JP3624365B2 - Power supply control method and in-station device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a power supply control method for controlling whether or not power is supplied from an in-station device to an in-home device connected to a digital subscriber line, and an in-station device.
A home device including a subscriber's telephone connected to the switching center is generally configured to operate by local power feeding from the local device of the switching center via a subscriber line. In addition, since the power consumption has increased along with the increase in functionality of in-home devices, the number of in-home devices that operate by in-home power supply (local power supply) has increased. As described above, since the local power supply is also performed for the home device that operates by the home power supply, reduction of power consumption in this case is desired.
[0002]
[Prior art]
FIG. 10 is an explanatory diagram of a conventional example, 101 is an in-station device, 102 and 103 are home devices, 104 is a digital subscriber line, 105 is a host device such as a processor, and the station device 101 and the host device 105 are exchanged. It is installed on the station side. 110 is a power supply, 111 is a power supply current detection circuit, 112 is a DC / AC separation unit, 113 is a power supply switching unit, 114 is a reception circuit, 115 is a transmission circuit, and 116 is a communication control circuit. A communication path switch for exchanging digital signals between subscribers transmitted and received via the receiving circuit 114 and the transmitting circuit 115 is not shown.
[0003]
The in-home devices 102 and 103 are installed on the subscriber side, 121 and 131 are DC / AC separation units, 122 is an in-device power source, 132 is a terminating resistor, 123 and 133 are receiving circuits, and 124 and 134 are transmissions. A circuit 135 indicates an AC / DC power source. Note that the reception circuits 123 and 133 and the transmission circuits 124 and 134 correspond to a telephone transmission / reception circuit, and one in-home device 102 operates by local power supply, and the other in-home device 103 has an AC / DC power supply 135. The case of the structure which operate | moves by in-house electric power feeding by is shown. Then, one in-home device 102 or the other in-home device 103 is connected to the in-station device 101 via the digital subscriber line 104.
[0004]
The DC / AC separators 112, 121, and 131 have a configuration in which a DC component for power supply and an AC component of a digital signal are separated by a capacitor or the like. In response to the normal power supply command and the reverse power supply command from the control circuit 116, the power supply polarity of the digital subscriber line 104 is switched. In addition, the communication control circuit 116 performs a normal power supply command or a reverse power supply command to the power supply switching unit 113 according to the current detection signal from the power supply current detection circuit 111, the subscriber line connection command and the subscriber line activation command from the host device 105. Is sent out. In addition, synchronization control is performed by transmitting and receiving training signals to and from the in-home devices 102 and 103 by a function not shown.
[0005]
The in-home device 102 has a configuration that operates by local power supply, and supplies a DC component to the in-device power source 122 via the DC / AC separation unit 121, and a constant current-fed current includes a capacitor and the like. A predetermined operating voltage is set and supplied to each part in the apparatus. An AC component (digital signal) is added to the receiving circuit 123, and an AC component (digital signal) from the transmitting circuit 124 is sent to the digital subscriber line 104.
[0006]
The in-home device 103 has a configuration that operates by in-house power supply (local power supply). The DC component via the DC / AC separation unit 131 is terminated by a termination resistor 132, and the AC component (digital signal) is received by a receiving circuit. The AC component (digital signal) from the transmission circuit 134 is sent to the digital subscriber line 104. The AC / DC power source 135 converts commercial AC 100V to DC and supplies it as operating power in the apparatus.
[0007]
The communication control circuit 116 of the intra-station device 101 applies a normal power supply command to the power supply switching unit 113 according to the subscriber line connection command from the host device 105, and the power supply switching unit 113 sets the power supply voltage from the power supply 110 to the normal power supply state. Power is supplied to the digital subscriber line 104. For example, when the in-home device 102 makes a call, a current due to the normal power supply flows. This current is detected by the power supply current detection circuit 111 and added to the communication control circuit 116 as a current detection signal.
[0008]
When this current detection signal is transferred to the host device 105, it is determined that the in-home device 102 is a call, and a subscriber line activation command is applied to the communication control circuit 116. As a result, the communication control circuit 116 applies a reverse power supply command to the power supply switching unit 113 to set a reverse power supply state in which the power supply polarity is reversed, and performs synchronization control by transmission / reception of a training signal.
[0009]
In the case of an incoming call to the in-home device 102, a subscriber line activation command from the host device 105 is applied to the communication control circuit 116. Therefore, the communication control circuit 116 adds a reverse power supply command to the power supply switching unit 113, and the digital subscriber The in-home device 102 is activated by inverting the power supply polarity of the line 104.
[0010]
[Problems to be solved by the invention]
In the system of the conventional example, a configuration is adopted in which power is supplied from the in-station device 101 to all in-home devices. Therefore, as in the case of the in-home device 102 that operates by the in-house power supply, the in-house device 101 also supplies power to the in-home device 103 that operates in the in-house power supply. For this reason, for the in-home device 103 that operates by in-house power supply, the power supply from the in-station device 101 is wasted, and the amount of wasted power increases as the number of such in-home devices 103 increases. It is conceivable to reduce such wasted power and save energy.
[0011]
However, since the in-station device 101 cannot identify whether or not the in-home device is a local power supply operation, the in-station power supply is performed in order to enable any in-home device to operate. In addition, the local power supply to the home device by the home power supply is wasted.
It is an object of the present invention to reduce power consumption by determining whether or not a home device is in a home power supply operation and stopping local power supply to the home device in the home power supply operation.
[0012]
[Means for Solving the Problems]
The power supply control method of the present invention is as follows: (1) A subscriber line is activated in a non-powered state for an in-home device 2 connected to an in-station device 1 including a power supply 10 via a digital subscriber line 4 and activated. If it is not possible, it is determined that the in-home device is in the station power supply operation and power is supplied from the power supply 10, and if it is possible to start, the home device determines that the station power supply is not required and supplies power from the power supply 10. It includes the process of stopping.
[0013]
(2) For the in-house device 2 connected to the in-station device 1 including the feeding power source 10 via the digital subscriber line 4, the feeding current from the feeding power source is changed, and the subscription corresponding to the change in the feeding current is performed. When the subscriber line voltage changes in response to the feeding current, the subscriber line voltage is determined to be an in-home device for in-house feeding operation, the feeding from the feeding power source is stopped, and the feeding current is When the subscriber line voltage slightly decreases or increases, it is determined that the subscriber line voltage is an in-home device for local power supply operation, and includes a process of continuing power supply from the power supply.
[0014]
(3) For the in-house device 2 connected to the in-station device 1 including the power supply 10 via the digital subscriber line 4, the equalization level for the received signal from the in-house device and the subscriber line voltage are measured. Then, it is determined whether or not the subscriber line voltage corresponds to the equalization level, and it is determined whether or not it is a home power supply operation home device. If it is not a home power supply operation home device, power supply from the power supply is performed. It includes the process of stopping.
[0015]
The intra-station apparatus of the present invention is (4) the in-station apparatus 1 for connecting the in-home apparatus 2 via the digital subscriber line 4 and supplying power to the in-home apparatus 2 from the power supply 10 via the digital subscriber line 4. The switches 17 and 18 are turned off, the subscriber lines are activated with the switches 17 and 18 turned off, and the switch 17 is determined by the activation control signal from the communication control circuit 16 for determining whether or not activation is possible. , 18 is continuously turned off to stop the power supply to the station, and an SW control circuit 19 is provided to turn on the switches 17 and 18 and perform the power supply by the station by a signal that cannot be activated.
[0016]
(5) The SW control circuit 19 is activated under an AND condition of either or both of the detection signal of the feeding current from the feeding power supply 10 and the subscriber line activation command and the subscriber line connection command. A timer having a set time of a scheduled time for obtaining a synchronization establishment signal from a line activation command and a synchronization establishment signal obtained by synchronization control in accordance with a subscriber line activation command are used as clock terminals, and an output signal by the timer activation is stored as data. It includes a flip-flop that is input to each terminal, and a gate circuit that outputs an output signal of the flip-flop and an output signal of the timer as an OFF signal of the switch.
[0017]
(6) An in-station device for connecting a home device via a digital subscriber line, a switch for supplying power to the home device via a digital subscriber line from a power supply, and a power supply voltage for supplying power to the digital subscriber line. The voltage measurement circuit to be measured and the current supplied from the power supply are changed, and the measured voltage of the voltage measurement circuit before and after the change in the supply current is compared. A comparison circuit is provided that determines that the device is an in-home device in operation and controls the switch to be turned off, and otherwise determines that the device is a home device in local power supply operation and continues to turn on the switch.
[0018]
(7) An in-station device for connecting a home device via a digital subscriber line, a switch for supplying power to the home device from a power supply power source via the digital subscriber line, and a power supply voltage for supplying power to the digital subscriber line. Compares the relationship between the voltage measurement circuit to be measured, the equalization level when equalizing and amplifying the received signal, and the voltage measured by the voltage measurement circuit, and determines whether or not the device is a home device for local power supply operation. A comparison circuit that keeps turning on the switch when it is determined that the device is a home device, and that controls the switch to be turned off when it is determined that the device is not a home power supply device.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is an explanatory diagram of a first embodiment of the present invention, wherein 1 is an in-station device, 2 is a home device, 3 is a host device such as a processor, 4 is a digital subscriber line, 10 is a power supply, and 11 is a power supply. Power supply current detection circuit, 12 is a DC / AC separation unit, 13 is a power supply switching unit, 14 is a reception circuit, 15 is a transmission circuit, 16 is a communication control circuit, 17 and 18 are switches (SW), and 19 is a SW control circuit. Show. Reference numeral 21 denotes a DC / AC separator, 22 denotes a terminating resistor, 23 denotes a receiving circuit, 24 denotes a transmitting circuit, and 25 denotes an AC / DC power source.
[0020]
The in-home device 2 shows a case of an in-home power supply (local power supply) operation in which power is supplied from an AC / DC power supply 25, and is terminated by a terminating resistor 22 with respect to a DC component by the DC / AC separation unit 21. The switches 17 and 18 of the in-station device 1 are for stopping power supply from the power supply 10 to the in-home device 2, and are turned on and off by the SW control circuit 19.
[0021]
The communication control circuit 16 controls the power supply switching unit 13 and the SW control circuit 19 in accordance with the subscriber line activation command and the subscriber line connection command from the host device 3, and also activates the subscriber line by the subscriber line activation command. Then, synchronization control is performed by transmission / reception of a training signal, and a synchronization establishment signal is added to the SW control circuit 19 when synchronization is established. Further, the SW control circuit 19 switches the switches 17, 17 according to the current detection signal from the feeding current detection circuit 11, the synchronization establishment signal from the communication control circuit 16, the subscriber activation command and the subscriber line connection command from the host device 3. 18 is controlled to turn on and off.
[0022]
FIG. 2 is an explanatory diagram of the SW control circuit according to the first embodiment of the present invention, in which 31, 35P36 is an OR circuit, 32 is an AND circuit, 33 is a timer, 34 is a flip-flop, and 37 is an inverter. When the feed current detection circuit 11 (see FIG. 1) detects that the feed current has flowed more than a predetermined value, it outputs a current detection signal of “1” and inputs it to the OR circuits 31 and 35. The host device 3 inputs a subscriber line activation command of “1” to the OR circuit 31 and inputs a subscriber line connection command of “1” to the AND circuit 32. When the communication control circuit 16 detects synchronization establishment between the in-station device 1 and the in-home device 2 by transmitting / receiving the training signal, the communication control circuit 16 inputs a synchronization establishment signal of “1” to the clock terminal CK of the flip-flop 34.
[0023]
The timer 33 sets a scheduled time required for establishing synchronization by transmitting and receiving the above-described training signal, and outputs “1” during the set time upon activation. For example, when a “1” subscriber line connection command is applied to the AND circuit 32, either or both of the “1” current detection signal and / or the subscriber line activation command are transmitted via the OR circuit 31. 32, the timer 33 is started by the output signal “1” of the AND circuit 32, the output signal of the timer 33 becomes “1”, and this output signal is applied to the data terminal D of the flip-flop 34. It is added to the OR circuit 36. The output signal of the Q terminal of the flip-flop 34 is applied to the OR circuit 36. The output signal of the OR circuit 36 is inverted by the inverter 37 to be a control signal for the switches 17 and 18, and is applied to the OR circuit 35. .
[0024]
This control signal is “0” for turning off the switches 17 and 18 and “1” for turning on the switches 17 and 18. Therefore, when the timer 33 is not activated and the flip-flop 34 is in the reset state, the output signal of the OR circuit 36 is “0”, so that the output signal of the inverter 37 is “1”, and the switches 17 and 18. Is turned on. That is, the power supply state is established.
[0025]
When the timer 33 is started by the above-described start condition, the output signal is set to “1”, so that the output signal of the inverter 37 is “0” and the switches 17 and 18 are turned off. If a synchronization establishment signal is applied to the clock terminal CK of the flip-flop 34 within the set time of the timer 33, the flip-flop 34 is set and the Q terminal output signal becomes "1". Therefore, after the set time of the timer 33 has elapsed. Further, the output signal of the inverter 37 becomes “0”, and the switches 17 and 18 are turned off. At this time, a current detection signal of “1” is continuously applied to the communication control circuit 16 via the OR circuit 35.
[0026]
If the synchronization establishment signal is not applied within the set time of the timer 33, the output signal of the timer 33 becomes “0” after the set time, so that the output signal of the inverter 37 becomes “1”, and the switches 17 and 18 Turn on. Note that the reset circuit of the flip-flop 34 is not shown, but when it is set, a configuration for resetting the communication upon completion of communication is provided. It can be realized by another logic circuit, and in the case where the switches 17 and 18 are turned off when “1”, the inverter 37 can be omitted.
[0027]
FIG. 3 is a flowchart of the first embodiment of the present invention, which will be described with reference to FIGS. In response to a subscriber line connection command from the host device 3, a normal power supply command is added from the communication control circuit 16 to the power supply switching unit 13, and a control signal from the SW control circuit 19 is "1" (the timer 33 and the flip-flop 34 are In the reset state), the switches 17 and 18 are controlled to be in the on state, and are in the normal power supply state (A1).
[0028]
In this state, when a subscriber line activation command is sent from the higher-level device 3 by an incoming call to the in-home device 2 or a current is supplied from the power supply 10 by a call on the in-home device 2 side, the feed current detection circuit 11 When the current detection signal of “1” is output from (A2), the communication control circuit 16 cancels the normal power supply (A3) and applies a reverse power supply command to the power supply switching unit 13 (A4).
[0029]
When the subscriber line connection command is “1”, a subscriber line activation command of “1” at the time of incoming call or a current detection signal of “1” at the time of call is input to the SW control circuit 19. When the timer 33 is activated, the switches 17 and 18 are turned off as described above, and the subscriber line is activated in a non-powered state. At this time, the output signal “1” of the timer 33 is added to the communication control circuit 16 as the current detection signal “1” via the OR circuits 36 and 35 (A5).
[0030]
Then, training is started under the control of the communication control circuit 16 (A6), it is determined whether or not synchronization is established (A7), and when synchronization is established in a state where the station power supply is stopped, Therefore, communication is continued in a non-powered state (A9). That is, the synchronization establishment signal is input to the clock terminal CK of the flip-flop 34 within the set time of the timer 33, the flip-flop 34 is set, and the output signal of the inverter 37 is “in accordance with the Q terminal output signal of“ 1 ”. Since it becomes 0 ″, the switches 17 and 18 continue to be turned off and become a non-powered state. Thereby, the power consumption of the in-station device 1 can be reduced.
[0031]
If the synchronization cannot be established, that is, if the synchronization establishment signal cannot be obtained within the set time of the timer 33, the output signal of the timer 33 returns to "0" and the flip-flop 34 is in the reset state. The output signal of 37 becomes “1”, the switches 17 and 18 are turned on, and the power supply state is restored (A8). In this power supply state, the communication control circuit 16 continuously sends a current detection signal of “1” to the host device 3 with a configuration not shown, and starts training (A10). (A11), if the synchronization can be established, the communication is continued in the power supply state (A12). If the synchronization cannot be established within a predetermined time, the home device 2 is not connected or the home device 2 is determined as a failure (A13), and the process is terminated.
[0032]
As described above, when the synchronization control is performed by activating the subscriber line while the switches 17 and 18 are turned off and no power is supplied, and a synchronization establishment signal is obtained, it is determined as a home device for home power supply operation and is continued. Then, the switches 17 and 18 are turned off to perform communication in the non-powered state. As a result, low power consumption can be achieved.
[0033]
FIG. 4 is a diagram for explaining the operation of in-home power supply according to the first embodiment of the present invention. When the subscriber line connection command is “1” (normal power supply), the subscriber line activation command by the incoming call is When “1” or the current detection signal (IN) from the feeding current detection circuit 11 by the call of the in-home device 2 becomes “1”, activation of the subscriber line is started and the timer 33 is activated.
[0034]
When the timer 33 is started, the current detection signal (OUT) from the SW control circuit 19 to the communication control circuit 16 is also set to “1”, and the SW control signals of the switches 17 and 18 are set to “0” to control the off state. Is done. That is, the normal power supply is switched to the non-power supply.
[0035]
When synchronization can be established by sending and receiving the training signal in this non-powered state, and the synchronization establishment signal becomes “1” within the set time (timer value) of the timer 33, the flip-flop 34 is set and continued. Thus, the OFF state of the switches 17 and 18 is maintained. That is, communication is performed in a non-powered state.
[0036]
FIG. 5 is a diagram for explaining the operation of the station power supply according to the first embodiment of the present invention. The subscriber line connection command, subscriber activation command, current detection signal (IN), subscriber line activation, and timer output signal are as follows. This is the same as the case shown in FIG. In the case of a home device that operates by local power supply, even if a training signal is transmitted and received in a non-powered state, synchronization is not established. That is, the synchronization establishment signal cannot be obtained within the set time (timer value) of the timer 33.
[0037]
When the set time of the timer 33 elapses, the output signal of the timer 33 becomes “0”, thereby turning on the switches 17 and 18. The communication control circuit 16 also applies a reverse power supply command to the power supply switching unit 13 so as to perform reverse power supply to the in-home device 2. As a result, the power supply state is switched to the reverse power supply state, the transmission / reception of the training signal is continued, whether synchronization is established or not, and when the synchronization establishment signal is obtained, communication is performed in the reverse power supply state. If synchronization is not established even after a predetermined time has elapsed, it is determined that the home device is not connected or is out of order as described with reference to FIG.
[0038]
FIG. 6 is an explanatory diagram of the second embodiment of the present invention. The same reference numerals as those in FIG. 1 denote the same parts, 41 denotes a voltage measurement circuit, and 42 denotes a comparison circuit. The power supply 10 has a constant current power supply function, but has a configuration in which the power supply current can be switched by a control signal from the comparison circuit 42. Then, as in the case of the above-described embodiment, it is determined whether the device is a home device that operates by in-house power supply or a home device that operates by station power supply. It is what makes communication.
[0039]
That is, the voltage supplied from the power supply 10 to the digital subscriber line 4 via the power supply switching unit 13 is measured by the voltage measurement circuit 41, and the comparison circuit 42 compares the previous measurement voltage with the current measurement voltage. To do. At that time, the power supply 10 is controlled to switch the power supply current, and the measured voltage before the switching is compared with the measured voltage after the switching. A home device that operates by local power supply has a power supply in the device, so that the change in voltage is small or high even when the supply current is switched, but the home device that operates by home power supply is terminated with a resistor. Therefore, the voltage changes corresponding to the feeding current. As a result, it can be determined whether or not the device is an in-home power supply device.
[0040]
FIG. 7 is an explanatory diagram of a voltage measurement circuit and a comparison circuit according to the second embodiment of the present invention. The voltage measurement circuit 41 includes an AD converter (A / D) 51, and the comparison circuit 42 includes: The case where the latch circuit 52 and the bit comparator 53 are provided is shown. Since the subscriber voltage is an analog value, it is converted to a digital value by the AD converter 51 and input to the latch circuit 52 of the comparison circuit 42. The synchronization establishment signal is input to the clock terminal CK, the output signal of the voltage measurement circuit 41 is latched, and reset when a normal power supply command is input to the reset terminal RST.
[0041]
The bit comparator 53 compares the output A of the latch circuit 52 with the output B of the voltage measurement circuit 41, outputs a signal “0” when A> B, and a signal “1” when A ≦ B. Is output. In addition, a function for holding the output signal until the end of communication may be provided, or a flip-flop or the like may be provided at the output stage of the bit converter 53. The switches 17 and 18 are turned off by “0” and turned on by “1” as in the above-described embodiment. Although the function of the control signal applied to the power supply 10 is not shown, this control signal can be formed based on, for example, a synchronization establishment signal from the communication control circuit 16.
[0042]
Therefore, when the switches 17 and 18 are in the ON state and the normal power supply command is applied to the communication control circuit 16 or the power supply switching unit 13 in accordance with the subscriber line connection command from the host device 3, the current from the power supply current detection circuit 11 When a detection signal or a subscriber line activation command from the host device 3 is added, the communication control circuit 16 applies a reverse power feeding command to the power feeding switching unit 13 to invert the power feeding polarity, and performs synchronization control by transmission / reception of a training signal .
[0043]
When the synchronization establishment signal is obtained, the output value of the AD converter 51 of the voltage measurement circuit 41 at that time is latched in the latch circuit 52 of the comparison circuit 42, and the power supply current 10 is controlled to reduce the power supply current. . The bit comparator 53 compares the output value of the AD converter 51 of the voltage measurement circuit 41 with the latch output value of the latch circuit 42. As described above, if the condition of A> B is satisfied, the in-home device 2 in this case has a voltage drop due to the resistance component due to the termination resistor 22, and thus can be determined as the in-home device 2 for in-home power supply. That is, the output signal becomes “0”, the switches 17 and 18 are turned off, and communication is performed without power supply.
[0044]
In the case of A ≦ B, even if the current value of the constant current power supply is reduced by the in-device power supply of the in-home device 2 (see FIG. 10), the voltage changes slightly or becomes higher due to the in-device power supply. . Therefore, in this case, the output signal is “1”, the switches 17 and 18 are turned on, and communication is performed by local power supply.
[0045]
FIG. 8 is an explanatory diagram of the third embodiment of the present invention. The same reference numerals as those in FIG. 1 denote the same parts, 61 is a voltage measuring circuit, and 62 is a comparison circuit. The voltage measurement circuit 61 measures the voltage applied to the digital subscriber line 4 when the constant current is supplied from the power supply 10. The reception circuit 14 equalizes and amplifies the digital signal from the home device, and adds the equalization level in that case to the comparison circuit 62. The comparison circuit 62 converts and compares this equalization level and the voltage measured by the voltage measurement circuit 61, and determines whether or not the device is a home device that operates by local power supply.
[0046]
FIG. 9 is an explanatory diagram of a voltage measurement circuit and a comparison circuit according to the third embodiment of the present invention. The voltage measurement circuit 61 is composed of an AD converter (A / D) 71. The comparison circuit 62 includes a memory (ROM) 72, a bit comparator 73, and a flip-flop 74.
[0047]
As described above, the equalization level from the reception circuit 14 is input to the bit comparator 73 of the comparison circuit 62, and the subscriber line voltage is converted into a digital signal by the AD converter 71 of the voltage measurement circuit 61. It is input as an address, converted into a value corresponding to the equalization level, and input to the bit comparator 73.
[0048]
In this case, the equalization level indicates the loss of the AC component of the digital subscriber line 4, and the subscriber line voltage corresponds to the loss of the DC component of the digital subscriber line 4 and the internal impedance of the home device. Is. In general, the loss of the alternating current component and the loss of the direct current component of the digital subscriber line 4 are correlated, and the internal impedance of the home device is a home device (internal impedance including the power source in the device) for local power supply operation. It differs depending on whether it is in-house power supply operation in the house (internal impedance including termination resistance).
[0049]
Therefore, the conversion value is set in the memory 72 in correspondence with the expected subscriber line voltage so that the relationship between the subscriber line voltage and the equalization level when the in-home device is, for example, a local power supply operation is almost equal. . In this case, for example, the subscriber line voltage and the equalization level can be set to a relationship of 1 V / dB, 30 V to 0 dB, and 40 V to 10 dB. Therefore, if the subscriber line voltage is within a change range of 30V to 60V, the change range of the equalization level is 0 to 30 dB.
[0050]
The memory 72 stores the equalization level using the voltage value as an address. For example, the equalization level 00 (= 0 dB) to the address of 1E (= 30 V) to 3 C (= 60 V) in hexadecimal notation. By storing 1E (= 30 dB), 30 to 60 V can be converted to an equalization level of 0 to 30 dB and input to the bit comparator 73.
[0051]
As a result of comparison by the bit comparator 73, when the equalization level B is equal to the equalization level A obtained by converting the subscriber line voltage by the memory 72 (when all bits are the same or the upper bits are equal), “1”. Is applied to the data terminal D of the flip-flop 74. When the synchronization establishment signal is input from the communication control circuit 16, the synchronization establishment signal is added to the clock terminal CK to set the flip-flop 74. In this case, an in-home apparatus for local power supply operation is connected, and the switches 17 and 18 are turned on by the signal “1” from the Q terminal of the flip-flop 74 to continuously supply power from the power supply 10.
[0052]
In addition, with respect to the inputs A and B of the bit comparator 73, when A> B, that is, when the subscriber line voltage is high under the same conditions, a home device for home power supply operation is connected. 0 "is output, and the flip-flop 74 is reset when the synchronization establishment signal is applied, and the switches 17 and 18 are turned off by the" 0 "signal from the Q terminal, and the power supply to the station is stopped. That is, a low power consumption state is set. The logic circuit in this case can also be changed according to the on / off logic levels of the switches 17 and 18.
[0053]
The present invention is not limited only to each of the above-described embodiments, and various additions and changes can be made, and whether the in-home device connected via the digital subscriber line has a configuration of a local power supply operation, Alternatively, it is determined whether the configuration is a home power supply (local power supply) operation, and the station power is supplied only to the home device in the station power supply operation. Of course, such a determination process can be performed for each call setting. However, at the time of system start-up, the result of determining whether it is a local power supply operation for the in-home device as a process for collecting subscriber information is stored as subscriber data, and periodic subscriber information It is also possible to update the subscriber data by collection.
[0054]
【The invention's effect】
As described above, according to the present invention, if synchronization can be established by subscriber line activation (synchronization control) in a station power supply stop state, it is determined as a home device for home power supply operation and station power supply is stopped. In addition, low power consumption can be achieved. It can also be determined whether or not the device is a home power supply operation based on the change in the subscriber line voltage when the power supply current is changed. In addition, based on the correlation between the equalization level at the time of equalization amplification of the received signal and the resistance loss of the digital subscriber line, and the difference in internal impedance between the in-home device for home power supply operation and the in-home device for station power supply operation, It can be determined whether or not the device is a home power supply operation. In either case, there is an advantage that the in-house power supply operation of the in-home device can stop the station power supply and reduce the power consumption.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram of a first embodiment of the present invention.
FIG. 2 is an explanatory diagram of a SW control circuit according to the first embodiment of this invention.
FIG. 3 is a flowchart of the first embodiment of the present invention.
FIG. 4 is an operation explanatory diagram of in-home power supply according to the first embodiment of this invention.
FIG. 5 is an explanatory diagram of the operation of local power supply according to the first embodiment of this invention.
FIG. 6 is an explanatory diagram of a second embodiment of the present invention.
FIG. 7 is an explanatory diagram of a voltage measurement circuit and a comparison circuit according to a second embodiment of the present invention.
FIG. 8 is an explanatory diagram of a third embodiment of the present invention.
FIG. 9 is an explanatory diagram of a voltage measurement circuit and a comparison circuit according to a third embodiment of the present invention.
FIG. 10 is an explanatory diagram of a conventional example.
[Explanation of symbols]
1 In-station equipment
2 Home equipment
3 Host device
4 Digital subscriber line
10 Power supply
11 Feeding current detection circuit
12 DC / AC separator
13 Power supply switching part
14 Receiver circuit
15 Transmitter circuit
16 Communication control circuit
17,18 switch
19 SW control circuit
21 DC / AC separator
22 Terminating resistor
23 Receiver circuit
24 Transmitter circuit
25 AC / DC power supply

Claims (7)

For the in-home device connected to the in-station device including the power supply via the digital subscriber line, the subscriber line is activated in the non-powered state. A power feeding control method comprising a step of performing power feeding from the power feeding power source and determining that the in-home device does not require power feeding when the power can be activated and stopping power feeding from the power feeding power source. For an in-home device connected via a digital subscriber line to an in-station device including a power supply, the power supply current from the power supply is changed, and the subscriber line voltage corresponding to the change in the power supply current is measured, If the subscriber line voltage changes in response to the feed current, the subscriber line voltage is judged to be an in-home device for in-house feed operation, the feed from the feed power supply is stopped, and the subscriber line voltage slightly decreases in response to the feed current Alternatively, the power supply control method includes a process of determining that the device is an in-home device for local power supply operation when the power supply is increased and continuing power supply from the power supply. For an in-home device connected to an in-station device including a power supply via a digital subscriber line, an equalization level for a received signal from the in-home device and a subscriber line voltage are measured, and the equalization level is set. It is determined whether or not it is a corresponding subscriber line voltage to determine whether or not it is a home power supply in-home device, and if it is not a home power supply operation in-home device, including a process of stopping power supply from the power supply A power supply control method characterized by the above. In an in-station device for connecting a home device via a digital subscriber line,
A switch for supplying power to the in-home device from the power supply via the digital subscriber line;
A communication control circuit for activating the subscriber line by turning off the switch and determining whether the activation is possible;
An SW control circuit that continuously turns off the switch by a start enable signal from the communication control circuit and stops the station power supply, and turns on the switch by a non-startable signal to perform the station power supply. In-station device characterized. The SW control circuit is activated under an AND condition of a detection signal of a feeding current from the feeding power supply, a subscriber line activation command or both and a subscriber line connection command, and the subscriber line activation command. A timer having a set time of a scheduled time from which a synchronization establishment signal is obtained from, and the synchronization establishment signal obtained by the synchronization control according to the subscriber line activation command as a clock terminal, and an output signal by the activation of the timer as data 5. The in-station apparatus according to claim 4, further comprising: a flip-flop input to each terminal; and a gate circuit that outputs an output signal of the flip-flop and an output signal of the timer as an off signal of the switch. In an in-station device for connecting a home device via a digital subscriber line,
A switch for supplying power to the in-home device from the power supply via the digital subscriber line;
A voltage measurement circuit for measuring a supply voltage to be supplied to the digital subscriber line;
In-home device for in-house power supply operation in the case of a change in the measured voltage corresponding to the change in the supply current by changing the supply current from the supply power source, comparing the measurement voltage of the voltage measurement circuit before and after the change in the supply current And a comparison circuit that determines that the switch is turned off and determines that the switch is in a home power supply operation in other cases and continues to turn on the switch. In an in-station device for connecting a home device via a digital subscriber line,
A switch for supplying power to the in-home device from the power supply via the digital subscriber line;
A voltage measurement circuit for measuring a supply voltage to be supplied to the digital subscriber line;
The relationship between the equalization level when equalizing and amplifying the received signal and the voltage measured by the voltage measurement circuit is compared, and it is determined whether or not the device is a home power supply operation home device. And a comparator circuit that controls the switch to be turned off when it is determined that the switch is kept on at times and is not an in-home device for local power supply operation.

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