JP2013131879A - Television device, portable terminal, and television broadcast receiving method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a television device supporting suffering and a power failure.SOLUTION: A television device 20 comprises connectors 205, 215, and 225 which input normal communication signals such as USB and radio signals of digital broadcast received by antennas of portable terminals 10, 11, and 12 through the same signal line. Tuner units 240, 241, and 242 demodulate the radio signals. A USB interface 250, an HDMI input unit 251, and a video input unit 252 are transmitting and receiving means for transmitting and receiving the normal communication signals. Switches 200, 210, and 220 switch a radio signal to the transmitting and receiving means or the tuner. A synthetic diversity unit 260 performs synthetic diversity for the radio signals demodulated by a plurality of tuner units 240, 241, and 242 by maximum ratio synthesis or antenna synthesis.

Description

  The present invention relates to a television device, a portable terminal, and a television broadcast receiving method, and more particularly, to a television device, a portable terminal, and a television broadcast receiving method that perform transmission and reception of digital broadcast radio signals.

In recent years, mobile terminals such as mobile phones that can receive a one-segment partial reception service (hereinafter referred to as “one-segment”) for mobile phones and mobile terminals in digital terrestrial television broadcasting have been sold.
One-segment broadcasting radio waves have the advantage of reaching farther than other terrestrial digital television broadcasting systems. For this reason, even if a nearby radio transmission tower is damaged in a disaster or the like, one-segment broadcasting can be received from a farther broadcasting tower.

Here, referring to Patent Document 1, a mobile phone having a video circuit therein and a video terminal for connecting to a video terminal of the television receiver for sending a video signal to the television receiver is provided. The phone is listed.
Further, referring to Patent Document 2, a one-seg signal received by the portable terminal is extracted from a portable terminal capable of receiving the one-seg signal, and a video signal in the one-seg signal is displayed on a display screen larger than the screen of the portable terminal. A one-segment television broadcast receiving method is described.
In addition, referring to Patent Document 3, an audio / video output terminal such as a video camera or a digital camera is incorporated in a mobile phone, and an audio / video device such as a TV or a personal computer is connected with a connection cable or the like to directly transmit audio / video. There is described a mobile phone terminal capable of visualizing video / audio and information of a mobile phone using an image / audio video device such as a television without using a processing device or software.
With the techniques of Patent Documents 1 to 3, one-segment broadcasting can be viewed on a large television even in the event of a disaster.

On the other hand, in recent years, large-sized home television receivers that are equipped with batteries and are not portable have been developed.
Such a television receiver can operate with low power consumption for a predetermined time. For this reason, when the power supply is temporarily stopped, for example, it can be operated by a battery even in the event of a disaster or a power failure in a developing country.

JP 2001-384894 A JP 2009-11559 A JP 2011-15378 A

However, in a mobile phone, when watching 1Seg broadcasting, much power is consumed as compared with power consumption during normal calls and standby. For this reason, the mobile phones disclosed in Patent Documents 1 to 3 have a problem that the one-segment broadcasting cannot be viewed for a long time.
Moreover, even a home television receiver equipped with a battery may not be able to view digital broadcasts if the antenna reception environment is impaired.
In other words, in an environment where a booster that amplifies radio waves is installed between the wiring from the outdoor antenna or indoor antenna and the TV, if the power is not supplied to the booster due to insufficient power supply or a power outage in the event of a disaster, viewing becomes impossible. It was.

  This invention is made | formed in view of such a condition, and makes it a subject to eliminate the above-mentioned subject.

The television apparatus of the present invention includes a connector that inputs a communication signal and a radio signal of a digital broadcast received by an antenna of a mobile terminal through the same signal line, a tuner that demodulates the radio signal, and the communication signal. Diversity for performing transmission / reception for transmitting / receiving, a switch for switching the radio signal to the transmission / reception unit and the tuner, and a plurality of radio signals demodulated by the plurality of tuners by maximum ratio combining or antenna combining Means.
The television apparatus of the present invention includes radio wave transmission instruction signal transmitting means for transmitting a radio wave transmission instruction signal to the portable terminal when radio waves cannot be input from an antenna provided in the apparatus, and the switch includes the radio wave from the portable terminal. When a signal is received, the tuner is switched to input the radio signal.
The portable terminal of the present invention includes a connector for transmitting and receiving a communication signal and a switch for switching the received digital broadcast radio signal from the signal line of the connector in the portable terminal that receives the digital broadcast. It is characterized by.
The television broadcast receiving method of the present invention is a television broadcast receiving method by a television device, in which a communication signal and a digital broadcast radio wave signal received by an antenna of a mobile terminal are input through the same signal line by a connector. The radio signal is switched from the communication signal transmitting / receiving means to a digital broadcast tuner by a switch, and a plurality of the radio signals demodulated by the plurality of tuners are diversity-divided by maximum ratio synthesis or antenna synthesis. And

  According to the present invention, a digital broadcast radio signal from an antenna of a mobile terminal is received by a signal line of a normal communication signal, and a television device that can be viewed even when the antenna reception environment is impaired, the mobile terminal, and A television broadcast receiving method can be provided.

It is a block diagram which shows the control structure of the video display system X which concerns on embodiment of this invention. It is a flowchart which shows the process in the television apparatus of the electromagnetic wave reception process which concerns on embodiment of this invention. It is a flowchart which shows the process in the portable terminal of the electromagnetic wave reception process which concerns on embodiment of this invention concerning embodiment of this invention. It is a block diagram which shows the detail of USB connection of the television apparatus and portable terminal which concern on embodiment of this invention. It is a flowchart which shows the USB determination process of the television apparatus which concerns on embodiment of this invention. It is a block diagram which shows the detail of MHL connection of the television apparatus and portable terminal which concern on embodiment of this invention. It is a conceptual diagram which shows the circuit example of the MHL connection of the television apparatus and portable terminal which concern on embodiment of this invention. It is a flowchart which shows the MHL determination process of the television apparatus which concerns on embodiment of this invention. It is a block diagram which shows the detail of the video connection of the television apparatus and portable terminal which concern on embodiment of this invention. It is a flowchart which shows the video determination process of the television apparatus which concerns on embodiment of this invention.

<First Embodiment>
[Configuration of video display system X]
Referring to FIG. 1, a video display system X according to an embodiment of the present invention includes a terminal such as a mobile terminal 10, 11, and 12 and a television device 20 that are connected by cables 30, 31, and 32, respectively. Connected and configured.
The mobile terminals 10, 11, and 12 are mobile phones, smart phones, PDAs (Personal Data Assistants), MIDs (Mobile Internet Terminals), netbooks, notebook PCs, and mobile phones that can receive one-segment broadcasting. TV receivers (televisions), and portable terminals such as video game machines.
The television apparatus 20 receives radio waves of digital broadcasting such as terrestrial digital broadcasting, one-segment broadcasting, and satellite digital broadcasting. The television apparatus 20 is connected to the mobile terminals 10, 11, and 12 using various connectors when radio wave reception from a normal antenna (not shown) connected to an RF (Radio Frequency) unit becomes impossible. Thus, a radio wave signal (RF) can be received. Thereby, terrestrial digital broadcasting and one-segment broadcasting can be received.

  The mobile terminal 10 includes an antenna unit 100 and a USB connector 105. Similarly, the mobile terminal 11 includes an antenna unit 110 and a USB connector 115. Similarly, the mobile terminal 12 includes an antenna unit 120 and a flat connector 125.

The antenna units 100, 110, and 120 are parts including an antenna, a tuner, and a switch (switching means). The antenna units 100, 110, and 120 are antennas having impedance suitable for digital broadcasting, unlike a headphone cord and the like, and may have a booster function for amplifying the band of digital broadcasting. The switches of the antenna units 100, 110, and 120 can be switched so that radio signals from the tuner are output from a connector of a normal communication signal such as a USB. This switching can be performed by a radio wave transmission switching command from the television apparatus 20. Note that this switching can be performed by a manual switch, or can be configured to automatically switch to output of a radio signal when the power is turned off.
The detailed configuration of the antenna units 100, 110, and 120 will be described later.
The antenna units 100, 110, and 120 can be configured to receive not only one-segment broadcasting but also normal “full-segment” terrestrial digital broadcasting. In addition, the antenna units 100, 110, and 120 can also receive satellite broadcasts using an external antenna or the like in the case of satellite carrying.

The USB connector 105, the USB connector 115, and the flat connector 125 are connectors for transmitting and receiving normal communication signals of general standards. That is, the USB connector 105, the USB connector 115, and the flat connector 125 of the present embodiment transmit radio signals from data lines and signal lines in addition to corresponding signals.
The USB connector 115 of the mobile terminal 11 is a general connector such as a connector corresponding to a normal A / B / micro / mini / USB 2.0 / 3.0 standard or a successor standard, a HDMI (High-Definition Multimedia Interface) connector, or the like. Use connector or original connector. The USB connector 115 can also input / output power as with a normal USB terminal.
The flat connector 125 of the mobile terminal 12 is a connector such as a “flat” terminal for connecting to an external display as an AV (Audio Visual) output from a mobile phone or the like. That is, the flat connector 125 can transmit a radio signal to a video (composite) signal line. Furthermore, a power source such as +5 V can be input / output from an input pin such as an audio input.
In addition, the mobile terminals 10, 11, and 12 include a control unit such as a CPU, a storage unit such as a RAM and a flash memory, a display unit such as a liquid crystal and an organic EL, and an input unit such as various buttons and sensors. Hardware resources necessary for mobile terminals are provided.
Further, one or a plurality of portable terminals 10, 11, and 12 can be connected to the television apparatus 20. Moreover, the same kind of portable terminals 10, 11, and 12 can be connected, or portable terminals 10, 11, and 12 having different configurations can be connected.

  The television apparatus 20 includes switches 200, 210, and 220 (switching means), a USB connector 205, an HDMI connector 215, an RCA connector 225, tuner units 240, 241, and 242, a USB interface 250, and an HDMI input unit. 251, a video input unit 252, and a synthesis diversity unit 260 (diversity means). The USB interface 250, the HDMI input unit 251 and the video input unit 252 are normal communication signal transmission / reception means.

The switch 200 is an electronic switch, a relay, or the like that switches the mobile terminal 10 and the television device 20 from a normal USB connection to the USB interface 250 to a radio signal connection to the tuner unit 240.
The switch 210 is an electronic switch, a relay, or the like that switches the mobile terminal 11 and the television apparatus 20 from normal USB-HDMI connection to the HDMI input unit 251 to connection of radio signal to the tuner unit 241.
The switch 220 is an electronic switch, a relay, or the like that switches the portable terminal 12 and the television apparatus 20 from an AV connection using a normal video signal to the video input unit 252 to a radio signal connection to the tuner unit 242.
When radio waves can be received from the mobile terminals 10, 11, and 12 when radio waves cannot be received from an antenna (not shown) provided in the own device, the switches 200, 210, and 220 are respectively connected to the tuner units 240 and 241. , And the radio signal is output.
Conversely, when radio waves can be received from a normal antenna, the switches 200, 210, and 220 switch to the USB interface 250, the HDMI input unit 251, and the video input unit 252, respectively, and function as normal USB, HDMI, and video input terminals. Let

The switching signal transmission unit 202 is a radio wave transmission instruction signal transmission unit that transmits a radio wave transmission switching command (radio wave transmission instruction signal) for instructing broadcast reception to the mobile terminals 10, 11, and 12.
For the radio wave transmission switching command, for example, a signal sequence with a predetermined frequency and a predetermined interval can be used.
When the mobile terminals 10, 11, and 12 are configured to switch to output radio signals with a manual switch or to automatically switch to output of radio signals when the power is turned off, a switching signal is transmitted. A configuration without using the unit 202 is also possible.

The USB connector 205 is a connector for transmitting and receiving signals according to normal USB 2.0, USB 3.0, and its successor standard (hereinafter referred to as “normal USB”).
The HDMI connector 215 is a connector such as HDMI, DVI, or display port, and is various HDMI connectors or the like.
The RCA connector 225 is an RCA connector or the like that can input a composite signal. As the RCA connector 225, various RCA connectors 225 such as audio input and component input can be used in addition to the RCA connector 225 of a video (composite) terminal.

  The tuner units 240, 241, and 242 are parts of a general digital broadcast tuner having the same configuration that receives digital broadcast airwaves. The tuner units 240, 241, and 242 also include an A / D converter and a filter. Here, in the example of terrestrial digital broadcasting in Japan, radio signals of ordinary digital broadcasting of HD (high definition) and SD (standard resolution) and one-seg broadcasting that can be received even when the electric field strength is low are acquired. That is, the tuner units 240, 241, and 242 can simultaneously receive at least normal terrestrial digital broadcasting and one-segment broadcasting.

The USB interface 250 is a transmission / reception means for communicating with various devices using a normal USB.
The HDMI input unit 251 is a connection part that serves both as an HDMI signal input interface and an MHL interface. The HDMI input unit 251 inputs an HDMI digital signal, and a video input unit (not shown), an audio input unit (not shown) of the television apparatus 20, and an MHL interface unit used for transmission / reception with a normal MHL signal. (Not shown).
The video input unit 252 is a part that inputs a composite signal, performs A / D conversion, and transmits the composite signal to a video input unit (not shown).

  The combining diversity unit 260 is a part that performs maximum ratio combining for selecting the strongest radio wave from the radio signals received by the tuner units 240, 241, and 242 and diversity for antenna combining. When the phase of the radio waves from the tuner units 240, 241, and 242 is different, the combining diversity unit 260 can perform error correction and receive. When a plurality of mobile terminals 10, 11, and 12 are connected, the combining diversity unit 260 divides radio signals from the plurality of antennas, and an RF unit (not shown) to which a normal antenna is connected Send to. Thereby, highly sensitive reception can be performed.

In the television apparatus 20 of FIG. 1, signal receiving portions from the mobile terminals 10, 11, and 12 are mainly described. In addition to this, the television device 20 includes a control unit such as a CPU and a control circuit that controls each unit, a RAM that stores programs and data executed by the control unit using hardware resources, Storage unit such as ROM or flash memory, display unit such as liquid crystal display or organic EL display that displays video such as still image or moving image, output unit that outputs video signal via HDMI, sensor or button such as infrared remote controller Can be provided.
Moreover, the television apparatus 20 may incorporate a general battery such as a lithium ion battery, a solar battery, or a hand-driven generator, and has a low power consumption such as an LED backlight liquid crystal display, an organic EL, or an FED. It is a low power consumption television receiving device provided with a display part of a display panel. Thereby, the television apparatus 20 can be viewed even at the time of a disaster or a power failure.

The cables 30, 31, and 32 can be general cables that can be used for other purposes.
The cable 30 is, for example, a USB cable corresponding to a USB connector 105 that is a normal USB terminal and a USB connector 205 for a mobile phone or the like. Here, the cable corresponding to the USB 2.0 standard is a cable corresponding to a high frequency capable of transmitting and receiving data at about 480 Mbps (Mega bit per second) in the case of normal USB connection. For this reason, by using a USB cable for the USB cable 30, radio wave signals for digital broadcasting can be sufficiently transmitted and received. In addition, the cable 30 is a USB cable that can supply power, and +5 V or the like is supplied from the television device 20 to the antenna unit 100 of the mobile terminal 10, so the power of the mobile terminal 10 may be turned off. The cable 30 can be a USB host cable with a shorted ID terminal.
The cable 31 is a USB shared terminal provided in the television device 20, for example, a digital video terminal HDMI connector 215 such as an HDMI terminal, and a USB shared terminal shared by the portable terminal such as the portable terminal 11. This is a general MHL cable for connecting to the USB connector 115. MHL is a standard capable of performing high-speed data transmission of about 4 Gbps, and an MHL cable capable of transmitting HDMI is a low noise cable with STP (Shielded Twisted Pair) specifications. For this reason, the cable 31 is suitable for transmitting a radio signal. The cable 31 is also a cable that can be fed with a terminal arrangement similar to the USB. That is, the power of the mobile terminal 11 may be turned off even when a radio signal is transmitted via the cable 31.
The cable 32 is, for example, a general RCA-flat terminal cable connected to an RCA terminal provided in the television device 20 and a flat terminal for a portable terminal capable of AV output. Here, power can be supplied via the cable 32 by connecting to the RCA terminal for voice input of the connector 225. As described above, even when a radio signal is transmitted through the cable 32 of the flat terminal, the mobile terminal 12 may be turned off.
That is, by using the cables 30, 31, and 33 that can supply power, the power can be supplied from the television device 20 to the mobile terminals 10, 11, and 12 so that the battery of the mobile phone is not consumed. .

[Radio wave reception processing of video display system X]
Next, radio wave reception processing using the television device 20 and the mobile terminals 10, 11, and 12 will be described with reference to FIGS.
In this process, when the television apparatus 20 cannot receive radio waves from a normal antenna, the switching signal transmission unit 202 transmits a radio wave transmission switching command to the mobile terminals 10, 11, and 12.
Then, in the mobile terminals 10, 11, and 12, the digital broadcast radio signal received by the antenna is transmitted to the television apparatus 20.
The switches 200, 210, and 220 of the television device 20 switch to the tuner units 240, 241, and 242 when receiving radio signals from the mobile terminals 10, 11, and 12, and the diversity unit 260 switches the diversity. Do.
The outline of each step of the radio wave reception process according to the embodiment of the present invention will be described below with reference to the flowcharts of FIGS.

<Processing in Television Apparatus 20 for Radio Wave Reception Processing>
(Step S100)
First, the control unit of the television apparatus 20 performs activation processing.
In this process, the control unit initializes each part. In this initialization, when it is detected that the battery is activated, the control unit switches to the low power consumption mode.
In this low power consumption mode, it may be set to receive one-segment broadcasting instead of terrestrial digital broadcasting with high definition and high power consumption of the video engine.

(Step S101)
Next, the control unit of the television apparatus 20 determines whether or not digital broadcasting such as terrestrial digital broadcasting or one-segment broadcasting can be received from the normal antenna. That is, even if the television device 20 is operated by a battery during a power failure, if the power is not supplied to the normal antenna booster, there is a problem with the indoor or outdoor wiring, or there is no antenna, Broadcast cannot be received.
If yes, that is, if digital broadcasting can be received, the control unit advances the process to step S102.
No, that is, if the digital broadcast cannot be received, the control unit advances the process to step S103.

(Step S102)
When digital broadcasting can be received from the normal antenna of the radio signal unit, the control unit of the television apparatus 20 performs normal operation processing.
In this process, the control unit controls each unit, and performs various processes such as receiving a digital broadcast from the normal antenna, decoding it, and displaying it on the display unit. Thereafter, the control unit ends the radio wave reception process according to the embodiment of the present invention.
Thereby, the viewer can receive a normal digital broadcast.

(Step S103)
Here, when the digital broadcast cannot be received from the normal antenna, the control unit of the television apparatus 20 performs USB determination processing.
In this process, the control unit determines whether or not the mobile terminal 10 is connected to the USB connector 205. When the mobile terminal 10 is connected, the control unit switches the switch 200 to the tuner unit 240. In addition, the control unit uses the switching signal transmission unit 202 to transmit a radio wave transmission switching command instructing the antenna unit 100 of the mobile terminal 10 to transmit a radio signal.
Details of the USB determination process and the operation of each unit will be described later.

(Step S104)
Next, the control unit of the television apparatus 20 performs MHL determination processing.
Also in this process, the control unit determines whether or not the portable terminal 11 is connected to the HDMI connector 215, and performs a process of switching the radio signal in the same manner as the USB determination process described above.
Details of the MHL determination processing and the operation of each unit will also be described later.

(Step S105)
Next, the control unit of the television apparatus 20 performs video determination processing.
Also in this process, the control unit determines whether or not the portable terminal 12 is connected to the RCA connector 225, and performs a process of switching radio signals similar to the above-described USB determination process and MHL determination process.
Details of the video determination processing and the operation of each unit will be described later.

(Step S106)
Next, the control unit of the television apparatus 20 determines whether or not there is an antenna connection. That is, the control unit determines whether the combining diversity unit 260 has received a radio signal from any one of the mobile terminals 10, 11, and 12.
If Yes, that is, if the radio signal can be received, the control unit advances the process to step S107.
No, that is, if the radio signal cannot be received, the control unit advances the process to step S108.

(Step S107)
When the radio wave signal can be received, the control unit of the television apparatus 20 performs diversity processing using the synthesis diversity unit 260.
Here, when a plurality of mobile terminals 10, 11, and 12 are connected, the control unit can perform diversity such as maximum ratio combining and antenna combining of a plurality of radio signals in the diversity unit 260. As a result, the digital broadcast can be received even in an environment where the radio wave condition is poor and normal terrestrial digital broadcasting or one-segment broadcasting cannot be received.
Thus, the radio wave reception process ends.

(Step S108)
When none of the radio signals can be received, the control unit of the television apparatus 20 performs a reception disable process.
In this process, the control unit displays a message such as “cannot receive radio waves” on the display unit. On this, the control unit also displays a message that urges connection of the antenna. In addition, a message indicating that reception is possible by connecting a portable terminal such as the portable terminals 10, 11, and 12 and a connection method can be illustrated and presented.
Thus, the radio wave reception process of the video display system X is completed.

<Processing in portable terminals 10, 11, 12 for radio wave reception processing>
During the above-described USB determination processing, MHL determination processing, and video determination processing, the antenna units 100, 110, and 120 of the mobile terminals 10, 11, and 12 that perform radio wave reception processing perform the following processing.

(Step S200)
When the mobile terminal 10 is connected to the television device 20 and receives a radio wave transmission switching command from the USB connector 105, the antenna unit 100 performs USB switch processing.
In this process, the antenna unit 100 performs switching so that a radio signal is transmitted through the USB signal line of the USB connector 105.
Details of the operation of each unit in this processing will be described later.

(Step S201)
When the mobile terminal 11 is connected to the television device 20 and receives a radio wave transmission switching command from the USB connector 115, the antenna unit 110 performs USB switch processing.
In this process, the antenna unit 110 performs switching so that the radio signal is transmitted through the signal line used for MHL data pair transmission by the USB connector 115.
Details of this processing will also be described later.

(Step S202)
When the portable terminal 12 is connected to the television apparatus 20 and receives a radio wave transmission switching command from the flat connector 125, the antenna unit 120 performs a flat radio signal switch process.
In this process, the antenna unit 120 is switched to transmit a radio signal on a signal line used for video output of the flat connector 125.
Details of this processing will also be described later.

  In addition, in the processing in these mobile terminals 10, 11, and 12, if power is supplied from the television device 20, it is not necessary to use the batteries of the mobile terminals 10, 11, and 12. Moreover, the power supply of parts other than the antenna units 100, 110, and 120 related to radio wave reception and transmission can be turned off.

<Details of USB determination processing>
Next, details of the USB determination process (FIG. 2) will be described with reference to FIGS.
First, with reference to FIG. 4, details of transmission / reception of radio signals by USB connection between the television device 20 and the mobile terminal 10 will be described.
The switch 200 of the television device 20 includes a power source 201 for supplying, for example, + 5V power via the USB connector 205, a tuner unit 240 that receives a USB data pair and converts it into a radio signal, and a tuner unit 240 / And a USB switch 203 for switching the USB interface 250.
The antenna unit 100 of the mobile terminal 10 can also include a resistor for impedance matching with an antenna that receives radio waves in a band suitable for digital broadcasting such as terrestrial digital broadcasting and one-segment broadcasting, a booster for radio amplification, and the like. Switching between portable antenna 109, portable one-segment tuner 101 for one-segment broadcasting, USB interface 102 for transmitting / receiving data to / from a normal USB device, transmission of radio signals from portable antenna 109 and USB communication of USB interface 102 And a USB switch 103.
Hereinafter, details of the USB determination process will be described step by step with reference to the flowchart of FIG.

(Step S131)
First, the control unit of the television apparatus 20 determines whether or not the mobile terminal 10 is connected to the USB connector 115. That is, the control unit determines whether the antenna unit 100 can be connected from the USB connector 105 of the mobile terminal 10 via the USB connector 205 and the cable 30.
In Yes, a control part advances a process to Step S132.
In No, a control part advances a process to step S135.

(Step S132)
Next, the control unit of the television apparatus 20 performs USB switch switching processing.
In this step, the USB switch 203 of the television apparatus 20 is connected to the USB interface 250.
For this reason, the control unit transmits a radio wave transmission switching command to the mobile terminal 10 using the USB switch 203.
Note that the control unit may be configured to generate and transmit a radio wave transmission switching command through the USB interface 250.
Further, as described above, the portable terminal 10 can be configured to be in a radio wave transmission state by switching a manual switch, or can be configured to be in a radio wave transmission state automatically when the power is turned off. In these cases, it is not necessary to transmit the radio wave transmission switching command.

Here, the USB switch 103 of the antenna unit 100 of the mobile terminal 10 performs the USB switch process of step S200 of FIG.
Specifically, since power is supplied from the power supply 201 of the television apparatus 20, the USB switch 103 can receive a radio wave transmission switching command. As a result, the USB switch 103 switches the output to the USB data pair line from the USB interface 102 to the radio signal output of the portable antenna 109. That is, the USB switch 103 can output a radio signal in a band related to digital broadcasting from the USB data pair line of the USB connector 105.
Note that the USB switch 103 outputs an error signal when the radio wave condition is not good or the digital broadcast cannot be received due to a failure or the like. Further, in the case of a portable terminal without the USB switch 103, an error signal is output whether it responds to the radio wave transmission switching command.

(Step S133)
Next, the control unit of the television apparatus 20 determines whether or not a radio wave signal is received from the mobile terminal 10 by USB. That is, it is determined whether the radio signal from the mobile terminal 10 has been received by the USB connector 205 or the USB switch 203 within a predetermined waiting time.
In Yes, a control part advances a process to step S134.
In No, a control part advances a process to step S135.

(Step S134)
When the radio signal can be received, the control unit of the television apparatus 20 performs the USB antenna on process.
Specifically, the control unit switches the USB switch 203 of the switch 200 of the television device 20 to the tuner unit 240.
As a result, the tuner unit 240 demodulates a signal necessary for digital broadcasting from the radio wave signal and transmits the demodulated signal to the combining diversity unit 260.
Thus, the USB determination process ends.

(Step S135)
When the radio signal cannot be received, the control unit of the television device 20 performs the USB antenna off process.
In this processing, the control unit performs processing related to normal USB connection while the USB switch 203 of the switch 200 of the television device 20 is connected to the USB interface 250. That is, no processing is performed when nothing is connected to the USB connector 205. If a USB device that does not support normal radio signal transmission is connected to the USB connector 205, processing related to the device is performed.
Thus, the USB determination process ends.

<Details of MHL determination processing>
Next, details of the MHL determination process (FIG. 2) will be described with reference to FIGS.
First, with reference to FIG. 6, details of transmission / reception of radio signals by MHL connection between the television apparatus 20 and the mobile terminal 11 used for the MHL determination process will be described. In FIG. 6, components having the same reference numerals as those in FIG. 4 have the same functions.
In addition, the switch 210 of the television apparatus 20 includes an MHL switch 213 for switching the tuner unit 241 / HDMI input unit 251.
The antenna unit 110 of the mobile terminal 11 switches between MHL interface 112 for transmitting and receiving images and data by normal MHL communication and HDMI, and MHL communication of the MHL interface 112 and transmission of radio signals from the mobile antenna 109. An MHL switch 113 as a switch is provided.

Further, an example of a circuit used for transmission / reception of radio signals by actual MHL will be described with reference to FIG.
When transmitting and receiving radio signals using MHL, it is necessary to use the impedance matching 114 of the antenna unit 110 of the mobile terminal 11 and the impedance matching 214 of the switch 210 of the television device 20 in FIG. The impedance matching 114, 214 is an impedance matching circuit using a coil and a capacitor (LC), a transformer or the like. A signal line having each resistance shown in a cylindrical shape indicates a transmission line under impedance control. As a result, radio wave signals can be suitably transmitted without impairing the standards of each signal line.
When transmitting and receiving each signal, it can be performed by pin assignment as shown in the example of FIG. 7, but is not limited thereto.

Next, the details of the MHL determination process will be described with reference to FIG.
The MHL determination process is the same as the USB determination process, except that, for example, an HDMI-USB cable is used as the cable 31 to be connected, and radio signals from the mobile terminal 11 are transmitted and received.
Step S141 in FIG. 8 performs the same processing as Step S131 in FIG. 5, Step S142 performs Step S132, Step S143 performs Step S133, Step S144 performs Step S134, and Step S145 performs Step S135.

<Details of video judgment processing>
Next, details of the video determination process (FIG. 2) will be described with reference to FIGS.
First, with reference to FIG. 9, details of transmission / reception of radio signals by video signals between the television device 20 and the mobile terminal 12 used for video determination processing will be described. Also in FIG. 9, constituent parts having the same reference numerals as those in FIG. 4 indicate parts having similar functions.
In addition, the switch 220 of the television apparatus 20 includes a video switch 223 that receives a radio signal from the video signal line and switches between the tuner unit 242 and the video input unit 252.
In addition, the antenna unit 120 of the mobile terminal 12 converts the radio signal of the antenna 109 into a video signal by a video amplifier 122 for transmitting a still image or a moving image using a video signal and a radio wave transmission switching command from the television device 20. And an RF switch 123 for outputting to the signal line.
The flat connector 125 may be a flat connector that outputs a video (composite) signal. Further, although not shown in FIG. 9, power can be input from the television apparatus 20 to the flat connector 125 via an audio line or the like and supplied to the RF switch 123.
With this configuration, the video (RCA) line has a simple configuration, and since the cable is also coaxial 75 Ω, it has high affinity for transmission of radio signals.

Next, referring to FIG. 10, in the video determination process, the above-described USB determination process is performed except that an RCA-flat terminal cable is used as the cable 32 to be connected and a radio signal is transmitted and received through the signal line of the video signal. And MHL determination processing.
That is, in the example of the USB determination process of FIG. 5, step S151 of FIG. 10 is step S131 of FIG. 5, step S152 is step S132, step S143 is step S133, step S154 is step S134, step S155. Performs the same processing as step S135.

With the configuration described above, the following effects can be obtained.
In the video display system X according to the embodiment of the present invention, radio signals are transmitted from the portable terminals 10, 11, and 12 to the television apparatus 20 through signal lines of USB, MHL, and video signals.
As a result, the video display system X receives digital broadcast radio signals from the mobile terminals 10, 11, 12 even in the event of a disaster or when the antenna reception environment such as a booster is impaired. Can be displayed. Moreover, since the general cables 30, 31, and 32 are used for transmission of the radio signal, the cost can be reduced.
In addition, the video display system X does not need to display the one-segment broadcast using the broadcast reception and display functions provided in the mobile terminals 10, 11, and 12. That is, in order to transmit a radio wave signal to a signal line of USB, MHL, or video signal, it is used for connection with a control unit other than the antenna units 100, 110, 120, a part related to communication / communication, or a general USB or MHL device There is no need to supply power to such parts. Therefore, the effect of not consuming the battery provided in the mobile terminals 10, 11, 12 can be obtained.
Also in the television device 20, it is only necessary to supply power to only the antenna units 100, 110, and 120 with respect to the mobile terminals 10, 11, and 12 using a USB terminal or the like. For this reason, the battery consumption of the television apparatus 20 can also be suppressed.

Further, in the video display system X, even when the broadcasting tower suffers from damage and normal terrestrial digital broadcasting cannot be received, the mobile terminals 10, 11, and 12 can receive one-seg broadcasting radio waves. Thereby, the possibility that the one-segment broadcasting can be viewed on the television device 20 can be increased.
Further, in the video display system X, even the television device 20 that does not have a one-segment broadcasting dedicated antenna or the like can receive the one-segment broadcasting. Therefore, the television device 20 does not require a dedicated antenna or tuner for receiving one-segment broadcasting, and costs can be reduced.

In addition, when a fixed antenna is mounted on a television receiver, the position of the antenna cannot be freely changed. However, when viewing 1Seg broadcasting on a mobile terminal, a location where radio wave reception is good does not always have a good viewing environment.
On the other hand, in the video display system X, the mobile terminals 10, 11, and 12 can be placed in a place where digital broadcast reception is good, and the television device 20 can be placed in a place where the viewing environment is good. At this time, the digital broadcast is not decoded by the portable terminal as in the techniques of Patent Documents 1 to 3, but the radio signal received by the portable terminals 10, 11, and 12 is decoded and displayed by the television device 20. Therefore, there is no need to worry about battery consumption of the mobile terminals 10, 11, 12.
Moreover, the video display system X can also obtain a diversity effect by connecting a plurality of portable terminals 10, 11, and 12 as antennas.
Furthermore, by decoding the radio signal with the television device 20, it becomes possible to use a decoder having a higher processing capability. Even in the case of one-segment broadcasting, a beautiful image or a high-resolution image can be obtained by time interpolation or high-resolution image interpolation. Audio can be viewed.

In the above-described embodiment, the example in which the mobile terminals 10, 11, 12 receive the digital broadcasting radio wave with the built-in antenna has been described. However, the mobile terminals 10, 11, and 12 may include an external antenna.
In addition, the antenna unit 100 of the mobile terminals 10, 11, and 12 has been described so as to switch the antenna by an electronic switch, a relay, or the like, but the antenna output is simply connected to the connectors 105, 115, It is also possible to output to 125. As a result, the portable terminals 10, 11, and 12 can be used as external antennas specialized for mere digital broadcasting, and it is not necessary to supply power at all.
Further, the mobile terminals 10, 11, and 12 may transmit radio wave signals to the television apparatus 20 using a cable other than USB, MHL, and video and a data transmission method.

In the portable terminal, the radio wave signal can be once A / D converted and encoded / modulated using a USB, MHL, or video signal for transmission. And it can also comprise so that it may decode / demodulate with switch 200,210,220 of the television apparatus 20, or tuner 240,241,242. In this case, noise can be avoided by transmitting a radio signal directly from the portable terminal using a USB, MHL, or video signal.
In addition, the mobile terminals 10, 11, and 12 can receive a broadcast using a wireless communication line and convert the received data into a data pair in the form of a digital broadcast radio signal.
Further, since the power supply line is DC, it is possible to superimpose the radio signal band on the USB or MHL power supply line.

  In addition to the television device 20, the present invention includes a digital tuner capable of receiving digital broadcasting, an HDD / BD recorder, a set-top box, a display device, a television, a projector, a mobile phone, a smartphone, a PDA (personal data). -Assistant), MID (mobile Internet terminal), netbook, notebook PC, one-segment TV, video game machine, etc.

  Note that the configuration and operation of the above-described embodiment are examples, and it is needless to say that the configuration and operation can be appropriately changed and executed without departing from the gist of the present invention.

10, 11, 12 Portable terminal 20 Television apparatus 30, 31, 32 Cable 100, 110, 120 Antenna unit 101 Portable one-segment tuner 102 USB interface 103, 203 USB switch 105, 115, 205 USB connector 109 Portable antenna 112 MHL interface 113 213 MHL switch 114, 214 Impedance matching 122 Video amplifier 123 RF switch 125 Flat connector 200, 210, 220 Switch 201 Power supply 202 Switching signal transmission unit 215 HDMI connector 223 Video switch 225 RCA connector 240, 241, 242 Tuner unit 250 USB Interface 251 HDMI input unit 252 Video input unit 260 Composite diversity unit X Video display system Temu

Claims (4)

A connector for inputting a communication signal and a radio signal of a digital broadcast received by an antenna of a mobile terminal through the same signal line;
A tuner for demodulating the radio signal;
Transmitting and receiving means for transmitting and receiving the communication signal;
A switch for switching the radio signal to the transmission / reception means and the tuner;
Diversity means for diversifying the plurality of radio signals demodulated by the plurality of tuners by maximum ratio combining or antenna combining. A radio wave transmission instruction signal transmitting means for transmitting a radio wave transmission instruction signal to the mobile terminal when radio waves cannot be input from an antenna provided in the own device;
The television apparatus according to claim 1, wherein the switch is configured to switch the tuner to input the radio signal when the radio signal is received from the mobile terminal. In mobile terminals that receive digital broadcasts,
A connector for transmitting and receiving communication signals;
A portable terminal comprising: a switch for switching the received digital broadcast radio signal to be output from a signal line of the connector. In a television broadcast receiving method by a television device,
With the connector, the communication signal and the radio signal of the digital broadcast received by the antenna of the mobile terminal are input through the same signal line.
With the switch, the radio signal is switched from the transmission / reception means for the communication signal to a tuner for digital broadcasting,
Diversifying the plurality of radio signals demodulated by the plurality of tuners by maximum ratio combining or antenna combining.

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