JPH10187555A - Power circuit of storage device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To simplify the hardware of a computer device by setting an alarm mode and generating an alarm if a power failure occurs to a power unit for a time which is long enough to cause the contents of a semiconductor memory device to change. SOLUTION: This device is equipped with a control part 7 for a battery device 3 as a means which sets the alarm mode and displays a flag 9 as an alarm if a power failure occurs to the power unit 4 for a time (t1 ) which is long enough to cause the contents of the semiconductor memory device 2 to change. This control part 7 switches the semiconductor memory device 2 to a stand-by mode if the power failure occurring to the power unit 4 lasts exceeding the specific time (t2 , t2 <t1 ) and inhibits the semiconductor memory device 2 from being accessed in stand-by mode. When the power unit 4 recovers from the power failure in alarm mode, the semiconductor memory device 2 is initialized. Further, when the power of a battery can be supplied, the flat 9 is set OFF through a signal line 16 and when not, the flag 9 is set ON.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention is applied to a computer device. The present invention is suitable for use in an exchange. Although the present invention has been developed for use in a computer device for controlling an exchange, it can be widely applied to other uses.

[0002]

2. Description of the Related Art A conventional computer device provided in an exchange has a semiconductor memory device for storing data during normal times and a magnetic disk device for storing data when a power failure occurs.

When the power is turned off due to an unexpected situation, the power is detected and the data is automatically transferred from the semiconductor memory device to the magnetic disk device.

[0004] This conventional example will be described with reference to FIG. FIG. 3 is a block diagram of a conventional computer device.
When the supply of the input power supply 10 is normal, power is supplied from the power supply 4 to each device via the power lines 24 and 25.

When the supply of the input power supply 10 is stopped, the power supply unit 4 detects this and notifies the control unit 7 of the battery unit 3 via the signal line 14. The control unit 7 instructs the battery unit 8 to supply power from the battery via the signal line 15. Battery unit 8 discharges the power of the battery to power line 25. Further, the control unit 7 controls the semiconductor memory device 2 via the signal line 18.
Is instructed to save the data to the storage unit 23 of the magnetic disk device 21. The control unit 5 reads data from the storage unit 6 via the signal line 19 and
6 to the control unit 22 of the magnetic disk drive 21, and the control unit 22 sends the data to the storage unit 2 via a signal line 27.
Write data to 3. When all the information has been transferred from the storage unit 6 of the semiconductor memory device 2 to the storage unit 23 of the magnetic disk device 21, the backup process ends. The battery unit 8 supplies power during this time.

[0006]

As described above, conventionally, a magnetic disk device is used as a secondary storage device. However, since a magnetic disk device has a low writing and reading speed, it is necessary to use a high throughput. Takes time. In addition, complicated software is required to transfer data between the semiconductor memory device and the magnetic disk device. Further, the magnetic disk drive has a mechanical drive mechanism, and has a high failure rate due to consumption of movable parts.
Further, time is required for maintenance and inspection such as periodic cleaning of the magnetic head.

As described above, a computer device having a semiconductor memory device and a magnetic disk device is complicated in both hardware and software, and the device cost is high. Further, the life of the device is shortened depending on the consumption of the movable parts. In addition, power consumption is large due to having a mechanical drive mechanism.

Therefore, it is desired to realize a computer system for controlling an exchange, which is equipped with only a semiconductor memory device.

The present invention has been made under such a background, and an object of the present invention is to provide a power supply circuit of a storage device capable of simplifying hardware of a computer device. An object of the present invention is to provide a power supply circuit of a storage device that can simplify software of a computer device. SUMMARY OF THE INVENTION It is an object of the present invention to provide a power supply circuit of a storage device that can reduce the time required for maintenance and inspection of a computer device. SUMMARY OF THE INVENTION It is an object of the present invention to provide a computer device having a high writing and reading speed. An object of the present invention is to provide a computer device having a high throughput. An object of the present invention is to provide a computer device with low power consumption.

[0010]

According to the present invention, data is protected by backing up only a storage section of a semiconductor memory device using a battery device. If the battery section has sufficient capacity to supply power for a certain period of time or more, data can be retained in this configuration, but the power interruption time is long and the power interruption time is long. If the compensation time of the device is exceeded, the reliability of the contents of the storage unit of the semiconductor memory device is not guaranteed, so that the storage unit of the semiconductor memory device needs to be initialized when power is restored. To determine this, a flag is provided to indicate whether or not the reliability of the content of the storage unit of the semiconductor memory device is guaranteed, and whether or not to perform initialization is controlled by the content of this flag. Data in a storage unit of a semiconductor memory device is held with high reliability.

[0011] Thus, in the event of a short-term power failure, a backup battery device is provided to make the semiconductor memory device non-volatile, so that a highly reliable system can be constructed economically. Even if the power failure is prolonged,
Since it is determined whether or not the reliability of the contents in the semiconductor memory device is guaranteed, there is no occurrence of an error due to the initialization processing after the power is restored, and the software control is simplified.

The highly-reliable semiconductor memory device configured as described above completely retains data in the semiconductor disk storage unit in response to a short-term power failure, and completely resets the semiconductor memory device in response to a long-term power failure. As it can, it keeps trusted data and works to completely eliminate untrusted data.

That is, the present invention is a power supply circuit of a storage device including a power supply for supplying power to a semiconductor memory device and an auxiliary device using a battery provided as a backup power supply for a power failure of the power supply. A feature of the present invention is that the power supply device has a means for setting an alarm mode and generating an alarm when a power failure occurs for a long time (t ₁ ) in which a change in the content of the semiconductor memory device can occur. It is in the prepared place.

A predetermined time (t ₂ , t ₂ <t) is applied to the power supply device.
It is desirable to include means for changing the semiconductor memory device to the standby mode when a power failure exceeding ₁ ) occurs, and means for inhibiting access to the semiconductor memory device in the standby mode.

It is preferable that the semiconductor memory device includes means for initializing the semiconductor memory device when the power failure of the power supply device is restored in the alarm mode.

This makes it possible to avoid using the data whose reliability has been degraded as it is when the power is restored.

The semiconductor memory device is a device for storing important information such as, for example, location information for a mobile phone service.

[0018]

BEST MODE FOR CARRYING OUT THE INVENTION

[0019]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described with reference to FIG. FIG. 1 is a block diagram of a computer device according to an embodiment of the present invention.

The present invention relates to a power supply for a storage device including a power supply device 4 for supplying power to the semiconductor memory device 2 and a battery device 3 provided as a backup power supply for a power failure of the power supply device 4 as an auxiliary device using a battery. Circuit.

Here, the feature of the present invention is that when a power failure occurs in the power supply device 4 for a long time (t ₁ ) in which the contents of the semiconductor memory device 2 can change,
There is provided a control unit 7 of the battery device 3 as a means for setting an alarm mode and displaying a flag 9 as an alarm.

The control unit 7 changes the semiconductor memory device 2 to a standby mode when a power failure occurs for a predetermined time (t ₂ , t ₂ <t ₁ ) in the power supply device 4. Prohibit access. When the power failure of the power supply 4 is restored in the alarm mode, the semiconductor memory device 2 is initialized.
This semiconductor memory device 2 is a device that stores the location information for a mobile phone service.

The embodiment of the present invention is used for a mobile telephone service exchange. The storage unit 6 stores customer data. The customer data is location information of the mobile phone, and is data that changes and updates every moment. The current storage capacity is 256 Mbytes and will be expanded to 512 Mbytes in the future. Furthermore, as technology advances, 1
It is expected to be extended from G bytes to 2 G bytes. Further, the backup time of the battery unit 8 is 24 hours, which is a sufficient backup time in view of recent power supply circumstances.

Due to recent power supply circumstances, the time when the power may be cut off is almost instantaneous time of 1 second or less in most cases, and is about several minutes even if it is long. Also, from the nature of the data, the location information of the mobile phone changes every moment as the mobile phone carrier moves, and the data that has passed one or two hours is the actual location status. It can be said that the data is quite far from the data. Therefore, it is understood that the capacity of the battery unit 8 has a very large margin.

Next, the operation of the embodiment of the present invention will be described with reference to FIG. FIG. 2 is a flowchart showing the operation of the control unit 5 of the semiconductor memory device 2 when the power is restored. When the supply of the input power supply 10 is normal, power is supplied to each unit via the power lines 12 and 13 (normal mode). When the supply of the input power supply 10 is stopped, the power supply device 4 detects that the input voltage from the input power supply 10 has dropped below a certain voltage, and controls the control unit 7 of the battery device 3 via the signal line 14.
To that effect. The control unit 7 instructs the battery unit 8 to supply power from the battery via the signal line 15, and notifies the control unit 5 of the semiconductor memory device 2 via the signal line 18 to shift to the backup state. I do. The battery unit 8 supplies power to the control unit 7 and the storage unit 6 of the battery device 3 via the power line 13 (standby mode).

The control unit 7 of the battery device 3 includes a signal line 15
Is read whether the battery unit 8 can supply the electric power of the battery via. The determination as to whether or not the battery can be supplied with power is made by detecting the battery voltage, discharge time, discharge current, and the like by the control unit 7. When the power of the battery can be supplied, the flag 9 is turned off via the signal line 16 (standby mode), and when the power cannot be supplied, the flag 9 is turned on (alarm mode). The flag is displayed by switching the voltage between positive and negative, but other general methods such as turning on and off a relay can be used.

When the input power supply 10 is restored, the semiconductor memory device 2 shifts to the initialization mode as shown in FIG.
By writing the procedure of the initialization mode in the control unit 5 of the semiconductor memory device 2 by the ROM, the initialization mode can be started at the same time when the power is restored.

When the power is restored, the control unit 5 of the semiconductor memory device 2 initializes itself (S1). Subsequently, the contents of the flag 9 are checked via the signal line 17 (S2).
If it is off, it is in the standby mode (S3),
It is determined that the contents of the storage unit 6 are normal, and the initialization mode ends. As a result, the contents of the storage unit 6 are restored to the state before the power was turned off. As a result, the exchange recovers to the normal mode, controls the mobile phone service in accordance with the data remaining in the storage unit 6 before the power is turned off, and updates the data in the storage unit 6 with newly arrived data. Do.

If the flag 9 is turned on, it is in the alarm mode (S3), it is determined that the reliability of the storage contents of the storage unit 6 cannot be guaranteed, and the storage unit 6 is initialized (S4). . As a result, the exchange recovers to the normal mode, writes the newly arriving data into the storage unit 6, and controls the mobile phone service according to the data.

In FIG. 1, the flag 9 is provided in the battery device 3, but may be provided in the semiconductor memory device 2. The present invention is not limited by the installation location of the flag 9.

According to the embodiment of the present invention, it is not necessary to separately provide a non-volatile storage device such as a magnetic disk device which takes a long time to read / write in response to a short-time power supply failure. It is possible to determine whether or not the reliability of the contents in the semiconductor memory device 2 is guaranteed even if the power failure is prolonged. Along with the processing, the data in the storage unit 6 is not accidentally erased, and the data in the storage unit 6 is useless during a long power outage, so that the data can be erased, so that the software control is simplified. Thus, a highly reliable system can be provided economically.

[0032]

As described above, according to the present invention,
The hardware and software of the computer device can be simplified, and the time for maintenance and inspection can be reduced. Further, according to the present invention, it is possible to realize a computer device with high writing and reading speed, high throughput, and low power consumption.

[Brief description of the drawings]

FIG. 1 is a block diagram of a computer apparatus according to an embodiment of the present invention.

FIG. 2 is a flowchart showing the operation of the control unit of the semiconductor memory device when the power is restored.

FIG. 3 is a block diagram of a conventional computer device.

[Explanation of symbols]

 Reference Signs List 1 processor 2 semiconductor memory device 3 battery device 4 power supply device 5, 7, 22 control unit 6, 23 storage unit 8 battery unit 9 flag 10 input power supply 11 to 13, 24, 25 power line 14 to 20, 26, 27 signal line 21 Magnetic disk drive

Claims (4)

[Claims] 1. A power supply circuit for a storage device comprising: a power supply for supplying power to a semiconductor memory device; and a battery-assisted auxiliary device provided as a backup power supply for a power failure of the power supply. A power supply circuit for a storage device, comprising: means for setting an alarm mode and generating an alarm when a power failure occurs for a long time (t ₁ ) in which a change in the content of the memory device can occur. 2. The power supply device is supplied with a predetermined time (t ₂ , t ₂ <
2. The power supply circuit for a storage device according to claim 1, further comprising: means for changing a semiconductor memory device to a standby mode when a power failure exceeding t ₁ ) occurs, and means for inhibiting access to the semiconductor memory device in the standby mode. 3. The power supply circuit for a storage device according to claim 1, further comprising means for initializing said semiconductor memory device when the power failure of said power supply device is restored in the alarm mode. 4. The power supply circuit for a storage device according to claim 1, wherein said semiconductor memory device is a device for storing location information for a mobile phone service.