JP2016148929A - Electric device and power-source cooperative system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electric device which can be started even when completely disconnected from an AC power source.SOLUTION: When entering power-ON state, a CPU 107 controls a switch SW1, to connect a signal line 71 to a power supply line where start-up power M1 is supplied. The start-up power M1 turns on a transistor Q1, to turn on a main power switch SW3. When started by power supplied from a power supply section 157, a CPU 156 turns on a switch SW2, to keep the transistor Q1 on with start-up power M2. Even when no start-up power M1 is supplied, the main power switch SW3 can be kept on.SELECTED DRAWING: Figure 3

Description

  The present invention relates to an electric device that operates by supplying power from an AC power source.

  As an electric device that operates by receiving power supply from an AC power source, for example, there is a powered speaker. The powered speaker can output a loud sound by receiving power supply from an AC power source.

  For example, when performing stereo reproduction using such a powered speaker, two powered speakers are required. Each of the two powered speakers needs to be connected to an AC power source. Therefore, the user needs to manually turn off or turn on the power of each powered speaker.

  Therefore, for example, the powered speaker system of Patent Document 1 performs power control by remote operation by performing control by remote operation in accordance with an external control signal.

JP 2004-104649 A

  Since the powered speaker system of Patent Document 1 performs power supply control in accordance with an external control signal, the device needs to be in a standby state. In the standby state, standby power is required, and it is not in a power-off state (a state where the AC power supply is completely cut off). When the AC power supply is completely cut off in order to reduce power consumption, it is necessary to turn on the power manually.

  Therefore, an object of the present invention is to provide an electric device that can be activated even when it is completely cut off from an AC power source.

  An electrical device of the present invention includes an interface to which another device is connected, a signal line for connecting to the other device via the interface, and a main power switch for turning on or off power supply from a main power source An activation circuit for turning on the main power switch when power is supplied from the signal line; and starting when the main power switch is turned on and receiving power supply from the main power source, And a control unit that maintains the ON state of the switch.

  As described above, the electric device according to the present invention has an activation circuit for turning on the main power switch (relay) when power is supplied from the signal line for connecting to other devices. It can be activated even if it is completely shut off from. In addition, since the main power switch is kept on after starting, the signal line supplied with power can be used for communication, and the signal line for communication and the signal line for power supply are shared. It is also possible to connect only one cable to other devices.

  In order to maintain the on state of the main power switch, for example, a power supply switch that turns on or off the power supply from the main power source to the start-up circuit is provided, and the control unit realizes by turning on the power supply switch at the time of start-up be able to.

  In addition, when the control unit receives power supply from the main power source, it is preferable to transmit a response signal to another device via the signal line. In the other device (second device), power is supplied via the signal line at the start-up, and then the signal line is connected to the control unit (second control unit) of the second device to send a response signal. Ready to receive. When the second device receives the response signal, the second device maintains a state where the signal line is connected to the second control unit. Thereby, after the first device is activated, a signal line for supplying power to the first device can be used as a signal line for communication.

  According to the present invention, even if the AC power supply is completely cut off, it can be activated.

It is the schematic which shows the structure of a powered speaker system. It is a block diagram about the structure of a powered speaker. It is a circuit diagram which shows the structure for performing a power supply interlocking | linkage. It is a circuit diagram which shows the structure for performing a power supply interlocking | linkage. It is a circuit diagram which shows the structure for performing a power supply interlocking | linkage. It is a circuit diagram which shows the structure for performing a power supply interlocking | linkage. It is a circuit diagram which shows the structure for performing a power supply interlocking | linkage. It is a flowchart which shows operation | movement of the powered speaker at the time of starting. It is a flowchart which shows operation | movement of the powered speaker at the time of completion | finish.

  FIG. 1 is a schematic diagram illustrating a configuration of a powered speaker system 1. As shown in FIG. 1, the powered speaker system 1 includes two powered speakers (powered speaker 10L and powered speaker 10R).

  The powered speaker 10R corresponds to the electric device (first device) of the present invention, and the powered speaker 10L corresponds to the second device.

  FIG. 2 is a block diagram showing the configuration of the powered speaker 10L and the powered speaker 10R.

  The powered speaker 10L includes an input unit 101, a DA converter (DAC) 102, a volume 103, an amplifier (Amp) 104, a speaker unit 105, a USB interface 106, a control unit (CPU) 107, and a power supply unit 108. Yes.

  The powered speaker 10 </ b> R includes a USB interface 151, a DAC 152, a Volume 153, an Amp 154, a speaker unit 155, a CPU 156, and a power supply unit 157.

  The USB cable 21 is connected to the USB interface 106 of the powered speaker 10L. Similarly, a USB cable 21 is connected to the USB interface 151 of the powered speaker 10R. The powered speaker 10L and the powered speaker 10R are connected to each other via the USB cable 21.

  The powered speaker 10L includes an outlet plug 31L, and is connected to an AC power supply via the outlet plug 31L. The power supply unit 108 converts the power supplied from the AC power supply via the outlet plug 31L into a direct current, and supplies it to the hardware such as the CPU 107 as a DC power supply.

  The powered speaker 10R includes an outlet plug 31R and is connected to an AC power supply via the outlet plug 31R. The power supply unit 157 converts the power supplied from the AC power supply via the outlet plug 31R into a direct current, and supplies it to the hardware such as the CPU 156 as a DC power supply.

  Data related to content (for example, audio data such as MP3) is input to the input unit 101 of the powered speaker 10L. The input unit 101 has a network interface (such as a LAN terminal or a wireless LAN function unit) or various input interfaces such as a USB interface. The input unit 101 decodes data related to the input content and extracts a digital audio signal. In this example, digital audio signals of two channels (L channel and R channel) are extracted. The L channel digital audio signal is output to the DAC 102. The R channel digital audio signal is output to the powered speaker 10 </ b> R via the USB interface 106 and the USB cable 21.

  In this example, the data related to the content is input and the digital audio signal is extracted by the input unit 101. However, the digital audio signal may be input via an interface such as a digital audio terminal. Good. Further, an analog audio terminal may be provided to input an analog audio signal.

  The digital audio signal output to the DAC 102 is converted into an analog audio signal. The signal level of the analog audio signal is adjusted by the Volume 103 and amplified by the Amp 104. The amplified analog audio signal is output to the speaker unit 105 and emitted.

  The R channel digital audio signal is input to the USB interface 151 of the powered speaker 10 </ b> R and output to the DAC 152. The digital audio signal output to the DAC 152 is converted into an analog audio signal. The signal level of the analog audio signal is adjusted by Volume 153 and amplified by Amp 154. The amplified analog audio signal is output to the speaker unit 155 and emitted.

  The powered speaker system 1 can turn on the power of the powered speaker 10R in conjunction with the power on of the powered speaker 10L even when the powered speaker 10R is in a power off state (a state in which the power speaker 10R is completely cut off from the AC power source). Realize a power interlocking system. Hereinafter, the power supply interlocking system will be described with reference to FIGS.

  3 to 7 are circuit diagrams showing a configuration for performing power supply interlocking. FIG. 8 is a flowchart showing the operation at the time of activation. FIG. 9 is a flowchart showing the operation at the end.

  FIG. 3 is a circuit diagram when the powered speaker 10L is in a power-off state (or standby state) and the powered speaker 10R is in a power-off state.

  As shown in FIG. 3, the power supply unit 108 of the powered speaker 10 </ b> L includes a transformer 81. The transformer 81 takes out power to be supplied from the main power supply (AC power supply) to various hardware. The extracted electric power is converted into a DC power source by the rectifying / smoothing circuit 82 and supplied to various hardware.

  Also, power different from the main supply power is taken out from the transformer 81, and the starting power M1 having a low voltage (for example, about 3.3V) is taken out through the rectifying and smoothing circuit 83. The starting power M1 is supplied to the switch SW1.

  The USB cable 21 has a plurality of signal lines (four signal lines). In this example, the four signal lines respectively constitute an audio signal supply line (SPDIF), a ground line (GND), a signal line for transmission (TX) in the CPU 107, and a signal line for reception (RX) in the CPU 107. . The audio signal supply line (SPDIF) supplies an R channel digital audio signal from the input unit 101 to the DAC 152 via the USB interface 106 and the USB interface 151.

  The switch SW1 is inserted between the USB interface 106 and a reception (RX) terminal in the CPU 107. The switch SW1 is a changeover switch, and a state (state 1) in which the reception signal line 71 in the USB interface 106 is connected to a reception (RX) terminal of the CPU 107, and the reception signal line 71 is connected to the power supply unit 108. The state to be connected to the power supply line to which the starting power M1 is supplied (state 2) is switched. When the switch SW1 is in the state 2, the signal line 71 functions as a power supply line and supplies the starting power M1 to the powered speaker 10R.

  The switch SW1 is in the state 1 in FIG. When the CPU 107 shifts from the power-off state to the power-on state (or when standby is canceled), the CPU 107 shifts the switch SW1 from the state 1 to the state 2 as shown in FIG.

  When the switch SW1 transitions to the state 2, the starting power M1 is supplied to the transmission signal line 72 in the powered speaker 10R. Then, the voltage by the starting power M1 is applied to the base of the transistor Q1, and the transistor Q1 is turned on. Thereby, the relay connected to the collector of the transistor Q1 is turned on. The relay corresponds to the main power switch SW3 on the AC power source side of the power supply unit 157. When the transistor Q1 is turned on, the main power switch SW3 is turned on as shown in FIG. That is, the transistor Q1 functions as an activation circuit that turns on the main power switch SW3 in conjunction with the power supplied from the signal line 71 and the signal line 72.

  In this way, the powered speaker 10R shifts to the power-on state, and power is supplied from the power supply unit 157 to each hardware such as the CPU 156. Then, when the CPU 156 is activated by receiving power supply from the power supply unit 157 which is a main power supply, the CPU 156 performs an operation of maintaining the on state of the main power switch SW3.

  In this example, the power supply unit 157 outputs start-up power M2 having a low voltage (for example, about 3.3 V, which is the same as the start-up power M1), separately from the power supplied to various hardware. This starting power M2 is connected to the switch SW2. The switch SW2 corresponds to the power supply switch of the present invention, and is off in the state shown in FIG. The CPU 146 is activated upon receiving power supply from the power supply unit 157, and then turns on the switch SW2, as shown in FIG. Then, the voltage by the starting power M2 is applied to the base of the transistor Q1, and the on state of the transistor Q1 is maintained. Thereby, even when the starting power M1 is not supplied, the on state of the transistor Q1 is maintained and the on state of the main power switch SW3 is maintained.

  However, in this state, the communication signal line 71 and the signal line 72 function as power supply lines and do not function as communication lines. Therefore, the CPU 107 and the CPU 156 perform the operation shown in the flowchart of FIG.

  As shown in FIG. 8, when the CPU 107 of the powered speaker 10L shifts from the power-off state to the power-on state, or when standby is released (s11), the state of the switch SW1 is changed every predetermined time (for example, 1 second). And the state 1 and the state 2 are alternately changed (s12). Thereafter, the CPU 107 transmits a response request to the powered speaker 10R using the transmission signal line connected to TX (s13).

  When the CPU 156 of the powered speaker 10R shifts from the power-off state to the power-on state (s21), the switch SW2 is turned on as described above (s22). Thereafter, the CPU 156 confirms whether or not a response request has been received from the powered speaker 10L (s23), and when a response request is received, transmits a response signal via the signal line 72 (s24).

  After transmitting a response request to the powered speaker 10R, the CPU 107 checks whether a response signal has been received (s14). CPU 107 repeats transmission of a response request until a response signal is received. When the CPU 107 receives the response signal, the CPU 107 fixes the state of the switch SW1 to the state 1 and fixes the signal line 71 to the RX of the CPU 107 (s15). Thereby, as shown in FIG. 7, the state in which the signal line 71 and the signal line 72 function as communication lines is maintained.

  FIG. 9 is a flowchart showing the operation of the powered speaker at the end. The CPU 107 confirms whether or not the user has operated a standby switch (not shown) or the like to instruct the transition to the standby state (s31). When the CPU 107 is instructed to shift to the standby state, the CPU 107 transmits a power-off instruction to the powered speaker 10R (s32), and shifts to the standby state (s33).

  The CPU 156 confirms whether or not a power-off instruction has been received from the powered speaker 10L (s41). When the CPU 156 receives a power-off instruction from the powered speaker 10L, the CPU 156 turns off the switch SW2 (s42). As a result, the transistor Q1 is turned off and the main power switch SW3 is turned off, so that the AC power supply is completely cut off. Therefore, the state of the circuit shown in FIG.

  Since the powered speaker 10R is completely cut off from the AC power supply, the power speaker 10R is in a state of further power saving than the standby state (power consumption is almost zero). Even in such a power-off state, if the powered speaker 10L shifts to the power-on state, the powered speaker 10R also shifts to the power-on state and starts up in conjunction with the power-on of the powered speaker 10L. be able to. Therefore, the powered speaker 10L and the powered speaker 10R can realize digital audio signal transmission / reception, control signal transmission / reception, and power supply interlocking operation with only one USB cable.

  In the present embodiment, an example in which an interface and a cable according to the USB standard are used as the connection between the first device and the second device is shown. However, other standards such as HDMI (registered trademark) are used. It is possible to use an interface and a cable, and it is also possible to use a dedicated interface and cable.

  Moreover, in this embodiment, although the power speaker was illustrated as a 1st apparatus and a 2nd apparatus, and the structure which outputs the audio signal of a stereo channel was illustrated, the power supply interlocking | linkage system using another electric apparatus is built. It is also possible to do. For example, a subwoofer for low sound range reproduction can be applied as the first device, and a main speaker (with a built-in receiver function) for medium and high sound range reproduction can be applied as the second device. In this case, even if the power of the subwoofer is turned off, the subwoofer can be activated in conjunction with the activation of the main speaker. For example, a television can be applied as the first device, and a recorder can be applied as the second device. In this case, even when the television is turned off, the television can be activated in conjunction with the activation of the recorder.

DESCRIPTION OF SYMBOLS 1 ... Powered speaker system 10L, 10R ... Powered speaker 21 ... USB cable 31L, 31R ... Outlet plug 71, 72 ... Signal line Q1 ... Transistor SW1 ... Switch SW2 ... Switch SW3 ... Main power switch 101 ... Input part 102 ... DAC
103 ... Volume
104 ... Amp
105 ... Speaker unit 106 ... USB interface 107 ... CPU
108 ... Power supply 151 ... USB interface 152 ... DAC
153 ... Volume
154 ... Amp
155 ... Speaker unit 156 ... CPU
157 ... Power supply section

Claims (6)

An interface to which other devices are connected;
A signal line for connecting to the other device via the interface;
A main power switch for turning on or off the power supply from the main power supply;
A starting circuit for turning on the main power switch when power is supplied from the signal line;
An electrical apparatus comprising: a control unit that is activated when the main power switch is turned on and receives power supply from the main power source and maintains the on state of the main power switch. A power supply switch for turning on or off power supply from the main power source to the starter circuit;
The electric device according to claim 1, wherein the control unit maintains the on state of the main power switch by turning on the power supply switch.   The electrical device according to claim 1, wherein the control unit transmits a response signal to the device via the signal line when receiving power supply from the main power source. . A control unit that operates by supplying power from a main power source;
An interface to which other devices are connected;
A signal line for connecting to another device via the interface;
A changeover switch that switches between a state in which the signal line is connected to the control unit and a state in which the signal line is connected to a power supply line that supplies power from the main power supply;
With
The control unit shifts to a state in which the changeover switch is connected to the power supply line at start-up, supplies power to the other device, and then shifts to a state in which the changeover switch is connected to the control unit. Receive response signals from other devices,
When the response signal is received, the electrical switch is maintained in a state of being connected to the control unit. A power interlocking system comprising a first device comprising the electrical device according to claim 3 and a second device connected to the first device,
The second device includes a second control unit that operates by supplying power from a main power source,
A second interface to which the first device is connected;
A second signal line for connecting to the first device via the second interface;
A changeover switch for switching between a state in which the second signal line is connected to the second control unit and a state in which the second signal line is connected to a power supply line that supplies power from the main power source;
With
The second control unit shifts to a state in which the changeover switch is connected to the power supply line at the time of start-up, supplies power to the first device, and then connects the changeover switch to the second control unit To receive the response signal,
When the response signal is received, the power supply interlocking system is configured to maintain the changeover switch in a state of being connected to the second control unit. When the second control unit is instructed to shift to a standby state, the second control unit transmits a power-off instruction to the first device,
The power supply interlocking system according to claim 5, wherein the control unit of the first device cancels the ON state of the main power switch when receiving the power shutdown instruction.

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