shown in FIG. 5L.

As a result, if the receiver is compatible with the advanced terrestrial digital broadcasting service (4K broadcasting) using a dual-polarized transmission method, it can determine that the segment format identification "111" means segment format 1 in broadcasting that includes the advanced terrestrial digital broadcasting service (4K broadcasting), and that the modulation method is synchronous modulation. Also, in current receivers dedicated to the terrestrial digital broadcasting service (2K broadcasting) and current receivers dedicated to the terrestrial digital broadcasting service (2K broadcasting), the segment format identification of bit allocation B17-B19 is determined according to Figure 5A, so "111" is determined to be differential modulation. Therefore, this does not affect conventional equipment or receivers that operate using conventional methods.

On the other hand, the C layer, which transmits only with horizontal polarization, sets "000" indicating segment type 2. As a result, if the receiver is compatible with the advanced terrestrial digital broadcasting service (4K broadcasting) using a dual-polarized transmission method, the segment type identification "000" means segment type 2 in the broadcasting including the advanced terrestrial digital broadcasting service (4K broadcasting), and it can be determined that the modulation method is synchronous modulation. In addition, in the current dedicated receiver for terrestrial digital broadcasting service (2K broadcasting) and the current dedicated receiver for terrestrial digital broadcasting service (2K broadcasting), the segment type identification of bit allocation B17-B19 is determined according to FIG. 5A, so "000" is determined to be synchronous modulation. In this way, even in the current dedicated receiver for terrestrial digital broadcasting service (2K broadcasting) and the current dedicated receiver for terrestrial digital broadcasting service (2K broadcasting), the segment type identification of bit allocation B17-B19 is determined to be "000" is synchronous modulation. Therefore, this does not affect conventional equipment or receivers that operate with conventional methods.

<Frequency deinterleaving in receiver>
Next, the operation of a broadcast receiving device that receives a transmission signal according to an embodiment of the present invention will be described. Fig. 21A is a block diagram showing a detailed configuration of the demodulation unit 133C and the layered processing/energy despreading/error correction decoding/stream reproduction unit 134C shown in Fig. 2B, which are dedicated receivers for the current terrestrial digital broadcasting service (2K broadcasting), and has a function of receiving the current 2K broadcast program transmitted by horizontal polarization.

In the demodulation unit 133C, the signal input from the tuning/detection unit 131C is subjected to orthogonal demodulation, and OFMD symbol synchronization and FFT sample frequency are reproduced by synchronous reproduction. FFT is performed on the valid period of the OFMD symbol, and a frame synchronization signal is extracted. Depending on the TMCC information extracted by the TMCC decoding unit 132C, differential demodulation or synchronous demodulation is performed in the carrier demodulation unit. Then, depending on the TMCC information, frequency deinterleaving and time deinterleaving are performed, and demapping is performed to extract bit information.

Next, in the hierarchical processing/energy despreading/error correction decoding/stream reproduction unit 134C, when hierarchical transmission is performed, the data is divided into layers, and bit deinterleaving and depuncture processing are performed for each divided layer. After combining the layers, Viterbi decoding is performed, and the data is again divided into layers, and byte deinterleaving and energy despreading are performed for each layer. After the transport stream is reproduced, Reed-Solomon decoding is performed and a packet stream is output.

Figure 19C shows a detailed configuration of the frequency deinterleaving unit 30030 of the demodulation unit 133C. Since frequency deinterleaving performs the inverse process of the frequency interleaving shown in Figure 19A, the segments after carrier demodulation are processed separately in a partial reception unit, a differential modulation unit, and a synchronous modulation unit. The partial modulation unit performs intra-segment carrier derandomization and intra-segment carrier rotation, i.e., intra-segment deinterleaving. The differential modulation unit and synchronous modulation unit perform intra-segment deinterleaving and inter-segment deinterleaving, respectively.

Here, in FIG. 19C, the processing to be performed by the frequency deinterleaving unit 30030 is selected according to the partial reception flag and segment type identification included in the TMCC information. Specifically, if the partial reception flag of the bit allocation B27 shown in FIG. 5B is set to "1", i.e., "partial reception of the central segment of the transmission band", the carrier of segment 0 is processed by the partial modulation unit. In FIG. 19C, the current terrestrial digital broadcasting service (2K broadcasting) dedicated receiver is included in the demodulation unit 133C that receives only the current terrestrial digital broadcasting, so for segments 1 to 12, a judgment is made according to the segment type identification of the bit allocation B17-B19 shown in FIG. 5A. That is, if the segment type identification of the bit allocation B17-B19 is set to "111", it is judged to be differential modulation and the differential modulation unit is processed. If the segment type identification of the bit allocation B17-B19 is set to "000", it is judged to be synchronous modulation and the synchronous modulation unit is processed.

As already explained, in the transmission coding section of the advanced terrestrial digital broadcasting service (4K broadcasting) using the dual-polarized transmission method according to the embodiment of the present invention, in accordance with FIG. 5L, the segment format identification of bit allocation B17-B19 in layer B is set to "111", which indicates segment format 1 and synchronous modulation, as TMCC information. Also, in layer C, "000", which indicates segment format 2 and synchronous modulation, is set.

Therefore, even when the demodulation unit 133C demodulates the current terrestrial digital broadcasting service (2K broadcasting) transmitted with horizontal polarization, which is included in the broadcast waves of this embodiment including the advanced terrestrial digital broadcasting service (4K broadcasting) using a dual-polarized transmission method, only the C layer is subjected to frequency deinterleaving as synchronous modulation, so it is possible to output the stream of the 2K broadcast program transmitted on the C layer. In addition, since the B layer and the C layer are transmitted using completely different frequency bands, the C layer transmitted with horizontal polarization is not subjected to interference from the vertical polarization, and deterioration of the reception performance of the C layer can be more effectively prevented.

Note that the B layer of an advanced terrestrial digital broadcasting service (4K broadcasting) using a dual-polarized transmission method is actually synchronously modulated, but the segment type identification is set to "111". The demodulation unit 133C included in the receiver dedicated to the current terrestrial digital broadcasting service (2K broadcasting) judges the segment type identification "111" to be differential modulation according to FIG. 5A, and therefore cannot correctly demodulate the B layer as a carrier. However, since the demodulation unit 133C is a receiving function dedicated to the current terrestrial digital broadcasting service (2K broadcasting), it is not a problem even if the 4K broadcasting cannot be carrier demodulated. In this way, the transmission wave of the advanced terrestrial digital broadcasting that has been subjected to the frequency interleaving according to the embodiment of the present invention can preferably prevent deterioration of the receiving performance of the receiver that receives the current terrestrial digital broadcasting.

A broadcast receiver dedicated to the current terrestrial digital broadcast service (2K broadcast) has the same configuration as that shown in Figures 21A and 19C. When a broadcast receiver dedicated to the current terrestrial digital broadcast service (2K broadcast) demodulates the current terrestrial digital broadcast service (2K broadcast) transmitted with horizontal polarization included in the broadcast waves of this embodiment, including the advanced terrestrial digital broadcast service (4K broadcast) using a dual-polarized transmission method, it becomes the same as the example of demodulation unit 133C described above. That is, since frequency deinterleaving is performed as synchronous modulation only on the C layer, it is possible to output the stream of the 2K broadcast program transmitted on the C layer.

In addition, since the B and C layers are transmitted using completely different frequency bands, the C layer, which is transmitted with horizontal polarization, is not interfered with by the vertical polarization, and the deterioration of the reception performance of the C layer can be more effectively prevented. Here, the B layer of the advanced terrestrial digital broadcasting service (4K broadcasting) using the dual-polarized transmission method is actually synchronously modulated, but the segment type identification is set to "111". In a broadcast receiver dedicated to the current terrestrial digital broadcasting service (2K broadcasting), the segment type identification "111" is determined to be differential modulation according to FIG. 5A, so the B layer cannot be correctly carrier demodulated. However, it is not a problem even if a broadcast receiver dedicated to the current terrestrial digital broadcasting service (2K broadcasting) cannot carrier demodulate the 4K broadcasting. In this way, the transmission wave of the advanced terrestrial digital broadcasting that has been subjected to the frequency interleaving according to the embodiment of the present invention can effectively prevent the deterioration of the reception performance of a broadcast receiver dedicated to the current terrestrial digital broadcasting service (2K broadcasting).

<Reception operation of dual-polarized receiver>
Next, the operation of the dual-polarized terrestrial digital broadcasting receiver according to the embodiment of the present invention will be described. Figure 21B shows a different configuration example of the second tuner/demodulation unit 130T shown in Figure 2C. Unlike Figure 2C, detection signals from both the horizontally polarized channel selection/detection unit 131H and the vertically polarized channel selection/detection unit 131V are input to the demodulation unit 30133V. In addition, the hierarchical processing/energy despreading/error correction decoding/stream reproduction unit 30134V performs processing using the output signal of the demodulation unit 30133V.

Figure 21C is a block diagram showing the detailed configuration of the demodulation unit 30133V and the hierarchical processing / energy despreading / error correction decoding / stream reproduction unit 30134V. The horizontal polarization processing unit 31133H performs orthogonal demodulation on the signal input from the tuning / detection unit 131H, and reproduces OFMD symbol synchronization and FFT sample frequency by synchronous reproduction. FFT is performed on the effective period of the OFMD symbol, and a frame synchronization signal is extracted. Furthermore, synchronous demodulation is performed in the carrier demodulation unit according to the TMCC information extracted by the TMCC decoding unit 132H. Similarly, the vertical polarization processing unit 31133V performs orthogonal demodulation, synchronous reproduction, FFT, and frame extraction on the signal input from the tuning / detection unit 131V, and the carrier demodulation unit performs synchronous demodulation according to the TMCC information extracted by the TMCC decoding unit 132V.

Next, in the MIMO detection unit 30010, 2x2 MIMO detection is performed using the output signals of the horizontal polarization processing unit 31133H and the vertical polarization processing unit 31133V. Next, in the deinterleaving unit 30020, time deinterleaving and frequency deinterleaving are performed according to the TMCC information extracted by the TMCC decoding units 132H and 132V. Note that inter-polarized deinterleaving may also be performed in the deinterleaving unit 30020.

The hierarchical processing/energy despreading/error correction decoding/stream playback unit 30134V performs LLR (Log-Likelihood Ratio) calculation, bit deinterleaving, LDPC decoding, and BCH decoding, and outputs a packet stream of a 4K broadcast program transmitted with horizontal and vertical polarization.

As already explained, in the transmission path coding unit on the broadcasting station side according to the embodiment of the present invention, as TMCC information, according to FIG. 5L, "111" is set as the segment format identification of bit allocation B17-B19 in layer B, and "000", meaning synchronous modulation, is set in layer C. In the configuration of FIG. 21B of the broadcast receiving device according to the embodiment of the present invention, when the segment format identification of layer B is "111", it means segment format 1, and it is determined that segment format 1 means synchronous modulation in broadcasting including advanced terrestrial digital broadcasting service (4K broadcasting) using a dual-polarized transmission method. Therefore, in carrier demodulation in the horizontal polarization processing unit 31133H and the vertical polarization processing unit 31133V, synchronous modulation is performed on layer B.

As another processing example, when carrier demodulation is performed by the horizontal polarization processing unit 31133H and the vertical polarization processing unit 31133V, processing may be performed according to only the carrier modulation mapping method without using the segment format identification of B17-B19 of the TMCC. Specifically, when the carrier modulation mapping method of the TMCC information shown in FIG. 5E indicates synchronous modulation for the B layer, the horizontal polarization processing unit 31133H and the vertical polarization processing unit 31133V may perform synchronous demodulation for the B layer. When the carrier modulation mapping method of the TMCC information shown in FIG. 5E is set to QPSK, 16QAM, 64QAM, 256QAM, 1024QAM, or 4096QAM for the B layer, the horizontal polarization processing unit 31133H and the vertical polarization processing unit 31133V may perform synchronous demodulation for the B layer.

Furthermore, the deinterleave unit 30020 performs inter-segment frequency deinterleaving only within the same hierarchical layer. In other words, by performing inter-segment deinterleaving only within the B hierarchical layer, it is possible to output the 4K broadcast stream of the B hierarchical layer transmitted with horizontal polarization and vertical polarization.

Figure 19B shows an example of a specific configuration of the deinterleave unit 30020. In the configuration of Figure 19B, the segment format identification of B17-B19 of the TMCC information is determined according to Figure 5L. As described above, in the transmission path coding unit on the broadcasting station side in this embodiment, the segment format identification of B17-B19 of the TMCC information is set to "111" for the B layer and "000" for the C layer, and the two values are different. The segment format identification "111" is set for the B layer, and in the configuration of Figure 19B, it is determined to mean segment format 1 according to Figure 5L. Therefore, processing is performed on the path for segment format 1, and inter-segment deinterleaving is performed only within the B layer. As a result, it is possible to obtain the 4K broadcast stream of the B layer transmitted with horizontal polarization and vertical polarization. In addition, "000" is set for layer C, which in the configuration of Figure 19B is determined to mean segment type 2 according to Figure 5L, so the segments in layer C will not be processed on a path for segment type 1, and the segments in layer C will not be included in the inter-segment deinterleaving process in layer B.

In the configuration example of FIG. 19B, the processing path of the partially modulated segment and the processing path of segment format 2 are illustrated, but if the configuration is intended to obtain only the 4K broadcast stream on layer B, the processing path of the partially modulated segment and the processing path of segment format 2 are not particularly necessary. However, if the demodulation results of the partially modulated segment on layer A or the demodulation results of the segment of segment format 2 on layer C are used for some other control, or if the configuration is made as a shared circuit for the demodulation functions of layers A and C, these processing paths may be provided.

With the configuration described above, the dual-polarized terrestrial digital broadcasting receiver according to the embodiment of the present invention can receive broadcasting services transmitted in horizontal and vertical polarization from advanced terrestrial digital broadcasting transmission waves generated so as not to degrade the reception performance of current terrestrial digital broadcasting receivers.

Example 4
<Mixed wiring with BS/CS broadcasting>
FIG. 22 shows an example of the configuration of a broadcasting system for an advanced terrestrial digital broadcasting service using a dual-polarized transmission method according to an embodiment of the present invention. This shows a transmitting system for an advanced terrestrial digital broadcasting service, a transmitting system for an advanced BS/CS digital broadcasting service, and a broadcast receiving system (including an intermediate facility 2200 and a broadcast receiving device 100). The configuration of the advanced terrestrial digital broadcasting system according to this embodiment is a configuration further improved based on the configurations of FIG. 7B and FIG. 7C, and the satellite 30300B, which is a broadcasting station facility, is a transmitting antenna capable of transmitting advanced BS/CS digital broadcasting. In the example of FIG. 22, only the tuning/detecting unit 131H and the tuning/detecting unit 131V of the second tuner/demodulator 130T and the tuning/detecting unit 131B of the fourth tuner/demodulator 130B are excerpted from the broadcast receiving device 100 and are shown, and other operating units are omitted.

The advanced BS/CS digital broadcasting signal sent from satellite 30300B is received by satellite receiving antenna 200B, frequency converted by converter 201B, and input to mixer 30400 via coaxial cable 30202B. On the other hand, the horizontally polarized signal and vertically polarized signal of advanced terrestrial digital broadcasting are received by antenna 200T, frequency converted by converter 201T1, and input to mixer 30400 via coaxial cable 30202T. Mixer 30400 mixes the horizontally polarized signal, vertically polarized signal, and advanced BS/CS digital broadcasting signal, and inputs it to splitter 30401 via coaxial cable 30204. Since all received signals can be distributed using a single coaxial cable 30204, it is advantageous in terms of equipment costs and handling when wiring cables.

The demultiplexing unit 30401 demultiplexes the horizontally polarized signal and the vertically polarized signal from the advanced BS/CS digital broadcast signal, and the horizontally polarized signal and the vertically polarized signal are input to the demultiplexing unit 30203T via the coaxial cable 202T3. The advanced BS/CS digital broadcast signal is input from the connector unit 100B via the coaxial cable 30201B to the channel selection/detection unit 131B. The demultiplexing unit 30203T demultiplexes the horizontally polarized signal and the vertically polarized signal, and the horizontally polarized signal is input from the connector unit 100F1 via the coaxial cable 202T1 to the channel selection/detection unit 131H, and the vertically polarized signal is input from the connector unit 100F2 via the coaxial cable 202T2 to the channel selection/detection unit 131V.

The power supply unit 30135B is connected to the connector unit 100B and supplies operating power to the conversion unit 201B via the coaxial cable 30201B, the branching unit 30401, the coaxial cable 30204, the mixing unit 30400 and the coaxial cable 30202B. Similarly, the power supply unit 30135T is connected to the connector unit 100F2 and supplies operating power to the conversion unit 201T1 via the coaxial cable 202T2, the branching unit 30203T, the coaxial cable 202T3, the branching unit 30401, the coaxial cable 30204, the mixing unit 30400 and the coaxial cable 30202T. The power supply unit 30135T may be connected to the connector 100F1. Also, only the power supply unit 30135T or the power supply unit 30135B may simultaneously supply power to the conversion unit 201T and the conversion unit 201B. In this case, the power supply voltage of the conversion unit 201T and the conversion unit 201B should be the same, and the power supplied by the power supply unit 30135T or the power supply unit 30135B should be greater than the total power consumption of the conversion unit 201T and the conversion unit 201B.

In addition, a communication unit 30136T connected to the connector unit 100F2 may be provided, and the conversion process performed by the conversion unit 201T1 may be switched by communicating with the conversion unit 201T1. For example, in the example shown in FIG. 7D, frequency conversion is performed on a vertically polarized signal, but when a conversion switching signal is transmitted from the communication unit 30136T and the conversion switching signal is received by the conversion unit 201T1, a process is performed to switch to frequency conversion processing on a horizontally polarized signal. This process makes it possible to input a signal of the main polarization to the tuning/detection unit 131H even when the main polarization is vertical polarization. In addition, in preparation for a configuration in which the conversion unit 201T1 is not used, a function for selecting whether or not to supply power from the power supply unit 30135T may be provided in the system menu. Furthermore, even if power supply from power supply unit 30135T is selected, if the tuning frequencies of tuning/detection unit 131H and tuning/detection unit 131V are the same, it may be determined that the configuration does not use conversion unit 201T1, and power supply from power supply unit 30135T may be stopped. When this operation is performed, the menu option for the power supply selection function from power supply unit 30135T may be automatically changed to the power stop side. As described above, the broadcast receiving system according to the embodiment of the present invention can distribute all broadcast signals using a single coaxial cable, which is suitable in terms of equipment costs and handling when wiring the cables.

Although examples of the embodiment of the present invention have been described above using Examples 1 to 4, the configurations for realizing the technology of the present invention are not limited to the above examples, and various modifications are possible. For example, it is possible to replace part of the configuration of one example with the configuration of another example, and it is also possible to add the configuration of another example to the configuration of one example. All of these fall within the scope of the present invention. Furthermore, the numerical values and messages that appear in the text and figures are merely examples, and the effect of the present invention will not be impaired even if different ones are used.

The functions of the present invention described above may be realized in part or in whole by hardware, for example by designing them as integrated circuits. They may also be realized by software, with a microprocessor unit or the like interpreting and executing an operating program that realizes each function. Hardware and software may also be used in combination.

The software that controls the broadcast receiving device 100 may be stored in the ROM 103 and/or storage unit 110 of the broadcast receiving device 100 at the time of product shipment. It may be acquired from other application servers 500 on the Internet 200 via the LAN communication unit 121 after product shipment. The software stored in a memory card, optical disk, etc. may be acquired via the extended interface unit 124, etc. Similarly, the software that controls the mobile information terminal 700 may be stored in the ROM 703 and/or storage unit 710 of the mobile information terminal 700 at the time of product shipment. It may be acquired from other application servers 500 on the Internet 200 via the LAN communication unit 721 or mobile telephone network communication unit 722 after product shipment. The software stored in a memory card, optical disk, etc. may be acquired via the extended interface unit 724, etc.

The control and information lines shown in the diagram are those considered necessary for explanation, and do not necessarily represent all control and information lines on the product. In reality, it is safe to assume that almost all components are interconnected.

100: Broadcast receiving device, 101: Main control unit, 102: System bus, 103: ROM, 104: RAM, 110: Storage (accumulation) unit, 121: LAN communication unit, 124: Expansion interface unit, 125: Digital interface unit, 130C, 130T, 130L, 130B: Tuner/demodulation unit, 140S, 140U: Decoder unit, 180: Operation input unit, 191: Video selection unit, 192: Monitor unit, 193: Video output unit, 19 4: Audio selection unit, 195: Speaker unit, 196: Audio output unit, 180R: Remote controller, 200, 200T, 200L, 200B: Antenna, 300, 300T, 300L: Radio tower, 400C: Cable television station head end, 400: Broadcasting station server, 500: Service provider server, 600: Mobile telephone communication server, 600B: Base station, 700: Portable information terminal, 800: Internet, 800R: Router device.

Claims (1)

A method for generating a transmission wave including a 4K broadcast service, in which a 4K broadcast service and a 2K broadcast service are both transmitted, comprising:
In a transmission wave including the 4K broadcast service , the 4K broadcast service and the 2K broadcast service are stored in different hierarchical layers each composed of a combination of different segments among a plurality of frequency segments obtained by dividing a predetermined frequency band of the transmission wave including the 4K broadcast service into a plurality of frequency segments, and are transmitted;
A setting step of setting 3-bit identification information capable of identifying whether a modulation method is synchronous modulation for each of a first layer in which the 4K broadcast service is stored and a second layer in which the 2K broadcast service is stored in the TMCC information included in the transmission wave including the 4K broadcast service,
In the setting step, in the generation of a transmission wave including the 4K broadcast service, even if the modulation methods of both the first layer in which the 4K broadcast service is stored and the second layer in which the 2K broadcast service is stored are synchronous modulation, the 3-bit identification information to be set in the first layer in which the 4K broadcast service is stored and the 3-bit identification information to be set in the second layer in which the 2K broadcast service is stored are set to different values. In the generation of a transmission wave including the 4K broadcast service, the 3-bit identification information of the first layer in which the 4K broadcast service, whose modulation method is synchronous modulation, is stored is always set to 111, and in the generation of a transmission wave including the 4K broadcast service, the 3-bit identification information of the second layer in which the 2K broadcast service, whose modulation method is synchronous modulation, is stored is always set to 000.
How transmission waves are generated.

Images