JP2009105742A - Receiving apparatus, receiving system, method of supplying power to antenna, and method of selling receiving system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a receiving apparatus capable of widening the latitude of antenna selection by making it possible to easily supply power corresponding to an external antenna in accordance with the request of a user. <P>SOLUTION: A set top box 1 includes a tuner block 4 which inputs a broadcast signal from an external antenna 2 and processes the broadcast signal; an incorporated power source 5 which supplies a DC power source to the antenna 2 connected outside; and a DC jack 3 to which a DC external power source is connected. When an external power source is input, the DC jack 3 switches incorporated power supply to an external power source 101. When the incorporated power supply runs short for power source capacitance of the antenna 2, an AC adapter 101 is connected via a DC plug 103. When the AC adapter 101 is connected, the DC jack 3 switches the internal connection from the incorporated power source 5 to the AC adapter 101 of the external power source. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a receiving apparatus that receives a broadcast signal from an antenna and a method of supplying power to the antenna.

  Conventionally, receivers that receive broadcast signals such as set top boxes, tuners, televisions, DVD players, etc., and output video signals have customarily supplied power to the antenna and built in the receiver. It was supplied from a power source.

  In recent years, from the viewpoints of environmental protection and power saving, a standard is set for the amount of power consumption to be equal to or less than a predetermined standard, and a logo conforming to the standard can be affixed to a product that conforms to the standard. Examples of this standard include Energy Star.

On the other hand, Patent Document 1 discloses a microwave / millimeter wave transmission apparatus that retransmits a broadcast signal received by an external antenna indoors. According to this, the freedom degree of installation of the television indoors can be raised. In this document, in order to supply power to an external parabolic antenna via an AC adapter, an IF signal (intermediate frequency intermediate frequency) of the parabolic antenna and a microwave / millimeter wave in which the power supply to the parabolic antenna is superimposed. A transmitting device is disclosed. By thus superimposing the IF signal on the power supply, the power cable and the broadcast signal cable can be made common.
JP 2004-072187 A

  However, conventionally, when a user purchases an antenna, it is necessary to check the capacity of the built-in power supply on the receiving device side. As a result of checking the capacity, if the capacity of the built-in power supply is insufficient, the user has to give up purchasing an antenna that consumes a lot of power even if the reception sensitivity is good.

  In addition, these receiving apparatuses are not necessarily connected to, for example, their own antennas recommended by the receiving apparatus, and may be connected to antennas other than those recommended by the user. In particular, in an area where the reception condition of the antenna is not good, it is desirable to install a stronger antenna in order to receive a clearer image.

  Considering the case where such an antenna of another company is connected, if the manufacturer of the receiving device designs a large built-in power supply, there is a possibility that it falls outside the standard. In particular, there are severe restrictions when exporting or using a receiving device in California, USA.

  Also, if the antenna power supply is simply an external power supply, the built-in power supply is certainly within the standard. However, a device without an external power source, that is, a receiving device that does not supply power to the antenna, is practically not established as a device. Eventually, an external power source was required, and a device without an external power source could be out of standards.

  As described above, it is desired that antennas with higher degrees of freedom can be selected while conforming to the above-mentioned standard with standard equipment.

  Therefore, an object of the present invention is to provide a receiving apparatus that can expand the degree of freedom of antenna selection by allowing power according to an external antenna to be easily supplied according to a user's desire. .

  In order to solve the above problems, the following configuration can be provided.

(1) In a receiving apparatus having a main block for inputting a broadcast signal from an external antenna and processing the broadcast signal,
An antenna connected to the outside and a built-in power supply for supplying DC power to the main block;
A power input unit for connecting a DC external power source, and when the external power source is input, a power source input unit that switches power supply to the antenna by the built-in power source to the external power source.

  According to this configuration, an internal power source can be used to supply power to the antenna, but an external power source can be selectively used via the power input unit. Therefore, since a necessary power source can be selected in accordance with the antenna purchased by the user, the degree of freedom in antenna selection can be expanded. On the other hand, conventionally, since the antenna is selected in accordance with the power source inside the receiving apparatus, the selection of the antenna is largely limited.

(2) The power input unit is connected to a cable that transmits a broadcast signal of the antenna, and a DC voltage and the broadcast signal are superimposed on the cable,
A separation unit is provided between the cable and the main block to cut off a DC voltage and transmit the broadcast signal to the main block.

  In this configuration, a DC voltage and the broadcast signal are superimposed on the cable, and a DC signal of the power source is cut off and a broadcast signal of the antenna is transmitted to the main block. Therefore, it is not necessary to provide both a power cable and a signal cable.

  (3) The separation unit may be a capacitor.

  (4) The built-in power supply preferably conforms to a predetermined standard regarding power consumption.

  In this way, a single receiver using a built-in power supply can selectively connect an external power supply while complying with the standard, and can select the external power supply according to the antenna selected by the user. Become.

(5) In a receiving system comprising the receiving device according to claim 4,
A standard antenna that receives power from a built-in power source of the receiving device and receives a broadcast signal;
An external power source connected to the power input unit,
Selectively connecting the standard antenna and the external power source to the receiver,
When using an antenna other than the standard antenna and having an operating power exceeding the capacity of the built-in power supply, the external power supply is used to supply power to the antenna.

  According to this system, since the power is supplied to the standard antenna by the built-in power supply, the reception system is completed without using an external power supply. Therefore, it does not escape from the above standard. In other words, a single receiver using a built-in power supply can comply with the standard. Further, it is possible to selectively connect an external power source and select the external power source according to the antenna selected by the user.

  Note that “selectively” is not limited to selectively connecting a standard antenna and an external power source. Both may be connected. In addition to the standard antenna, it is possible to connect neither the standard antenna nor the external power source as long as power can be supplied from the built-in power source.

(6) A receiving device including a main block for inputting a broadcast signal from an external antenna and processing the broadcast signal, and a built-in power supply for supplying a DC power to the antenna connected to the outside, and a DC external power supply A power input unit for connecting a power supply input unit that switches the supply of built-in power to an external power source when the external power is input;
In the method of supplying power to an antenna using one or more external power supplies connected to the power input unit,
A first step of calculating the power capacity required for the antenna;
A second step of determining whether the power supply capacity is sufficient with a built-in power supply;
In the second step, when the power source capacity is not sufficient by the built-in power source, a third step of selecting an external power source necessary for the antenna and connecting the external power source to the power input unit is executed.

  According to this configuration, when the power supply to the antenna is insufficient with the built-in power supply, the external power supply can be selectively used via the power supply input unit. Therefore, since a necessary power source can be selected in accordance with the antenna purchased by the user, the degree of freedom in antenna selection can be expanded.

(7) In a method for selling a receiving system comprising the receiving device according to claim 4,
Receiving power from the built-in power supply of the receiving device, a standard antenna that receives broadcast signals can be connected, an external power supply can be connected to the power input unit according to a user's request, and the capacity of the built-in power supply When using an antenna with a power consumption exceeding, a first step of posting in an advertisement that the external power source is used to supply power to the antenna;
The receiving device and a second step of selling the standard antenna or the external power source are performed according to a user's request.

  According to this method, the purchaser of the receiving device can connect an external power source to the receiving device, and when using an antenna with a power consumption exceeding the capacity of the built-in power source, the external power source is used for power supply to the antenna. You can understand what to do. Thereby, the manufacturer of the receiving apparatus can comply with a predetermined standard, for example, Energy Star, as long as the standard antenna is used. On the other hand, the purchaser can select an external power source according to the separately purchased antenna and connect it to the receiving device. Therefore, even if the purchaser has already selected the antenna, the purchaser can easily select the external power supply and purchase the power supply suitable for the antenna. In addition, there is little restriction on the built-in power supply, and the antenna can be selected more freely. Note that this method is not merely an agreement, but is made possible on the assumption that the receiving apparatus is configured as described above, and uses the laws of nature.

  ADVANTAGE OF THE INVENTION According to this invention, the receiving apparatus which can supply the electric power according to an external antenna easily according to a user's hope can be provided. As a result, the user is less affected by the built-in power supply and can select the antenna more freely.

  A receiving system 10 according to an embodiment of the present invention will be described with reference to FIG. 1A is a front view, FIG. 1B is a rear view, and FIG. 1C is a circuit diagram.

  The receiving system 10 includes a set top box 1 (hereinafter abbreviated as STB), an antenna 2, and an AC adapter 101 (the AC adapter 101 is omitted in FIG. 1A). ). An antenna 2 is connected to the STB 1.

  As shown in FIG. 1A, a display panel 110, a plurality of operation buttons 111, and a power button 112 are provided in front of the STB 1. When the power button 112 is pressed, the STB 1 is activated and accepts the operation of the operation button 111. The display panel displays the state of STB1.

  As shown in FIG. 1B, the antenna 2 is connected via an F connector 14. A power source that activates the STB 1 is connected to a commercial power source via the power plug 12. The DC jack 3 is a power supply terminal for inputting auxiliary power for the antenna 2 from the outside. An AC adapter 101 as an auxiliary power source is connected to the DC jack 3. The AC adapter 101 includes a DC conversion unit 102, a DC plug 103, and a power plug 106, which are connected by second power cables 104 and 105. A DC plug 103 is inserted into the DC jack 3 of the STB 1.

  Next, the circuit of the STB 1 will be described with reference to FIG. The STB 1 includes a tuner block 4, a built-in power supply 5, a DC jack 3, an F connector 14, a terminal 16, a first diode 16, a capacitor 17, a second diode 18, and a ground G.

  The tuner block 4 processes the broadcast signal input from the antenna 2. For example, RGB colors are extracted from the broadcast signal and output. When the tuner block 4 is a digital tuner block, the transport stream or the digital MPEG format video data and audio data, or the video data and audio data decoded and converted into analog signals and An audio signal may be taken out. In any case, the tuner block 4 may be a block that processes this broadcast signal.

  This block corresponds to the main block of the present invention.

  The built-in power source 5 is a power source that supplies power to the tuner block 4 and the antenna 2 from a commercial power source input from the power plug 12. The built-in power supply 5 is connected to the DC jack 3. When the DC plug 103 is not connected to the DC jack 3, the terminal B and the terminal S are in contact with each other inside the DC jack 3. In this case, the built-in power supply 5 supplies power to the antenna 2 via the terminal 16 and the F connector 14. On the other hand, when the DC plug 103 is connected to the DC jack 3, the contact between the terminal P and the terminal S is released inside the DC jack 3 in response to the insertion of the terminal of the DC plug 103. As a result, the power supply from the built-in power supply 5 is stopped, and the AC adapter 101 is supplied with power from the DC plug 103.

  The first diode 15 is connected with the direction flowing from the DC jack 3 to the terminal 16 as the forward direction. Thereby, the backflow of the current from the first diode 15 to the DC jack 3 is prevented. The terminal 16 is connected to the antenna 2 via the F connector 14. The terminal 16 is connected to the first diode 15, the second diode 17, and the capacitor 18.

  An internal power supply or an external power supply supplies power to the antenna 2. Then, the broadcast signal received by the antenna 2 is transmitted to the terminal 16. As described above, since a direct current is supplied to the cable of the antenna 2 via the F connector 14, the broadcast signal and the direct current are superimposed on this cable. As a result, the power supply to the antenna 2 and the signal line of the new broadcast can be shared.

  The second diode 17 and the capacitor 18 block the supply of power from the built-in power supply 5 or the external power supply AC adapter 101 to the tuner block 4 side. On the other hand, the capacitor 18 transmits an AC broadcast signal. With this configuration, even when the cable of the antenna 2 superimposes the DC voltage for operating the antenna 2 and the signal voltage of the antenna 2, only the broadcast signal can be transmitted to the tuner block 4. There will be no hindrance.

  Note that the second diode 17 is not necessarily required, and may be only the capacitor 18. Even in this case, the direct current component can be blocked and the alternating current component of the new broadcast can be transmitted. The first diode 15 is for internal protection, and is not necessarily provided as an embodiment of the present invention.

  Next, an example of the structure of the DC jack 3 and the DC plug 103 that is connected to the DC jack 3 will be described with reference to FIG.

  FIG. 2A shows the DC jack 3. The DC jack 3 includes a main body 30, a flange portion 31, an internal terminal 32, and terminals S, B, and P that are electrodes. The main body 31 is a hollow cylinder, and the terminals S and B are fixed at the rear end of the main body (the side opposite to the insertion port of the DC plug 103). The collar portion 31 is a ring-shaped member and is integrally formed with the main body 30. The DC jack 3 can be fixed to the STB1 main body by fixing the collar portion 31 to the STB1 main body. The internal terminal 32 is coaxially formed inside the cavity of the main body 30. The internal terminal 32 is connected to the terminal P.

  Here, when the DC plug 103 is not inserted into the DC jack 3, each operation when it is inserted will be described. When the DC plug 103 is not inserted, the terminals S and B are in contact with the contact 33. Thus, the built-in power supply 5 supplies power to the antenna 2 via the terminal B, the contact 33, and the terminal S.

  When the DC plug 103 is inserted, both electrodes of the DC plug 103 come into contact with the internal terminal 32 and the terminal S, respectively. At the same time, the terminal S bends (becomes) in the direction 36 on the outer peripheral side. Thereby, at the contact 33, the contact of the terminals S and B is released. Since the built-in power supply 5 supplies power to the antenna 2 via the terminal B and the terminal S, the supply of power by the built-in power supply 5 is cut off when the DC plug 103 is inserted. At the same time, power is supplied to the antenna 2 from the external power supply of the AC adapter 101.

  A circuit diagram is shown in FIG. When the DC plug 103 is inserted, the terminal S is separated from the terminal B. Since the built-in power supply 5 is supplied from B, the power supply is cut off when it is inserted. At the same time, since the terminals P and S are connected to the terminals of the DC plug 103, the external power supply supplies power instead of the built-in power supply 5.

  An example of the structure of the DC plug 103 is shown in FIG. The DC plug 103 includes a hollow main body 106, a cylindrical portion 107 formed integrally therewith, an external terminal 108 on the outer periphery thereof, and an internal terminal 109 on the inner periphery thereof. Lead electrodes 1081 and 1091 are led out from the terminals 108 and 109, respectively. These lead electrodes are connected to the second power cable 104 inside the main body 106. When the DC plug 103 is inserted into the DC jack 3, the external terminal 108 is electrically connected to the terminal S and the terminal 109 is electrically connected to the internal terminal 32.

  Next, a method for designing the internal power supply and external power supply of the STB 1 will be described. From the viewpoint of giving the user the degree of freedom of antenna selection, it is desirable to “supply power that matches the antenna” rather than “select an antenna that matches the constraints of the built-in power supply” as in the past. Therefore, the AC adapter 101 of the external power supply is supplied from the DC plug 103 as needed. In supplying external power, a plurality of external power supplies (AC adapters 101) having different capacities to be supplied to the antenna 2 are prepared in advance and selected.

  The built-in power supply 5 is preferably designed to conform to a predetermined power saving program standard, for example, Energy Star. In order to comply with this standard, it is desirable to design the standard antenna 2 that operates using the built-in power supply 5. The antennas of other companies do not grasp the circumstances of the tuner block 4, but if the antenna is designed in-house, it is possible to design an antenna that satisfies the standard. As a result, the antenna 2 has a standard specification that is activated by the built-in power supply 5, so that the STB 1 is established without the AC adapter 101 of the external power supply. Therefore, if designed in this way, the standard will not be lost.

  Next, the selection method of these power supplies is demonstrated using the flowchart of FIG. For this selection, steps ST11 to ST13 are executed in advance. ST11 to ST12 are designed by a manufacturer that manufactures STB1, and ST13 is performed by a user or a service person.

  In ST11, the manufacturer designs the built-in power supply so as to meet the power consumption standard. In addition, a standard antenna that operates with this built-in power supply is designed. As a result, even if an external power source is selectively used, the standard set conforms to the standard.

  In ST12, the manufacturer investigates the power capacity necessary for antennas (other companies) other than the standard antenna. A plurality of external power supplies are prepared in accordance with this capacity. As an actual sales form, as will be described later, for example, as an option of the STB 1, a standard antenna and an external power source can be listed and sold, and the user can selectively purchase them. As described above, the receiving system 10 selectively includes the standard antenna, the AC adapter 101 (and antennas purchased by other companies) in addition to the STB 1, and it is necessary to include all of them for implementation. There is no.

In ST13, a user or a service person selects an antenna.
In ST21, the power supply capacity required for the antenna selected in ST13 is calculated.
In ST22, it is determined whether the power supply capacity calculated in ST14 can be sufficiently supplied by the built-in power supply. If this determination is affirmative (YES in ST21), the process moves to ST22. In ST22, the internal power supply is selected and no external power supply is connected. Here, even when an antenna outside the standard specification is selected, if the determination in ST21 is affirmative, it is not necessary to connect an external power source.

  If this determination is negative, an external power supply sufficient for the power supply capacity calculated in ST14 is selected from a plurality of external power supplies. The power supply necessary for the antenna can be selected by the above ST23 and ST24.

  In the description of FIG. 3, a plurality of external power supplies are prepared in ST11. However, an embodiment in which a single external power supply is prepared instead of a plurality is possible depending on the investigation status in ST12 and other factors.

  In ST12 of FIG. 3, the embodiment of the present invention does not necessarily conform to the above-mentioned standard. Even if the standard does not conform to ST12, the power supply capacity supplied to the antenna 2 can be adjusted "in accordance with the antenna 2 purchased by the user". As a result, the antenna 2 is not selected according to the STB 1, so that the antenna can be selected without being restricted by the internal power supply 5.

  Further, as an embodiment of the present invention, the tuner block 4 may perform any processing by inputting a broadcast signal, and any output may be used. For example, it may be a transboat stream, a video signal, or an audio signal. The video signal and audio signal may be digital or analog.

  Next, a method for selling a receiving system including STB 1 will be described with reference to FIG. FIG. 4 shows a catalog 7 for selling a receiving system on the Internet. The catalog 7 displays products 71 to 73 to be sold, a check mark 74, a note 77 for the product, and an icon 78. When the user accesses a predetermined home page, the catalog 7 is displayed on the Internet screen. The catalog 7 has a check mark 74 attached to each of the products 71 to 73. By checking each of the products 71 to 73, selection of each of the products 71 to 73 to be purchased is accepted. Then, when the icon (to checkout) 78 is pressed, the total amount of the selected products is added up.

  The user can select a receiving device FT1 (FT1 is assumed to be a model number of the receiving device) and other optional products from the catalog 7. When the product (standard antenna) 72 is selected, the built-in power supply 5 can be used. Further, as for the product (external power source for antenna), as shown in FIG. 4, a plurality of types of STB 1 manufacturers may be prepared and selected. Further, only one type may be prepared by the manufacturer according to the sales situation of the antenna.

  Further, as shown in # 1 of the note 77, when only the built-in power supply is used, the wattage that can be supplied to the antenna by the built-in power supply is displayed. At the same time, in # 3, it is described that an antenna other than the standard antenna, for example, another company's antenna is used, and that an external power source should be used. In this case, a correspondence table between applicable external power sources and antennas of other companies may be displayed.

  By such a sales method, the manufacturer of the STB 1 can comply with a predetermined standard, for example, Energy Star, as long as the standard antenna is used. On the other hand, the user can select an external power source according to the separately purchased antenna, and can connect to the DC jack 3. Therefore, the user is less affected by the built-in power supply 5 and can select the antenna more freely.

  It supplements about the above embodiment.

  In FIG. 1A, the display panel 110, the plurality of operation buttons 111, and the power button 112 are provided. These are essential for the STB 1 to supply power to the antenna 2 as an embodiment of the present invention. is not. In view of the ease of use of the STB 1, an apparatus generally provided is illustrated. Even without these, it is possible to supply power to the antenna. Even if the power button 112 is not provided, the STB 1 can be activated immediately after the power plug 12 is connected to a commercial power source.

  In FIG. 4, an example of selling on the Internet is shown. However, it may be simply described in a paper catalog or a store flyer, and an order for a product may be received at the store.

  In the above description, the DC plug mechanically switches the contacts to switch between the internal power supply and the external power supply. However, it may be switched electrically by applying an electric circuit such as a transistor or FET. In this case, the power input may be switched by accepting the setting in the STB 1 from the user.

It is a block diagram of the set top box of the embodiment of the present invention. The example of the DC jack used for the set top box of embodiment of this invention and a DC plug is shown. It is a flowchart showing the selection method of the power supply used for the set top box of embodiment of this invention. It is a figure showing the sales method of the receiving system containing the set top box of embodiment of this invention.

Explanation of symbols

1-set top box (STB),
110-display panel, 111-operation button, 112-power button,
12-power plug, 13-first power cable,
14-F connector, 15-first diode, 16-terminal,
17-second diode, 18-capacitor, 19-path,
2-Antenna, P-terminal, B-terminal, S-terminal, G-ground,
3-DC jack (power input section), 30-rib section, 31-main body,
32-internal terminal, 33-contact,
4- tuner block (main block), 5- built-in power supply,
7-catalog, 71-product (receiving device), 72-product (standard antenna),
73-Product (external power supply for antenna), 74-Check mark, 75-Power supply,
76-Power supply, 77-Caution note, 78-Icon,
101-AC adapter, 102-power plug, 103-DC plug,
104-second power cable, 106-main body, 107-cylindrical part,
108-terminal, 109-terminal

Claims (7)

In a receiving device having a main block for inputting a broadcast signal from an external antenna and processing the broadcast signal,
An antenna connected to the outside and a built-in power supply for supplying DC power to the main block;
It has a power input section to connect a DC external power supply,
The power supply input unit is a receiving device that switches power supply to the antenna by the built-in power supply to an external power supply when the external power supply is input. The power input unit is connected to a cable that transmits a broadcast signal of the antenna, and the DC voltage and the broadcast signal are superimposed on the cable,
The receiving apparatus according to claim 1, further comprising a separation unit that cuts a DC voltage and transmits the broadcast signal to the main block between the cable and the main block.   The receiving device according to claim 2, wherein the separation unit is a capacitor.   The receiving device according to claim 1, wherein the built-in power supply conforms to a predetermined standard regarding power consumption. In a receiving system provided with the receiving device according to claim 4,
A standard antenna that receives power from a built-in power source of the receiving device and receives a broadcast signal;
An external power source connected to the power input unit,
Selectively connecting the standard antenna and the external power source to the receiver,
When using an antenna other than the standard antenna and having an electric power used exceeding the capacity of the built-in power supply, the receiving system uses the external power supply to supply power to the antenna. A receiving device having a main block that inputs a broadcast signal from an external antenna and processes the broadcast signal, and connects a built-in power source that supplies DC power to the antenna connected to the outside and a DC external power source A power supply input unit that, when the external power supply is input, a power supply input unit that switches the supply of the built-in power supply to the external power supply;
In the method of supplying power to an antenna using one or more external power supplies connected to the power input unit,
A first step of calculating the power capacity required for the antenna;
A second step of determining whether the power supply capacity is sufficient with a built-in power supply;
In the second step, when the power source capacity is not sufficient by the built-in power source, an external power source necessary for the antenna is selected, and the third step of connecting the external power source to the power source input unit is performed. Power supply method. In the selling method of a receiving system provided with the receiving device according to claim 4,
Receiving power from the built-in power supply of the receiving device, a standard antenna that receives broadcast signals can be connected, an external power supply can be connected to the power input unit according to a user's request, and the capacity of the built-in power supply When using an antenna with a power consumption exceeding, a first step of posting in an advertisement that the external power source is used to supply power to the antenna;
A method for selling a receiving system, which executes the receiving device and a second step of selling the standard antenna or the external power supply according to a user's request.

Images