JP2003295979A - Power-supply voltage monitoring control system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power-supply voltage monitoring control system in which a power-supply voltage assumes a stable state constantly. <P>SOLUTION: Each of a master card 2 and slave cards 4 to 13 monitors the power-supply voltage. The master card 2 checks the power-supply voltage of every card in a device. If the power-supply voltage value of a certain card is lower than a lower limit of a rated power-supply voltage, the master card exercises power-supply voltage control of a power-supply card 3, thereby maintaining the power-supply voltage which is equal to or above the lower limit, and each card is provided with a circuit for preventing the upper limit of the rated power-supply voltage from being exceeded, so that the upper limit of the rated power-supply voltage is maintained. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a communication device and a control device having a power supply unit and a plurality of circuit boards,
In particular, it relates to a system for monitoring and controlling the power supply voltage in the device.

[0002]

2. Description of the Related Art Generally, in a communication device, a control device, etc., in which a power supply unit and a circuit board are mounted, and the circuit board is supplied with a power supply voltage output from the power supply unit to operate.
The control of the power supply voltage supplied to the circuit board is performed by controlling the power supply voltage and correcting it so that it is within the predetermined range when the monitored power supply voltage is out of the range from the predetermined upper limit value to the lower limit value. Done. An example of a conventional power supply voltage monitoring / control system is a power supply voltage control system disclosed in Japanese Patent Laid-Open No. 64-76104.

According to Japanese Unexamined Patent Publication No. 64-76104, the power supply voltage supplied from the power supply unit is monitored, and when the voltage is out of the predetermined voltage range, the voltage is corrected and brought into the predetermined voltage range. A power supply voltage control system is disclosed in which there is no secondary trouble due to the device stopping halfway without going out of the voltage range.

In this conventional power supply voltage control system, the voltage supplied from the power supply unit is divided by the resistance in the control circuit that is the target of the power supply voltage monitoring, and converted into a digital value by the A / D converter. And then read by the CPU. The CPU compares the read digital value with a value in a predetermined voltage range, recognizes that it is in a normal state when it is within the range, and controls the output to the power supply unit when it is out of the range. It is to put it within a predetermined voltage range.

[0005]

However, in the above-mentioned conventional power supply voltage control system, the power supply voltage supplied from the power supply unit is monitored and controlled so that the voltage does not deviate from the predetermined range. For example, when the power supply voltage output from the power supply unit is supplied to a plurality of cards (circuit boards) as seen in a mobile communication base station device, the power is supplied to a specific card or an observation point as a monitoring target. Even if the power supply voltage output of the unit is controlled so that the voltage at the monitored location falls within the specified range, the power supply voltage supplied to the non-monitored card may fall outside the specified range. .

This is because there is a voltage drop due to the propagation loss of the transmission line from the power supply unit to the card, so that the voltage supplied to each card differs depending on the mounting position, and that each card is different. This is because the current consumption of each card differs due to the difference in the circuit configuration of the card and the difference in the data processing load.For example, the power supply voltage output of the power supply unit is changed for a specific card. If this happens, the power supply voltage of other cards may exceed the upper limit value or the lower limit value. Therefore, even if some of the cards have an improper power supply voltage, the operation of the system is not stable.

Further, since the conventional power supply voltage control system only controls so that the voltage does not deviate from the predetermined range, the power supply voltage is controlled even when the substrate is abnormal and the power supply voltage is abnormally lowered. There was a problem that the abnormality could not be detected due to the raising control.

Therefore, an object of the present invention is to solve these problems, to provide a system in which the power supply voltage is always stable, and to provide a system capable of detecting and notifying the occurrence of an abnormality in the power supply voltage. It is to be.

[0009]

A power supply voltage monitoring and control system of the present invention comprises a power supply unit and a plurality of circuit boards, wherein the power supply unit supplies power to the plurality of circuit boards. For each of the circuit boards
Input means for inputting the power supplied from the power supply unit to supply power to the circuit board, comparing means for reading the voltage value of the power supply supplied by the input means and comparing it with a predetermined lower limit voltage value, and the power supply unit And a means for limiting the voltage of the power source supplied from a predetermined upper limit voltage value, and when any one of the comparison means of the plurality of circuit boards detects a voltage value lower than the predetermined lower limit voltage value. It is characterized by comprising means for increasing the power supply voltage of the power supply supplied by the power supply unit.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

The configuration of the first embodiment of the present invention is shown in FIG. Referring to FIG. 1, a master card, which is a circuit board for monitoring and controlling the inside of the mobile communication base station device 1, is provided.
Mounted are the slave cards 4 to 13 which are circuit boards for communication between the card 2 and the mobile communication terminal, and a power supply card which is a power supply unit for supplying a power supply voltage to each of the circuit boards. Here, the number of slave cards is 10, but the number of mounted boards may be changed as necessary.

Master card 2 and slave card 4 to
Transmission / reception of data between 13 is performed through the system bus 14. The system bus 14 is composed of a data bus and an address bus having an arbitrary bus width, and is connected to each of the master card 2 and the slave cards 4 to 13.

Further, there is a voltage control signal line 15 between the master card 2 and the power supply card 3, and a control signal is output from the master card 2 to the power supply card. The power supply voltage transmission line 16 is a line for supplying the power supply voltage output from the power supply card 3, and the power supply voltage is supplied from the power supply card 3 to the master card 2 and the slave cards 4 to 13. .

Further, an external input power line 17 is connected to the power supply card 3 for supplying power from the outside of the mobile communication base station device 1, and is required in the mobile communication base station device 1. The power supply voltage is generated by the power supply card 3.

Next, the structure of the master card 2 will be described with reference to FIG. In the master card 2, a CPU 23 used for monitoring control processing in the mobile communication base station device 1 is mounted. The CPU 23 has a system bus 14, a flash memory 24 in which a program for driving the master card 2 and a lower limit value of a predetermined rated voltage in the card operation are written, the master card 2 and a slave card.
Voltage control signal obtained by converting the digitalized voltage value reported from the corresponding card into an analog value when any one of the cards 4 to 13 falls below the lower limit value of the predetermined rated voltage in the card operation. A D / A converter 22 for outputting to the signal line 15 and a power supply voltage monitoring circuit 19 for monitoring the power supply voltage are connected. The power supply voltage monitoring circuit 19
The A / D converter 20 for converting the power supply voltage input from the power supply voltage transmission line 16 into a digital value and the power supply voltage input from the power supply voltage transmission line 16 exceed the upper limit of a predetermined rated voltage in card operation. It is composed of a diode 21 for voltage clipping for limiting the voltage.

The configuration of the slave card 4 will be described with reference to FIG. The other slave cards 5 to 13 have the same construction as the slave card 4. In the slave card 4, a CPU 25 mainly for controlling transmission / reception of data to / from a mobile communication terminal is mounted. The CPU 25 has a system bus 14
A flash memory 26 in which a program for driving the slave card 4 and a lower limit value of a predetermined rated voltage in the card operation are written, and a power supply voltage monitoring circuit 19 for monitoring the power supply voltage are connected. There is. The power supply voltage monitoring circuit 19 includes an A / D converter 20 for converting the power supply voltage input from the power supply voltage transmission line 16 into a digital value and a power supply voltage input from the power supply voltage transmission line 16 to a predetermined rating in card operation. It is composed of a voltage clipping diode 21 for limiting the voltage from exceeding the upper limit value.

The configuration of FIGS. 2 and 3 of the present embodiment is provided with the voltage clip diode 21 as a means for limiting the upper limit value of the predetermined rated voltage. Other circuits may be provided in place of the voltage clipping diode 21 as long as the upper limit can be restricted.

The structure of the power supply card 3 will be described with reference to FIG. A D / D converter 27 is mounted in the power supply card 3. The D / D converter 27 includes an external input power supply line 17, a power supply voltage transmission line 16, and a voltage control signal line 1.
5 is connected. The power supply voltage supplied from the external input power supply line 17 is converted by the D / D converter 27 into the power supply voltage used in the mobile communication base station device 1 and output to the power supply voltage transmission line 16. The output power supply voltage value is variable by the voltage control signal from the master card 2 input from the voltage control signal line 15.

The operation when the power supply voltage supplied to the slave cards 4 to 13 is below the lower limit of the predetermined rated voltage in the card operation will be described with reference to the operation flow chart of FIG. Here, the control of the power supply voltage of the slave cards 4 to 13 will be described, but the control of the power supply voltage of the master card 2 itself is the same internal processing.

The master card 2 is a slave card 4-1.
In order to confirm the value of the power supply voltage supplied to No. 3, the voltage status report request is output to the slave cards 4 to 13 (step 100). The confirmation timing may be a fixed cycle or may be set and changed for each card depending on the load of the card. When the slave cards 4 to 13 receive the voltage status report request, the slave cards 4 to 13 investigate whether the power supply voltage supplied to each is below the lower limit value. In this investigation, the CPU 25 reads the power supply voltage converted into the digital value output from the A / D converter 20 (step 101), and the value of the read power supply voltage and the flash memory 26 are written in advance. Digital value (car
(The lower limit value of the rated voltage in the operation mode) is compared (step 102).

At this time, if the value output from the A / D converter 20 is smaller than the digital value read from the flash memory 26, the power supply voltage for the master card 2 is below the lower limit value (voltage lower limit). It is in a value excess state) and the difference between the value output from the A / D converter 20 and the recommended value of the card operating power supply voltage is reported as a digital value (step 103). Here, the recommended value of the card operating power supply voltage is a value between the lower limit value and the upper limit value of the rated voltage, which is written in the flash memory 26 in advance, and is a value set appropriately by the device. However, in the flow of FIG. 5, the median of the lower limit and the upper limit is set as the center value. If the voltage lower limit value is not exceeded,
The master card 2 is notified that the power supply voltage lower limit value is not exceeded (step 104).

The CPU 23 of the master card 2 recognizes from the voltage status reports from the slave cards 4 to 13 that, for example, the power supply voltage of the slave card 4 is in the state of exceeding the lower limit voltage (step 105). ), The digital value of the difference from the voltage value from the A / D converter 20 reported from the slave card 4 to the center value of the power supply voltage in the card operation is sent to the D / A converter 22. Output (step 106). When a plurality of slave cards report that the voltage lower limit is exceeded, for example, the largest digital value reported is the D / A converter.
The data may be output to the data 22.

Next, the D / A converter 22 has a CPU 23.
The digital value input from is converted into an analog value and output to the voltage control signal line 15 (step 107). The analog value output to the voltage control signal line 15 is input to the D / D converter 27 in the power supply card 3 to control the power supply voltage. By this control of the power supply voltage, for example, when the slave card 4 reports that the power supply voltage lower limit is exceeded, the slave card 4 is supplied with the power supply voltage having the rated center value. It will be. At this time,
By controlling the power supply voltage of the power supply card 3, the power supply voltage supplied to the master card 2 and other slave cards 5 to 13 naturally rises. Due to this increase, the power supply voltage in the card of any of the slave cards may exceed the upper limit of the rated power supply voltage in the card operation. But,
Since each card is equipped with a voltage clipper diode that limits the upper limit value of the rated voltage in the card operation, the upper limit value of the rated voltage in the card operation is not exceeded. .

The master card 2 also confirms its own power supply voltage. The CPU 23 in the master card 2 compares the power supply voltages by the same operation as the CPU 25 in the slave card described above, but the confirmation timing may be the same as that of the slave card, or only the master card 2 may be used. You can change the timing, such as making it frequent.

In the flow of FIG. 5, the above operation is repeated.

When the mobile communication base station apparatus 1 is activated, for example, the CPU 23 of the master card 2 sets the initial setting value (the factory configuration of the mobile communication base station apparatus 1 in the maximum configuration state with no load). At some time, the digital value adjusted so that the power supply voltage of the slave card 13 becomes the center value of the power supply voltage in the card operation is read from the flash memory 24 and output to the D / A converter 22. To do.

FIG. 6 shows an operation flow of the second embodiment of the present invention. The configuration diagram is the same as that in FIGS.

In the second embodiment of the present invention, when the power supply voltage in the card becomes lower than the voltage value (abnormal value) preset to a value lower than the lower limit value,
It is determined that the card is in an abnormal state, and the control that raises the power supply voltage of the power supply card 3 is not performed based on the voltage value of the card that outputs the abnormal voltage value, and which card outputs the abnormal voltage value. I have notified you. The above-mentioned abnormal voltage value is written in the flash memory 26 in advance like the lower limit value. Others are the same as those in the first embodiment described above, and steps 100 to 107 of FIG. 6 are the same as steps 100 to 107 of FIG.

The operation flow added in the second embodiment will be described with reference to FIG. 6. When it is determined in step 102 that the voltage lower limit value is exceeded, the CPU 25 further causes the A / A The value of the power supply voltage output from the D converter 20 is compared with the abnormal voltage value previously written in the flash memory 26 (step 110).

At this time, when the value output from the A / D converter 20 is smaller than the abnormal voltage value read from the flash memory 26, the power supply voltage for the master card 2 is below the abnormal voltage value ( It is reported that the voltage is abnormal (step 111).

The CPU 23 of the master card 2 recognizes from the voltage status reports from the slave cards 4 to 13 that the power supply voltage of any one of the slave cards is in an abnormal voltage state (step). 112), and notifies that the slave card that has reported the abnormal voltage state is abnormal. Based on this notification, the power supply card 3 is not controlled.

Regarding the notification, the CPU 23 may send it to a display panel or the like and display it on the display panel or the like with an LED, a lamp, a buzzer or the like, or send it to another control device or the like as abnormal data information. Good too.

[0033]

As described above, the power supply voltage monitoring and controlling system of the present invention has a master card and a slave card.
If the power supply voltage of one of the cards drops,
By controlling the power supply voltage output from the power supply card according to the value obtained by monitoring the power supply voltage, it is possible to prevent the voltage of the master card and the slave card from falling below the lower limit value of the predetermined range. it can.

Further, since the power supply voltage monitoring and control system according to the present invention is equipped with the clipper diode in the master card and the slave card, the voltage is prevented from exceeding the upper limit of the predetermined range. Therefore, the voltage of the master card and the slave card can be kept within a predetermined range.

Further, in the power supply voltage monitoring control system according to the present invention, the power supply voltage of either the master card or the slave card is lower than the preset voltage value lower than the lower limit value. It is possible to detect that something has happened and notify the abnormality of the system.

[Brief description of drawings]

FIG. 1 is a configuration diagram of an apparatus according to a first embodiment of the present invention.

FIG. 2 is a configuration diagram of a master card according to the first embodiment of the present invention.

FIG. 3 is a slaver according to the first embodiment of the present invention.
FIG.

FIG. 4 is a configuration diagram of a power supply card according to the first embodiment of the present invention.

FIG. 5 is a diagram showing an operation flow of the device according to the first embodiment of the present invention.

FIG. 6 is a diagram showing an operation flow of the device according to the second embodiment of the present invention.

[Explanation of symbols]

1 Mobile communication base station equipment 2 Mastercard 3 power card 4 to 13 slave cards 14 system bus 15 Voltage control signal line 16 power supply voltage transmission line 17 External input power line 19 Power supply voltage monitoring circuit 20 A / D converter 21 Diode for voltage clipping 22 D / A converter 23 CPU 24 flash memory 25 CPU 26 Flash memory 27 D / D converter

Claims (10)

[Claims] 1. A device having a power supply unit and a plurality of circuit boards, wherein the power supply unit supplies power to the plurality of circuit boards, wherein each of the plurality of circuit boards is supplied from the power supply unit. Input means for inputting power and supplying power to the circuit board, comparing means for reading the voltage value of the power supplied by the input means and comparing it with a predetermined lower limit voltage value, and voltage of the power supplied from the power supply unit And a means for limiting the voltage to a predetermined upper limit voltage value, and when any one of the comparison means of the plurality of circuit boards detects a voltage value lower than the predetermined lower limit voltage value, the power supply unit supplies power. A power supply voltage monitoring and control system comprising means for increasing the power supply voltage. 2. The input means converts the voltage value power source of the power source supplied from the power source unit into a digital value and outputs the digital value to the comparing means, and the comparing means outputs the digital value as the predetermined lower limit which is a digital value. The power supply voltage monitoring control system according to claim 1, which is compared with a voltage value. 3. A master card, which is one of the plurality of circuit boards, detects a voltage value lower than the predetermined lower limit voltage value from the comparison means of a slave card, which is another circuit board. 3. The notification is sent, and the master card notifies the power supply unit that any one of the comparison means detects a voltage value lower than the predetermined lower limit voltage value. 2. A power supply voltage monitoring control system according to item 1. 4. The power supply voltage monitoring control according to claim 3, wherein the notification from the slave card to the master card is performed through a system bus of a CPU connected to each of the slave card and the master card. system. 5. The master card is provided with a D / A converter, and the notification from the slave card to the power supply unit is performed by an analog signal converted by the D / A converter. The power supply voltage monitoring control system according to claim 3 or 4. 6. The comparing means compares the voltage value obtained by reading the voltage value of the power source supplied by the input means with a predetermined low voltage value lower than the predetermined lower limit voltage value, and comparing the voltage value with the predetermined low voltage value. 2. The power supply voltage monitoring control system according to claim 1, further comprising a notification means for notifying when a low voltage value is detected. 7. The input means converts a voltage value power source of the power source supplied from the power source unit into a digital value and outputs the digital value to a comparing means, and the comparing means outputs the digital value as the predetermined lower limit which is a digital value. 7. The power supply voltage monitoring control system according to claim 6, wherein a comparison is made with a voltage value or the predetermined lower limit voltage value and the predetermined low voltage value. 8. A voltage lower than a predetermined lower limit voltage value or a predetermined lower voltage value is applied to a master card, which is one of the plurality of circuit boards, from the comparison means of a slave card, which is another circuit board. You are notified that you have detected the value,
8. The master card notifies the power supply unit that any one of the comparison means detects a voltage value lower than the predetermined lower limit voltage value. The power supply voltage monitoring and control system described. 9. The power supply voltage monitoring control according to claim 8, wherein the notification from the slave card to the master card is performed through a system bus of a CPU connected to each of the slave card and the master card. system. 10. The master card is provided with a D / A converter, and the notification from the slave card to the power supply unit is performed by an analog signal converted by the D / A converter. The power supply voltage monitoring control system according to claim 8 or 9.