JP2001022480A - Information processor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent such a setting that a current consumption in each function block exceeds power feeding capabilities of a power supply source and a power source circuit as for an information processor consisting of plural function blocks. SOLUTION: Operation of each of function blocks 18 to 21 is controlled by a power source control block 6 so that a current consumption of whole equipment does not exceed current supply capabilities of a power source circuit 3 and a power supply source 2. Even when software 12 erroneously performs power source control of each of the function blocks 18 to 21, it becomes possible for the current consumption of the whole equipment not to exceed the current supply capabilities of the power supply source 2 and the power source circuit 3 so that erroneous operation of the equipment can be prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an information processing apparatus comprising a plurality of functional blocks.

[0002]

2. Description of the Related Art In recent years, in the field of electronic devices such as personal computers, small portable devices such as hand-held devices have become widespread. In such small devices, a power supply source and a power supply circuit are small. Therefore, when all the functional blocks constituting the device are operated at the same time, the current supply capability of the power supply source and the power supply circuit may be exceeded. For this reason, when operating the functional blocks configuring the device, the current value from the power supply source and the power supply circuit, the voltage of the power supply source, etc. are detected, and the current supply capability of the power supply source and the power supply circuit is exceeded by software. It was necessary to limit the functional blocks to be operated so that they did not occur.

However, if the software does not have a function for limiting such a functional block, the current consumption of the operating functional block exceeds the current supply capability of the power supply source and the power supply circuit. In the worst case, this has led to equipment malfunction.

FIG. 2 is composed of a plurality of functional blocks.
When operating the functional blocks that make up the device, the current value from the power supply source and the power supply circuit and the voltage of the power supply source are detected, and the software operates so that the current supply capability of the power supply source and the power supply circuit is not exceeded. FIG. 11 is a block diagram of a conventional information processing device that limits the function blocks to be performed. Reference numeral 31 denotes a line for detecting the voltage and current value of the power supply source, reference numeral 32 denotes a line for detecting the current value of the power supply circuit, reference numeral 33 denotes a power supply source for supplying power to the device, and reference numeral 34 denotes a line from the power supply source. A power supply circuit for converting a power supply to a voltage used in the device. Reference numeral 35 denotes a power supply circuit 47, 48, 4 in accordance with a command from a main information processing function block 39.
Registers for setting the operation / non-operation of each of the functional blocks 9 and 50. Reference numeral 36 denotes reference numerals 47, 48, and 4.
Reference numeral 37 denotes a power supply control block for controlling the power supply of the functional blocks 9 and 50. Reference numeral 37 denotes an address / data bus and a command signal for exchanging data between the main information processing function block 39 and the power supply control block 36. Reference numeral 38 denotes a power supply line supplied from the power supply circuit 34 to the inside of the device, reference numeral 39 denotes a main information processing function block that is always operating among the component blocks of the device, and reference numeral 40 denotes a main information processing unit that controls the basic operation of the device. CPU, reference numeral 41 denotes software for operating the main CPU,
Reference numeral 42 denotes an address / data bus and a command signal for exchanging data between the main information processing function block 39 and the function blocks 47, 48, 49, and 50. Reference numeral 43 denotes a power supply control block 36. An operation control signal output from the power supply control block denoted by reference numeral 47 is output from the power supply control block denoted by reference numeral 47, and an operation control signal is output from the power supply control block denoted by reference numeral 48 to control the power supply of the functional block 2 denoted by reference numeral 48. An operation control signal output from the power supply control block 36 to control the power supply of the functional block 3 denoted by reference numeral 49. An operation control signal 46 is output from the power supply control block 36 to control the power supply of the functional block 4 denoted by reference numeral 50. Signals, reference numeral 47 denotes a functional block 1 constituting the device, reference numeral 48 denotes a functional block 2, which constitutes the device, reference numeral 49 Function block 3 of the device, reference numeral 50 is a functional block 4 constituting the device.

[0005] First, in FIG.
Are operated at the same time, the current value consumed by them exceeds the current supply capability of the power supply source and the power supply circuit. When the function block 1 is currently operating and the function block 2 is newly operated, the voltage value and the current value of the power supply source and the current value of the power supply circuit are detected by the main information processing block. It is necessary to determine whether or not to operate the functional block 2 based on the above, and if the operation is possible, it is necessary to change the setting of the register in the power supply control block relating to the functional block 2 and operate the functional block 2. These series of operations are performed by software, but in order to perform these operations, it is necessary to use software corresponding to these operations.

[0006]

However, when software corresponding to the above-described series of operations is not used, the current consumption of the entire device exceeds the current supply capability of the power supply source and the power supply circuit, and The power supply voltage output from the circuit deviates from the standard, and in the worst case, the device may operate abnormally. The present invention has been made to solve such a problem, and even if software incorrectly controls the power supply of each functional block, the current consumption of the entire device is reduced by the current supply capability of the power supply source and the power supply circuit. The purpose is not to exceed.

[0007]

According to an information processing apparatus of the present invention, a power supply control circuit includes a current supply capability of a power supply circuit and a power supply source, a current consumption value of the entire apparatus, and a function block to be operated from now on. It is characterized in that whether or not the function block can be operated is determined from the current consumption value, and the operation of each function block is controlled so as not to exceed the current supply capability of the power supply circuit and the power supply source.

According to the present invention, when software tries to make settings such that the current consumption value of each functional block exceeds the current supply capability of the source supply source and the power supply circuit, such a setting is forcibly performed. The above problem can be solved by prohibiting the setting and notifying the main CPU of the prohibition.

Further, the information processing apparatus of the present invention has a plurality of function blocks, a power supply circuit for supplying power to the plurality of function blocks, a current consumption value of the information processing apparatus and a function to be operated from now on. A power supply control block that calculates the sum of the current consumption values of the blocks and controls the operation of each functional block so that the sum does not exceed the current supply capability of the power supply circuit.

[0010] Furthermore, a storage medium storing a software program for operating each of the functional blocks is provided. When the software program causes the functional block to malfunction and exceeds the current supply capability of the power supply circuit, Control means for changing the power supply distribution of each functional block to control the current supply capability is not provided.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail using an embodiment of the present invention. FIG. 1 is a block diagram showing an embodiment of the present invention. Here, a case will be described where the device is composed of a main information processing function block and four function blocks.

Reference numeral 1 denotes a current / voltage detection line for detecting a voltage and a current value of a power supply source and a power supply circuit, and reference numeral 2 denotes a power supply source for supplying power to a device. Reference numeral 3 denotes a power supply circuit that converts power from the power supply source 2 into a voltage used by the device and supplies the voltage to the inside of the device. Reference numeral 4 denotes an interrupt signal from the power control block 6 to the main information processing function block 10. .

Reference numeral 5 denotes a main information processing function block 1.
This register is used to set the operation / non-operation of each of the functional blocks 18 to 21 by a command from 0.
Reference numeral 6 denotes a power supply control block that controls the power supply of the functional blocks 18 to 21.

Reference numeral 7 denotes a power supply source 2 and a power supply circuit 3.
, The voltage value and the current value are detected, and the setting of the register 5 by the software 12 causes each of the functional blocks 18 to 2 to
1 is a current / voltage value detection circuit and a register control circuit for prohibiting the setting change of the register 5 when the current consumption value of the power supply 1 exceeds the current supply capability of the power supply source 2 and the power supply circuit 3.

Reference numeral 8 denotes a main information processing function block 1.
Reference numeral 9 denotes a power supply line supplied from the code power supply circuit 3 to the inside of the device, which is an address / data bus and a command signal for exchanging data between 0 and the power supply control block 6.

Reference numeral 10 denotes a main information processing function block that is always operating in the component blocks of the device, and reference numeral 11 denotes a main CPU that controls the basic operation of the device.
It is. Reference numeral 12 denotes software for operating the main CPU 11. Reference numeral 13 denotes a main information processing function block 10 and function blocks 18, 19, 20, and 2.
These are an address / data bus and a command signal for exchanging data between one.

Reference numeral 14 denotes an operation control signal output from the power supply control block 6 for controlling the power supply of the functional block 1 (18). Reference numeral 15 denotes an operation control signal output from the power supply control block 6 and controlling the power supply of the functional block 2 (19). Reference numeral 16 denotes an operation control signal output from the power supply control block 6 and controlling the power supply of the functional block 3 (20). Reference numeral 17 denotes an operation control signal output from the power supply control block 6 and controlling the power supply of the functional block 4 (21).

Reference numeral 18 denotes a functional block 1 constituting the device, and reference numeral 19 denotes a functional block 2 constituting the device.
Reference numeral 20 denotes a functional block 3 that configures the device, and reference numeral 21 denotes a functional block 4 that configures the device.

The operation of the embodiment shown in FIG. 1 will be described below. First, the current supply capability of the power supply source 2 is 1 A when the voltage of the power supply source 2 is 5 V or more, and 0.7 A when the voltage of the power supply source 2 is less than 5 V. The current rating of the power supply circuit 3 is 1. 5A. The total current value in the main information processing function block 10 and the power supply control block 6 is 0.3 A at the power supply source output and 0.5 A at the power supply circuit output.
And

It is assumed that the current consumption of the functional block 1 (18) is 0.5 A at the output of the power supply source 2 and 0.7 A at the output of the power supply circuit 3.

It is assumed that the current consumption of the functional block 2 (19) is 0.3 A at the output of the power supply source 2 and 0.5 A at the output of the power supply circuit 3.

It is assumed that the current consumption of the functional block 3 (20) is 0.1 A at the output of the power supply source 2 and 0.15 A at the output of the power supply circuit 3.

It is assumed that the current consumption of the functional block 4 (21) is 0.1 A at the output of the power supply source 2 and 0.15 A at the output of the power supply circuit 3.

Now, assuming that the voltage of the power supply source 2 is 7 V and the function block 1 (18) is operating inside the device, the current consumption of the entire device is 0 at the output of the power supply source 2. .8 A, and 1.2 A at the output of the power supply circuit 3 (total current consumption of the power supply control block 6, the main information processing function block 10, and the function block 18).

Here, it is assumed that the setting corresponding to the function block 4 (21) in the register 5 is changed in order to operate the function block 4 (21) by the software 12. Here, the current / voltage detection circuit 7 detects that the voltage of the power supply source 2 is 5 V or more, and the current consumption of the entire device when the functional block 4 (21) is additionally operated is the power supply. The output of the power supply 2 is 0.9 A, and the output of the power supply circuit 3 is 1.35 A. The current consumption of the entire device is the current supply capability of the power supply source 2 (max. 1 A when 5 V or more) and the power supply circuit 3 (max. .5A).

Further, current values in the power supply source 2 and the power supply circuit 3 are detected by a current / voltage detection circuit 7,
It is determined whether the value obtained by adding the current consumption value in the function block 4 (21) to the detected value does not exceed the current supply capabilities of the power supply source 2 and the power supply circuit 3, respectively. The change of the set value of the register 5 by the register control circuit 7 is permitted by the register control circuit 7, and the operation block 17 starts the operation of the functional block 4 (21) by the operation control signal 17.

Further, from the above state, the function block 2
It is assumed that the setting corresponding to the function block 2 (19) in the register 5 is changed in order to operate (19).
At this time, the current / voltage detection circuit 7 detects that the voltage of the power supply source 2 is 5 V or more as described above,
Further, when the functional block 2 (19) is additionally operated, the current consumption of the entire device is 1.
2A, the output of the power supply circuit 3 becomes 1.85 A, and it is determined that the current consumption value of the entire device exceeds the current supply capability of the power supply source 2 or the power supply circuit 3.

When the operation of the function block 2 (18) is permitted in this state, the current consumption value of the entire device is reduced by the power supply source 2.
And the current supply capacity of the power supply circuit 3 is exceeded.
The register control circuit 7 prohibits the setting change of the register 5. Further, in order to notify this to the main CPU 11, the power supply control block 6 causes the main CPU 11 to generate an interrupt process by the interrupt signal 4.

When the software 12 operates the function block 2 (19) by the interrupt processing, the software 12 knows that the current consumption value of the entire device exceeds the current supply capability of the power supply source 2 and the power supply circuit 3, and After reducing the current consumption value of the entire device by stopping the operation of other unused functional blocks, the functional block 2 is again activated.
To operate (19), the register 5 is changed.

The above description is for the case where the software 12 corresponds to the circuit of the present invention.
Is not supported, the current / voltage detection circuit and the register control circuit are set when the setting is made in the register 5 so that the current consumption value of the entire device exceeds the current supply capability of the power supply source 2 and the power supply circuit 3. 7, the change of the set value of the register 5 is prohibited, and the current consumption value of the entire device is changed to the power supply source 2.
It is possible to avoid exceeding the current supply capability of the power supply circuit 3.

[0031]

As described above, according to the present invention, by controlling the operation of each functional block by the power supply control circuit so as not to exceed the current supply capability of the power supply circuit and the power supply source, software can execute each function. Even when the power supply of the block is erroneously controlled, the current consumption of the entire device can be prevented from exceeding the current supply capability of the power supply source and the power supply circuit, and malfunction of the device can be prevented.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention.

FIG. 2 is a block diagram showing an example of the related art.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 voltage / current detection line 2 power supply source 3 power supply circuit 4 interrupt signal 5 register 6 power supply control block 7 current / voltage detection circuit, register control circuit 8 address / data bus, command 9 power supply line 10 main information processing function block 11 main CPU 12 software 13 address / data bus, command 14 function block 1 operation control signal 15 function block 2 operation control signal 16 function block 3 operation control signal 17 function block 4 operation control signal 18 function block 1 19 function block 2 20 function block 3 21 Function Block 4 31 Voltage / Current Detection Line 32 Current Detection Line 33 Power Supply Source 34 Power Supply Circuit 35 Register 36 Power Supply Control Block 37 Address / Data Bus, Command 38 Power Supply Line 39 Main Information Processing Function Block 40 Main CPU 41 Software 42 Address / Data Bus, Command 43 Function Block 1 Operation Control Signal 44 Function Block 2 Operation Control Signal 45 Function Block 3 Operation Control Signal 46 Function Block 4 Operation Control Signal 47 Function Block 1 48 Function Block 2 49 Function Block 3 50 Function block 4

Claims (2)

[Claims] A plurality of function blocks; a power supply circuit for supplying power to the plurality of function blocks; and a sum of a current consumption value of a current information processing apparatus and a current consumption value of a function block to be operated from now on. And a power supply control block that controls the operation of each functional block so that the sum does not exceed the current supply capability of the power supply circuit. 2. A storage medium storing a software program for operating each of the functional blocks, wherein the software program causes the functional block to malfunction and exceeds the current supply capability of the power supply circuit. 2. The information processing apparatus according to claim 1, further comprising control means for changing a power distribution of each functional block so as to control the power supply capacity so as not to exceed the current supply capability.