JP2013128338A - Power supply circuit controller and stopping method for power supply circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply sequence having no effect of a variation or a device state on start/stop by controlling both of a device and a power supply circuit, thereby to achieve device reliability.SOLUTION: The present invention comprises: a device 10 requiring a power supply sequence; a power supply circuit 30 for supplying electric power to the device 10; a start/stop control circuit 20 for controlling start/stop; and an adjustment circuit 50 that receives a control signal from the start/stop control circuit 20 and adjusts an output voltage. The start/stop control circuit 20 controls the device 10 and the power supply circuit 30 to achieve a start sequence and a stop sequence.

Description

  The present invention relates to a power supply circuit control device and a power supply circuit stop method, and more particularly, to a power supply circuit control device that provides a power supply stop sequence to a device to which a power supply device requests a power supply sequence, and to stop the power supply circuit Regarding the method.

In order to supply power to a device, the power supply sequence specification that specifies the order of starting and stopping the supply voltage in response to a request from a load side device has increased in recent years. As means for realizing this requirement, there is Patent Document 1. Patent Document 1 discloses an electronic device including a plurality of power supplies having a circuit for controlling the order of stopping when voltage control at the time of stopping is necessary, and a circuit for controlling a stopping time (voltage drop time). Describes that the required voltage control at the time of stopping can be performed.
Patent Document 2 describes providing a start / stop order control device that can flexibly control the start / stop order of a power supply start circuit.

JP 2010-226863 A JP-A-2005-253124

  The power supply sequence required by the device is defined for the purpose of device protection such as reverse current flowing through a parasitic diode inside the device. Violation of this rule will damage the device. The device may be broken once, but the device may be destroyed due to the accumulation of damage, which may impair the long-term reliability of the product.

  Therefore, it is necessary to protect the power supply sequence, prevent device destruction and damage, and ensure product reliability. The power supply sequence constitutes a power supply sequence in which a plurality of power supply circuits cooperate to start / stop the supply voltage in the order required by the device.

  At the time of start-up, the start-up sequence is realized by controlling the start-up signals in the order set in advance in each power supply circuit. At the time of stop, the stop signal is controlled in the order set in the same manner as at the time of start to realize the stop sequence.

  When the stop control is performed, the power supply circuit is stopped and the device is initially discharged by the load of the device. However, after the power supply circuit and the device are completely stopped, the impedance becomes high impedance, and the capacitor mounted between the power supply circuit and the device may not be completely discharged and residual charges may exist. For this reason, in order to remove the influence of the reversal of the voltage at the time of stop and the residual charge at the time of start-up, the discharge circuit performs discharge and stops.

  However, if power supply stop control is performed without first knowing the device load status in the stop sequence, even if the power supply circuit is stopped, the initial drop in output voltage is due to the device dynamics and the time constant of the discharge circuit. Depends on. Since the voltage drop time also varies depending on the state of the device, the stop time varies due to variations in component constants and changes in device conditions. When the worst case variation is large, the sequence is reversed, and a reverse current may flow through the internal diode, causing damage to the device.

  The present invention provides a power supply sequence that is not affected by variations and changes in device conditions by controlling the power supply sequence using a power supply circuit capable of current source / sink and a circuit that monitors and controls the state of the device and the power supply circuit. To do.

  The above-described problem is a power supply circuit control device that is connected to the feedback input of the power supply circuit and controls the output of the power supply circuit. When the power supply circuit is stopped, the output voltage to the feedback input is increased and the output of the power supply circuit is increased. This can be solved by a power supply circuit control device that stops the output of the telephone circuit after the voltage is lowered.

  A step of monitoring the output voltage of the power supply circuit; a step of increasing the feedback input voltage of the power supply circuit; a step of confirming that the output voltage is less than a predetermined voltage; and a step of stopping the power supply circuit; This can be achieved by stopping the power supply circuit.

  According to the present invention, since the start / stop sequence can be realized and the start / stop power sequence can be protected without being affected by the indefinite load state of the device and the stop time due to component variations, the device (load) Can prevent damage.

It is a block diagram of a power supply system. It is a flowchart explaining the starting process of a power supply sequence. It is a flowchart explaining the stop process of a power supply sequence. It is a block diagram of another power supply system. It is a wave form chart at the time of starting. It is a wave form diagram at the time of starting abnormality. It is a wave form diagram at the time of a stop process. It is a block diagram of another power supply system.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings using examples. The same reference numerals are assigned to substantially the same parts, and the description will not be repeated.

  In this embodiment, a basic operation of power supply sequence control will be described. First, the power supply system 100 will be described with reference to FIG. The power supply system 100 includes a device 10 that requires a power supply sequence, a power supply circuit 30 capable of current source / sink for power supply to the device 10, a start / stop control circuit 20 that controls start / stop, and a start / Adjustment circuit 50 that receives the control signal from stop control circuit 20 and adjusts the output voltage. The power supply circuit 30 and the adjustment circuit 50 are two circuits that are distinguished by A and B. The power supply circuit 30-A may be referred to as a power supply circuit A. The adjustment circuit 50 is the same.

  The power supply circuit 30 has a start / stop port, an OUTPUT port, and a Feed Back port. The device 10 includes a load circuit 11-A, a load circuit 11-B, a device stop control port, and a power stop signal port. The start / stop control circuit 20 includes a voltage monitoring circuit 21-A, a voltage monitoring circuit 21-B, a power supply stop control port, and a voltage control signal port.

  The stop signal is input to the device stop control port of the device 10. The power stop signal port of the device 10 is connected to the power stop control port of the start / stop control circuit 20. The output of the voltage monitoring circuit 21 of the start / stop control circuit 20 is connected to the start / stop port of the power supply circuit 30. The voltage output output from the OUTPUT port of the power supply circuit 50 is connected to the load circuit 11 of the device 10, the voltage monitoring circuit 21 of the start / stop control circuit 20, and the adjustment circuit 50. The voltage control signal output from the voltage control signal port of the start / stop control circuit 20 is input to the adjustment circuit 50. The output of the adjustment circuit 50 is input to the Feed Back port of the power supply circuit 30.

  With reference to FIG. 2, the startup flow of the power supply circuit will be described. The startup sequence of the power supply circuit is assumed to be a power supply circuit 30-A and a power supply circuit 30-B. In FIG. 2, the start / stop control circuit 20 accepts start of a start / control circuit (not shown) (S8). The start / stop control circuit 20 generates a start signal for the power supply circuit A and outputs it to the power supply circuit 30-A (S9). The power supply circuit 30-A is activated (S10). The power supply circuit 30-A outputs a voltage (S11). The start / stop control circuit 20 monitors the voltage of the power supply circuit 30-A (S12). The start / stop control circuit 20 determines whether the output voltage is OK (S13). In the case of NG, the start / stop control circuit 20 executes the stop process of the power supply circuit 30-A (S14) and ends.

  When OK at step 13, the start / stop control circuit 20 generates a start signal for the power supply circuit B and outputs it to the power supply circuit 30-B (S15). The power supply circuit 30-B is activated (S16). The power supply circuit 30-B outputs a voltage (S17). The start / stop control circuit 20 monitors the voltage of the power supply circuit 30-B (S18). The start / stop control circuit 20 determines whether the output voltage is OK (S19). In the case of NG, the start / stop control circuit 20 executes a stop process for the power supply circuit 30-A and the power supply circuit 30-B (S20) and ends. (S20). When the result of step 19 is OK, the start / stop control circuit 20 completes the start control.

  With reference to FIG. 3, the flow of stopping the power supply circuit will be described. The power supply circuit is stopped in the order of the power supply circuit 30-A and the power supply circuit 30-B. In FIG. 3, the device 10 performs a device stop process (S23). The device 10 stops the device functions of the I / O and internal core (S24). The device 10 enters a function stop state (S25). The device 10 sends a stop signal to the start / stop control circuit 20 (S26).

  The start / stop control circuit 20 that has received the stop signal starts a stop sequence (S27). The start / stop control circuit 20 sets the voltage control value A (S28). The power supply circuit 30-A sets the voltage control value A in the adjustment circuit A (S29). The power supply circuit 30-A performs Feed Back control (S30). The start / stop control circuit 20 acquires the voltage of the power supply circuit A subjected to Feed Back control (S31). The start / stop control circuit 20 determines whether the voltage is less than the threshold value a (S32). In the case of NG, the start / stop control circuit 20 adjusts the control value and returns to Step 28 (S33). When it is OK in step 32, the start / stop control circuit 20 sends a stop signal to the power supply circuit A (S34). The power supply circuit 30-A stops (S35). The start / stop control circuit 20 releases the voltage control (S36). The start / stop control circuit 20 completes the stop of the power supply circuit 30-A (S37).

  The start / stop control circuit 20 sets the voltage control value B (S38). The power supply circuit 30-B sets the voltage control value B in the adjustment circuit B (S39). The power supply circuit 30-B performs Feed Back control (S40). The start / stop control circuit 20 acquires the voltage of the power supply circuit B subjected to Feed Back control (S41). The start / stop control circuit 20 determines whether the voltage is less than the threshold value b (S42). In the case of NG, the start / stop control circuit 20 adjusts the control value and returns to Step 38 (S43). When it is OK at step 42, the start / stop control circuit 20 sends a stop signal to the power supply circuit B (S44). The power supply circuit 30-B stops (S45). The start / stop control circuit 20 releases the voltage control (S46). The start / stop control circuit 20 completes the stop of the power supply circuit 30-B (S47) and ends.

  When starting the stop sequence, an OFF switch (not shown) provided in the apparatus is used to transmit the stop signal to the device 10 that performs stop processing. The device 10 has a program for executing a processing flow for performing stop processing in advance, and starts stop control after receiving a stop signal. A stop process is instructed to the device 10, device function stop control is performed, internal control and use I / O are stopped, and the function of the device 10 is stopped. By making the transition to the function stop state, the device 10 eliminates the load fluctuation associated with signal transmission / reception, makes the load state constant, and makes the device 10 transition to the power stop sequence. Next, by stopping the power supply circuit, it is possible to always perform stop processing under the same conditions, and it is possible to eliminate the influence of component variations and device conditions.

  After the device is stopped, a stop signal is transmitted to the start / stop control circuit 20 and the power supply circuit is controlled using the start / stop control circuit 20. The start / stop control circuit 20 applies a voltage control value A to the adjustment circuit A after receiving the stop signal.

  In Patent Document 1, since the power supply circuit is only stopped, the voltage drop time varies depending on the load state. However, the output voltage control is performed by the power supply circuit having the source / sink function and the adjustment circuit 50-A. This realizes a circuit that does not depend on the load.

  The power supply circuit 30 performs control inside the power supply so that the voltage sensed by the output voltage is returned to the feedback of the power supply circuit to keep the output voltage constant. When the feedback voltage increases, it is determined that the output voltage has increased, and control is performed to lower the output voltage inside the power supply circuit, and conversely, control is performed to increase the output voltage when the voltage decreases.

  The adjustment circuit 50 shown in the present embodiment is a circuit in which a voltage other than the output voltage is externally added to the voltage feedback by using a power supply control method. By using this adjustment circuit 50, the output voltage can be lowered below the rated voltage. By applying an adjustment signal to the adjustment circuit 50 and returning it to the Feed Back port of the power supply circuit 30 -A, the voltage of the OUTPUT of the power supply circuit 30 is lowered. By forcibly lowering the voltage in this way, it is possible to reliably realize the stop sequence without being affected by the load and without causing reverse rotation of the stop sequence due to the influence of variations in peripheral parts.

  With reference to FIG. 4, another power supply system 100A will be described. Here, only differences from the power supply system 100 described with reference to FIG. 1 will be described. In FIG. 4, the power supply circuit 30 is supplied with an input voltage VIN. In the device 10, IN is a device stop control port. OUT is a power stop signal port. In the start / stop control circuit 20, OUT is a power supply stop control port. The output port of the voltage monitoring circuit 21 is described as ON_OFF. The start / stop control circuit 20 further includes a SWCONT port and VCC_C23. The SWCONT port is a port that controls the SW 54 of the adjustment circuit 50. VCC_C23 receives an external VIN_C signal.

  The adjustment circuit 50 includes three resistors R, a SW 54, and a filter 55. R1 and R2 are connected in series and connect the output voltage of the power supply circuit 30 and the ground. R3, SW54, and filter 55 are connected in series. When the SW 54 is turned on by a signal from the SWCONT port, the adjustment circuit 50 connects the voltage control signal port of the start / stop control circuit 20 and the Feed Back port of the power supply circuit 20. Here, the filter 55 performs noise removal / smoothing of the signal. When the switch 54 is OFF, the adjustment circuit 20 is kept at a high impedance when viewed from the power supply circuit 20. R1 to R3 divide the voltage.

  With reference to FIG. 5, a startup waveform in which the power supply circuit 30-A is started up first and then the power supply circuit 30-B is started up in the power supply system 100A will be described. The power supply circuit 30 has a current source (supply) / sink (suction) function.

  In FIG. 5, for activation, VIN and VIN_C are input to the input of the power supply circuit 30 and the VCC_C 23 of the activation / stop control circuit 20, respectively. The operation of the power supply circuit 30 is performed by operating the start / stop control circuit 20 in order to ensure that the interlocking power supply circuit is not selected and that the power supply circuit 30 is started and stopped from 0V without fail. -Control start / stop of A. At startup, an activation signal is transmitted from ON_OFF_A to the activation / deactivation port of the power supply circuit 30-A. The power supply circuit 30-A receives the activation signal and supplies a voltage from the OUTPUT port to the load circuit 11-A of the device 10.

  The OUTPUT port is monitored by the voltage monitoring circuit 21 -A of the start / stop control circuit 20. When the voltage threshold value set in advance is reached, the voltage monitoring circuit 21-A determines that the output voltage is OK. Next, a start signal is transmitted from ON_OFF_B of the start / stop control circuit 20 to the start / stop port of the power supply circuit 30-B. The power supply circuit 30 -B receives the activation signal and supplies a voltage from the OUTPUT port to the load circuit 11 -B of the device 10. The OUTPUT port is monitored by the voltage monitoring circuit 21 -B of the start / stop control circuit 20. When the voltage threshold value set in advance is reached, the voltage monitoring circuit 21-B determines that the output voltage is OK and ends the start-up control.

  With reference to FIG. 6, a waveform when the power supply circuit 30 -A is not normal in the power supply system 100 </ b> A will be described. In FIG. 6, the power supply circuit 30 -A is activated by setting the ON / OFF_A output of the activation / stop control circuit 20 to High. After outputting the start signal, the start / stop control circuit 20 monitors the voltage at the OUTPUT port of the power supply circuit 30 by the voltage monitoring circuit 21-A. However, since the OUTPUT port does not satisfy the voltage set in advance during the voltage determination (S13) of the startup flow shown in FIG. 2, the startup / stop control circuit 20 sets the ON_OFF_A signal to the stop state, and the power supply circuit 30- The start control of B is not performed and the stop state is set. The start / stop control circuit 20 protects against damage to the device 10 due to a start sequence violation.

  With reference to FIG. 7, in the power supply system 100A, a stop waveform for stopping the power supply circuit 30-A first and then stopping the power supply circuit 30-B will be described. The power supply circuit has a current source (supply) / sink (suction) function.

  In FIG. 7, when starting the stop sequence, transmission is performed to the device 10 that performs the stop process using an OFF switch provided in an apparatus that uses the device 10. The device 10 has a program for performing a processing flow for performing stop processing in advance. When the device 10 receives the stop signal, the device 10 performs stop control. In the stop control, the device function and I / O are stopped, and the device 10 is shifted to the function stop. This is because, for the load circuit 11-A and the load circuit 11-B, the load fluctuation of the device 10 is eliminated during power supply stop control, and the load is made constant. After making the load constant, the device 10 is shifted to a power supply stop sequence. Next, by stopping the power supply circuit 30, it becomes possible to always perform a stop process under the same conditions, and it is possible to eliminate the influence of component variations and device conditions.

  After the transition to the function stop state, the device 10 transmits a stop signal to the start / stop control circuit 20. The start / stop control circuit 20 receives the stop signal and starts power supply stop control of the power supply circuit 30.

  First, the start / stop control circuit 20 sends an adjustment voltage (V_CONT_A) from the voltage control signal port A. At the same time, the start / stop control circuit 20 sets the output of the SWCONT port A to High. As a result, the SW 54 -A is ON-controlled through the filter 55 -A, and a voltage is applied to R 3 of the adjustment circuit 50 -A.

  The adjustment circuit 50 is a circuit for controlling the output voltage of the power supply circuit 30 from the outside. By using the adjustment circuit 50, the output voltage of the power supply circuit 30 can be reduced below the rated voltage. In the normal state, the voltage obtained by dividing the OUTPUT port of the power supply circuit 30-A by R1 and R2 is returned to the Feed Back, and the power supply circuit 30-A is adjusted so that the Feed Back voltage becomes constant. On the other hand, when stopping, a voltage is applied to R3 and the output voltage is adjusted to 0.7V or less.

  For this reason, by performing control to forcibly increase the voltage of Feed Back, it is determined that the output voltage has increased in the power supply circuit 30-A, and processing for decreasing the output voltage is performed. By forcibly lowering the voltage in this way, it is possible to reliably realize the stop sequence without being affected by the load and without causing reverse rotation of the stop sequence due to the influence of variations in peripheral parts.

  Next, the voltage monitoring circuit 21-A of the start / stop control circuit 20 monitors the voltage of the OUTPUT port. When the voltage becomes equal to or lower than the target value, a stop signal is sent from ON_OFF_A, and the power supply circuit 30-A Stop function. After the power supply circuit 30-A stops functioning, the start / stop control circuit 20 stops outputting the adjustment voltage from the voltage control signal A. Further, the start / stop control circuit 20 performs the OFF control of the SW 54-A and disconnects the circuit so that the set voltage does not become abnormal during the steady operation.

After the power supply circuit 30-A is stopped, the power supply circuit 30-B is stopped. The stop control of the power supply circuit 30-B is the same as the stop control method of the power supply circuit 30-A, and is omitted here. The stop sequence control is thus completed.
When the power supply circuit 30-B is started up first and then the power supply circuit 30-A is started up, the same operation can be performed when the power supply circuit 30-B is stopped first and then the power supply circuit 30-A is stopped. is there.

  In the first embodiment and the second embodiment, the power supply sequence control in the case where there are two power supply types is shown. In the third embodiment, a case where one device requires n power supply circuits will be described. In FIG. 8, the power supply system 100 </ b> B includes n power circuits, n adjustment circuits, a start / stop control circuit, and a device 10. For a device 10 that requires a power supply sequence, n power supply circuits for device supply and a voltage adjustment circuit 50 and a start / stop control circuit 20 at the output part of each power supply circuit 30 are set in advance. The start and stop sequences are realized in the same procedure as described in the first embodiment.

  According to the above-described embodiment, the start / stop sequence can be realized, and the start / stop power sequence can be protected without being affected by the indefinite load state of the device and the stop time due to component variations. Damage to the load) can be prevented.

  DESCRIPTION OF SYMBOLS 10 ... Device, 11 ... Load circuit, 20 ... Start / stop control circuit, 21 ... Voltage monitoring circuit, 23 ... VCC_C, 30 ... Power supply circuit, 50 ... Voltage adjustment circuit, 54 ... SW (switch), 100 ... Power supply system .

Claims (5)

A power supply circuit control device that is connected to a feedback input of a power supply circuit and controls an output of the power supply circuit,
The power supply circuit control device, wherein when stopping the power supply circuit, the output voltage to the feedback input is increased, and after the output voltage of the power supply circuit is lowered, the output of the telephone circuit is stopped. The power supply circuit control device according to claim 1,
A power supply circuit control device connected to a first power supply circuit and a second power supply circuit, and controlling a starting order of the first power supply circuit and the second power supply circuit. The power supply circuit control device according to claim 1,
A power supply circuit control device, connected to a first power supply circuit and a second power supply circuit, for controlling a stop order of the first power supply circuit and the second power supply circuit. The power supply circuit control device according to claim 1,
It consists of an adjustment circuit and a control circuit,
The adjustment circuit increases the output voltage to the feedback input when stopping the power supply circuit,
The said control circuit stops the output of the said telephone circuit, after reducing the output voltage of the said power supply circuit, The power supply circuit control apparatus characterized by the above-mentioned. Monitoring the output voltage of the power circuit;
Increasing the feedback input voltage of the power supply circuit;
Confirming that the output voltage is less than a predetermined voltage;
Stopping the power supply circuit, and stopping the power supply circuit.

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