KR101214218B1 - Apparatus for driving regulator-independent CPU's standby RAM and method thereof - Google Patents

Abstract

A standby ram drive device of a central processing unit independent of a regulator is disclosed. The standby ram driving device is a regulator for supplying standby power to the standby RAM of the central processing unit, and a power converter that receives the standby power supplied from the regulator and supplies the standby power to the standby ram as the operating power of the standby ram. Include. This allows the CPU standby RAM to be used reliably without replacing the regulator.

Description

Apparatus for driving regulator-independent CPU's standby RAM and method

The present invention relates to a standby memory (CPU standby RAM) of the central processing unit, and more particularly to a technology for driving a CPU standby RAM independent of the regulator.

The CPU standby RAM stores power even when the CPU power is turned off. For this function, the CPU must be designed to enable standby mode. Basically, the CPU standby RAM is configured to receive standby power through a regulator. However, since the CPU-specific regulator is selected and used, the standby power specification supplied by the regulator may not match the CPU standby RAM even if other conditions are well met. In this case, the CPU eventually does not support standby mode.

It is an object of the present invention to provide a technical scheme for driving a CPU standby RAM even if the standby power specification supplied by the regulator does not match the CPU standby RAM.

The standby ram driving device of the central processing unit independent of the regulator according to an aspect of the present invention for achieving the above technical problem is a regulator for supplying standby power to the standby RAM (CPU Standby RAM) of the central processing unit, and the regulator And a power converter configured to receive a standby power supplied from the standby power and supply the standby power as an operating power of the standby RAM.

The power conversion unit bypasses the standby power and outputs the standby power, a bypass unit for dropping the standby power supply voltage, a voltage dropping unit for dropping the standby power supply voltage and outputting the standby power supply, a voltage rising unit for raising the standby power supply voltage and outputting the standby power supply, and And a switching unit configured to output a standby power source to any one of a bypass unit, a voltage drop unit, and a voltage riser according to the control signal.

On the other hand, the standby RAM driving method of the central processing unit independent of the regulator according to an aspect of the present invention for achieving the above technical problem is to check the standby power supply voltage value supplied from the regulator, the confirmed standby power supply voltage value Comparing the standby power supply voltage with the standby power supply voltage of the standby RAM in the CPU, and controlling the bypass to supply the standby power supply voltage directly to the standby RAM if the comparison result is matched.

According to the present invention, the standby power supplied from the regulator is converted to be suitable for the operating power of the CPU standby RAM and supplied to the CPU standby RAM, thereby enabling the stable use of the CPU standby RAM regardless of the regulator specification.

1 is a block diagram of a CPU standby RAM driving device independent of a regulator according to an embodiment of the present invention.
2 is a block diagram of a power conversion unit according to an embodiment of the present invention.
Figure 3 is a block diagram of a power conversion unit according to another embodiment of the present invention.
4 is a flowchart illustrating a method for driving a CPU standby RAM that is independent of a regulator according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The foregoing and further aspects of the present invention will become more apparent from the following detailed description of preferred embodiments with reference to the accompanying drawings. Hereinafter, the present invention will be described in detail to enable those skilled in the art to easily understand and reproduce the present invention.

1 is a block diagram of a CPU standby RAM driving device independent of a regulator according to an embodiment of the present invention, and FIG. 2 is a block diagram of a power conversion unit according to an embodiment of the present invention.

The regulator 110 stabilizes and supplies power required for the CPU 130. The regulator 110 according to an embodiment of the present invention supplies the standby power to the standby RAM 131. The power converter 120 receives the standby power supplied from the regulator 110 and supplies the standby power to the standby RAM 131 at a voltage level suitable for the standby RAM 131. In one embodiment, the power converter 120 has a circuit configuration for bypassing the standby power supplied from the regulator 110 to the standby RAM 131, a boost circuit for raising a standby power supply voltage, It consists of a mid-circuit that includes a dropping circuit to lower the standby supply voltage. In one embodiment, each of the boosting circuit and the dropping circuit may be configured as two or more as necessary. That is, two or more boosting circuits and two or more dropping circuits may be configured according to the degree of boosting and the degree of dropping. Alternatively, the variable resistor can be used to adjust the degree of boost and drop.

As shown in FIG. 2, the power conversion unit 120 includes a bypass unit 210 for bypassing the standby power supplied from the regulator 110, a voltage raising unit 220 for raising the standby power supply voltage, And a voltage drop unit 230 for lowering the standby power supply voltage. In addition, the power converter 120 includes a switching unit 240 having a switching element for outputting the standby power input to any one of the bypass unit 210, the voltage raising unit 220, and the voltage dropping unit 230. do. The switching unit 240 is switched and controlled by a control signal from the CPU 130.

The CPU 130 has a standby RAM 131 therein. The standby RAM 131 operates by receiving a standby power output from the power converter 120. In one embodiment, the CPU 130 checks the operating power of the standby RAM 131 and confirms the standby power supplied from the regulator 110. In the system implementation, specification information of the standby RAM 131 and the regulator 110 may be recorded in the system memory. Therefore, in this case, the CPU 130 may check the standby power supply of the regulator 110 and the operating power supply of the standby RAM 131, and control signals to the switching unit 240 of the power conversion unit 120 according to the check result. The standby power is output to one of the bypass unit 210, the voltage raising unit 220, and the voltage dropping unit 230. If each of the voltage raising unit 220 and the voltage lowering unit 230 includes a plurality of boosting circuits and a plurality of dropping circuits, the CPU 130 may increase the voltage level to the rising or falling voltage level. In order to control the switching unit 240 so that the standby power is input to the circuit. If the voltage rise circuit and the voltage drop circuit are designed to adjust the voltage rise level and the voltage drop level through the variable resistor, the CPU 130 adjusts the variable resistor value with the voltage riser 220 or the voltage drop 230. By outputting a control signal for the voltage rising level or voltage drop level can be adjusted.

In another embodiment, the CPU 130 knows the specification information of the standby RAM 131 implemented therein, requests the specification information to the regulator 110 at system initialization, and requests the specification information from the regulator 110 according to the request. Receive specification information. In this way, the CPU 130 may check the standby power of the regulator 110 and the operating power of the standby RAM 131, and output a control signal to the switching unit 240 of the power converter 120 according to the check result. The standby power is output to any one of the bypass unit 210, the voltage raising unit 220, and the voltage dropping unit 230. If each of the voltage raising unit 220 and the voltage lowering unit 230 includes a plurality of boosting circuits and a plurality of dropping circuits, the CPU 130 may increase the voltage level to the rising or falling voltage level. In order to control the switching unit 240 so that the standby power is input to the circuit. If the voltage rise circuit and the voltage drop circuit are designed to adjust the voltage rise level and the voltage drop level through the variable resistor, the CPU 130 adjusts the variable resistor value with the voltage riser 220 or the voltage drop 230. By outputting a control signal for the voltage rising level or voltage drop level can be adjusted.

In another embodiment, the CPU 130 knows the specification information of the standby RAM 131 implemented therein and has a configuration for detecting a standby power supply voltage value input to the standby power input terminal. Since the standby power supply voltage value is known, the CPU 130 outputs a control signal to the switching unit 240 of the power converter 120 so that the standby power supply voltage matches the operating power supply voltage of the standby RAM 131. The bypass unit 210, the voltage raising unit 220, and the voltage dropping unit 230 are output to any one. If each of the voltage raising unit 220 and the voltage lowering unit 230 includes a plurality of boosting circuits and a plurality of dropping circuits, the CPU 130 may increase the voltage level to the rising or falling voltage level. In order to control the switching unit 240 so that the standby power is input to the circuit. If the voltage rise circuit and the voltage drop circuit are designed to adjust the voltage rise level and the voltage drop level through the variable resistor, the CPU 130 adjusts the variable resistor value with the voltage riser 220 or the voltage drop 230. By outputting a control signal for the voltage rising level or voltage drop level can be adjusted.

3 is a block diagram of a power conversion unit according to another embodiment of the present invention.

In the case of FIG. 3, the CPU 130 does not control an operation mode (bypass mode, voltage rising mode, voltage drop mode) of the power conversion unit 120, but the power conversion unit 120 itself operates in a mode. It is a way to operate by determining. The bypass unit 310 is configured to bypass the standby power supplied from the regulator 110 to the standby RAM 131 of the CPU 130. The voltage raising unit 320 is configured to increase the standby power supply voltage supplied from the regulator 110, and the voltage dropping unit 330 is configured to lower the standby power supply voltage supplied from the regulator 110. In an exemplary embodiment, each of the booster circuit of the voltage raising unit 320 and the dropping circuit of the voltage lowering unit 330 may be configured as two or more as necessary. That is, two or more boosting circuits and two or more dropping circuits may be configured according to the degree of boosting and the degree of dropping. Alternatively, each of the voltage rising unit 320 and the voltage drop unit 330 may be adjusted with a boost level and a drop level through a variable resistor.

The switching unit 340 is configured as a switching element for outputting the standby power supplied from the regulator 110 to any one of the bypass unit 210, the voltage raising unit 320, and the voltage dropping unit 330. The controller 350 may be a microcontroller. The CPU 130 compares the operating power of the standby RAM 131 with the standby power supplied from the regulator 110 and controls the switching unit 340 according to the comparison result. In an exemplary embodiment, the controller 350 requests and receives the operating power voltage value of the standby RAM 131 from the CPU 130, and requests and receives the standby power voltage value from the regulator 110 to receive the two voltage values. Can be compared. In another embodiment, the controller 350 requests and receives the operating power voltage value of the standby RAM 131 from the CPU 130 and detects the standby power voltage value input to the switching unit 340 to detect the two voltage values. Can be compared. In another embodiment, the specification information of the regulator 110 and the standby RAM 131 may be recorded in the internal memory of the power converter 120 when the system is implemented. Therefore, in this case, the controller 350 may compare the two voltage values by searching the specification information recorded in the memory.

The controller 350 controls the switching unit 340 according to the comparison result through the above-described embodiments. If each of the voltage raising unit 320 and the voltage lowering unit 330 is composed of a plurality of boosting circuits and a plurality of dropping circuits, the controller 350 may be configured to increase or decrease the voltage level. In order to control the switching unit 340 so that the standby power is input to the corresponding circuit. If the voltage rising circuit and the voltage drop circuit are designed to adjust the voltage rising level and the voltage drop level through the variable resistor, the controller 350 adjusts the variable resistance value to the voltage rising section 320 or the voltage drop section 330. By outputting a control signal for the voltage rising level or voltage drop level can be adjusted.

For reference, Table 1 illustrates a correlation between the standby power supply, the operating power supply of the standby RAM, and the operation mode of the power conversion unit 120. The operation mode of the intermediate circuit is determined according to the standby power output from the regulator 110 and the operating power of the standby RAM 131.

Regulator Standby Output Power CPU Standby RAM Power Mid-circuit Regulator power CPU power TLE7368 2.6V or 1.0V MPC5553 1.0 V short TLE7368 2.6V or 1.0V TC1796 1.5V Voltage drop circuit ... ... ... ... ... ... ... ... ... ... ... ... ... ... ...

4 is a flowchart illustrating a method for driving a CPU standby RAM that is independent of a regulator according to an embodiment of the present invention.

In one embodiment, the CPU standby RAM driving method according to FIG. 4 is performed by the controller 350 shown in FIG. 3. The controller 350 checks the standby power supply voltage value supplied from the regulator 110 (S410). In one embodiment, the control unit 350 may check the standby power supply voltage value by obtaining the specification information from the regulator 110 during initial system startup. In another embodiment, the controller 350 may detect a standby power supply voltage input to the switching unit 340 and check the voltage value. In another embodiment, the specification information of the regulator 110 is pre-stored in the memory of the power conversion unit 120, so that the control unit 350 receives the standby power supply voltage supplied from the regulator 110 through a memory search. You can check the value.

The controller 350 compares the identified standby power supply voltage value with the operating power supply voltage value of the standby RAM 131 in the CPU 130 (S420). In an exemplary embodiment, the controller 350 may obtain the specification information of the standby RAM 131 from the CPU 130 during initial system driving, and then check the driving power voltage value of the standby RAM 131. In another embodiment, the specification information of the standby RAM 131 is pre-stored in a memory of the power converter 120. Therefore, the controller 350 may store the standby power voltage supplied from the regulator 110 through a memory search. You can check the value.

The controller 350 determines whether or not the standby power supply voltage value and the operating power supply voltage value of the standby RAM 131 match (S430), and when the match is matched, the control unit 350 controls the switching unit 340 to immediately turn on the standby power supply 131. To be applied (S440). When the standby power supply voltage value and the operating power supply voltage value of the standby RAM 131 do not match, the controller 350 controls the switching unit 340 so that the standby power supply voltage becomes the standby RAM 131 through the voltage raising unit 320. ) To be applied to the standby RAM 131 through the voltage drop unit 330 (S450). When the voltage raising unit 320 and the voltage lowering unit 330 are controlled by the variable resistor, the boosting level and the dropping level are adjusted. In operation S450, the controller 350 controls the voltage raising unit 320 and the voltage lowering unit 330. By controlling the variable resistance value, the boost level and the drop level can be adjusted.

So far I looked at the center of the preferred embodiment for the present invention. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the disclosed embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is defined by the appended claims rather than by the foregoing description, and all differences within the scope of equivalents thereof should be construed as being included in the present invention.

110 regulator 120 power conversion unit
130: CPU 131: standby RAM
210, 310: bypass unit 220, 320: voltage rising unit
230, 330: voltage drop 240, 340: switching unit
350: control unit

Claims (7)

delete delete delete delete A central processing unit;
A regulator for supplying standby power to a standby RAM of the CPU; And
A bypass unit for bypassing the standby power supplied from the regulator and outputting the standby power to the standby ram, and a voltage drop unit for dropping the standby power supply voltage supplied from the regulator to the operating power supply voltage of the standby ram and outputting the standby power to the standby ram. A voltage rising unit configured to increase a standby power supply voltage supplied from the regulator to an operating power supply voltage of the standby RAM and output the standby power supply to the standby RAM; and a standby power supply supplied from the regulator to the bypass unit and the voltage drop unit; Includes; a power converter including a switching unit for outputting to any one of the voltage rising unit,
The CPU checks and compares the standby power supply voltage value and the operating power supply voltage value of the standby RAM based on the specification information of the standby RAM and the specification information of the regulator, and stores the standby power according to the comparison result. The standby RAM driving apparatus of the central processing unit independent of the regulator, characterized in that for controlling the power conversion unit so that the operating power of the RAM is supplied to the standby RAM. delete The standby power supply voltage value and the operating power supply voltage value of the standby RAM are checked through CPU standby RAM specification information recorded in a memory and specification information of a regulator for supplying standby power to the standby RAM. And comparing;
If the comparison result is matched, bypass control to supply the standby power supply voltage of the regulator directly to the standby RAM; And
If the result of the comparison does not match, controlling the standby power supply voltage of the regulator to be supplied to the standby RAM by increasing or decreasing the standby power supply voltage so that the standby power supply voltage value matches the operating power supply voltage value of the standby RAM;
Standby RAM drive method of the central processing unit independent of the regulator comprising a.

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