KR101245291B1 - Apparatus for controlling power and sensing over current running to smartcard - Google Patents

Abstract

PURPOSE: A power control and over-current detection apparatus is provided to protect an internal circuit due to over-current. CONSTITUTION: A power control and over-current detection apparatus includes a first control unit(101), a power output unit(102) for a smart card, and a power converter(103). The first control unit maintains a control pin voltage as a base level for applying a first power for smart card. The first control unit converts a first level of the control pin voltage into a second level of the control pin voltage when inserting the smart card. The power output unit for a smart card outputs a first power as a base level and outputs a second power by distributing the input power when the control pin voltage is converted from the first level to the second level. The power converter controls a voltage distribution value of the power output unit for a smart card. [Reference numerals] (101) First control unit; (105) Second control unit; (AA) Control panel

Description

Apparatus for controlling power and sensing over current running to smartcard}

The present invention relates to a power supply control and an overcurrent sensing device applied to a smart card, and more particularly, the overcurrent while being able to apply power for both 3.3V or 5V used in the CONDITIONNAL ACCESS SYSTEM of the smart card. It relates to a power supply control and an overcurrent sensing device applied to a smart card, which can protect the internal circuit from the.

In order to apply the conditional access system (CONDITIONNAL ACCESS SYSTEM) of a general microcontrol unit (MCU), an external controller IC is configured to operate the INPUT / OUTPUT data including power control according to the "ISO7816 International Standard". .

However, the conventionally applied power supplies are the same two DC-DC converters, and the 3.3V and 5V power supplies are used as each single output, which is redundant and expensive.

Therefore, it is necessary to separately control power according to the smart card type by providing an interface that meets the standard in the MCU itself without using an external IC.

The present invention was developed to solve the above problems, the power control to apply all the power (3.3V, 5V) required according to the type of smart card, and the short circuit state continuously by a circuit consisting of a simple TR An object of the present invention is to provide a power supply control and an overcurrent sensing device applied to a smart card that can recognize and protect an internal circuit from overcurrent.

Power control and overcurrent sensing device applied to the smart card according to the present invention for achieving this object,

The control pin voltage is maintained at the first level, which is the basic level for applying the first power supply for the smart card, and the control pin voltage is set from the first level, which is the second level, to the data response when the smart card driven by the second power source is inserted. A first control unit for converting to a level, connected to the first control unit through the control pin, and outputting a first power supply for a smart card as a basic power supply under the control of the first control unit, and under the control of the first control unit When the control pin voltage is converted from the first level to the second level, the voltage distribution value of the smart card power output unit for outputting the second power for the smart card by dividing the input power voltage, and the voltage distribution value of the smart card power output unit. Characterized in that it comprises a power converter to adjust.

Preferably, the power converter monitors the power flowing to the smart card to turn on the built-in switch when a steady state level is detected, input a low level signal, and turn off the built-in switch when a short state level is detected. And a short detection unit for inputting a high level signal, and when the low level signal is input from the short detection unit, the enable port of the power converter is made high to enable the output power of the power converter. And a second control unit for disabling the output power of the power converter by setting the enable port of the power converter to a low level when the high level signal is input from the short detection unit.

The present invention is a low-cost equivalent functional circuit configured to recognize and apply a short-circuit condition when two voltages used in a smart card are required to be applied when a dedicated access IC is not used. The applied power is duplicated by outputting each single output 3.3V and 5V power supply with two identical DC-DC converters, but the present invention is a conditional access to one DC-DC converter (the "power converter" of the present invention). Both 3.3V or 5V power supply used in the CONDITIONNAL ACCESS SYSTEM can be output through the transistor to reduce the redundant use of the power output IC, thus reducing the cost and outputting the power to be applied according to the output state. The effect is to protect the internal circuits from overcurrent by adjusting them.

1 is a diagram illustrating a power control and overcurrent sensing device applied to a smart card according to the present invention.
2 is a view for explaining the overcurrent detection and protection operation performed in the normal state according to the present invention;
3 is a view for explaining an overcurrent detection and protection operation performed in a short state according to the present invention;

Hereinafter, the present invention will be described with reference to the accompanying drawings.

It is to be understood, however, that the embodiments described below are only for explanation of the embodiments of the present invention so that those skilled in the art can easily carry out the invention, It does not mean anything.

In order to clearly illustrate the present invention, portions which are not related to the description have been omitted, and like reference numerals have been assigned to similar portions throughout the specification.

Throughout the specification and claims, when a section includes a constituent, it is intended that the inclusion of the other constituent (s) does not exclude other elements unless specifically stated otherwise.

1 is a diagram illustrating an apparatus for controlling power and overcurrent applied to a smart card according to the present invention.

As shown in FIG. 1, the apparatus includes a first control unit 101, a smart card power output unit 102, and a power converter 103.

That is, the control pin voltage is maintained at the first level, which is the basic level for applying the first power supply for the smart card, and the control pin voltage is set at the first level, which is the basic level, as a data response when the smart card driven by the second power source is inserted. A first control unit 101 for converting to a second level, connected to the first control unit 101 through the control pin, and outputs the first power for the smart card as a basic power under the control of the first control unit 101 When the control pin voltage is changed from the first level to the second level under the control of the first control unit 101, the power output for the smart card outputting the second power supply for the smart card by dividing the voltage of the input power. The unit 102 and the power converter 103 for adjusting the voltage division value of the power output unit 102 for the smart card is configured.

In addition, the short circuit detecting unit 104 and the second control unit 105 is configured to include.

Here, the first control unit 101 is connected to the smart card power output unit 102 through the control pin, the first level (the basic level for applying the control pin voltage to the first power supply for the smart card (3.3V) ( For example, the control pin voltage is changed from the first level (Low), which is the basic level, to the second level (High) in response to a data response when the smart card is driven by the second power source (5V). .

The smart card power output unit 102 is connected to the first control unit 101 through a control pin, and outputs the first power source for the smart card (3.3 V) as a basic power under the control of the first control unit 101. When the control pin voltage is changed from the first level to the second level under the control of the first control unit 101, the input power is divided by the power converter 103 to divide the voltage into the second power source for the smart card. Output (5V). That is, a high signal is input from the first control unit 101 through a control pin and the first power supply for the smart card (3.3V) is controlled by voltage distribution through two resistors R1 and R2 under the control of the power converter 103. Is outputted as a basic power supply, and when a low signal is input from the first control unit 101 through the control pin (that is, when the control pin voltage is changed from the first level to the second level), the power converter ( Under the control of 103, the second power supply 5V for the smart card is output by voltage distribution through three resistors R1, R2, and R3.

The power converter 103 adjusts the voltage distribution value of the power output unit 102 for the smart card. That is, in the case of outputting the first power supply for the smart card (3.3V) which is the basic power supply, the voltage distribution is performed through two resistors of R1 and R2, and the second power supply (5V) for the smart card is output. In the present invention, the voltage distribution value of the smart card power output unit 102 is adjusted so that the voltage distribution is made through three resistors of R1, R2, and R3.

The short circuit detecting unit 104 monitors the power flowing from the power converter 103 to the smart card, and when the steady state level is detected, the short circuit detecting unit 104 turns on the built-in switch to transmit the low level signal to the second control unit 105. When the short state level Low is detected (that is, when the smart card slot is shorted), the built-in switch is turned off to input the high level signal to the second control unit 105.

When the low level signal is input from the short circuit detection unit 104, the second control unit 105 sets the enable port of the power converter 103 to a high level to supply output power of the power converter 103. When the high level signal is input from the short detection unit 104, the enable port of the power converter 103 is set to a low level to disable the output power of the power converter 103. By blocking it, it is possible to protect the internal circuit from overcurrent by an external smart card.

Hereinafter, the operation of the power control and overcurrent sensing device applied to the smart card according to the present invention of FIG.

1. Power control operation applied to smart card

First, the first control unit 101 is connected to the smart card power output unit 102 through the control pin, the initial state, that is, the basic level for applying the control pin voltage of the first power supply for the smart card (3.3V) Maintain at the first level (eg Low level).

Next, in this initial state, when a smart card driven by the second power source 5V is inserted, the first control unit 101 sets the control pin voltage at a first level Low, which is a basic level, in response to a data response. 2 levels (High).

Then, the smart card power output unit 102 outputs the smart card first power (3.3V) as a basic power under the control of the first control unit 101, and then the control of the first control unit 101. When the control pin voltage is converted from the first level to the second level, the input power is divided by the power converter 103 to output the second power supply 5V for the smart card.

That is, a high signal is input from the first control unit 101 through a control pin and the first power supply for the smart card (3.3V) is controlled by voltage distribution through two resistors R1 and R2 under the control of the power converter 103. Is outputted as a basic power supply, and when a low signal is input from the first control unit 101 through the control pin (that is, when the control pin voltage is changed from the first level to the second level), the power converter ( Under the control of 103, the second power supply 5V for the smart card is output by voltage distribution through three resistors R1, R2, and R3.

At this time, the power converter 103 adjusts the voltage distribution value of the power output unit 102 for the smart card.

That is, in the case of outputting the first power supply for the smart card (3.3V) which is the basic power supply, the voltage distribution is performed through two resistors of R1 and R2, and the second power supply (5V) for the smart card is output. In the present invention, the voltage distribution value of the power output unit for the smart card is adjusted so that the voltage distribution is made through three resistors of R1, R2, and R3.

2. Overcurrent Sensing Operation

First, the short circuit detection unit 104 monitors the power flowing from the power converter 103 to the smart card.

Then, when a steady state level (High) is detected, the built-in switch is turned on to input a low level signal to the second controller 105.

When the short state level Low is detected (that is, when the smart card slot is shorted), the built-in switch is turned off to input the high level signal to the second controller 105.

Next, when the low level signal is input from the short detection unit 104 (that is, the normal state), the second control unit 105 makes the enable port of the power converter 103 high. Enable the output power of the power converter 103.

On the other hand, when a high level signal is input from the short circuit detecting unit 104 (that is, a short is generated), the enable port of the power converter 103 is brought into a low level state so that the power converter 103 is turned on. Disable and cut off the output power.

This protects the internal circuits from overcurrent by an external smart card.

As described above, the present invention is a DC-DC converter ("power converter" of the present invention) to enable the output of both 3.3V or 5V used in the conditional access system (CONDITIONNAL ACCESS SYSTEM) through the transistor power supply Cost reduction can be achieved by reducing the redundant use of the output IC, and the internal circuit can be protected from overcurrent by adjusting the output of the power to be applied according to the output state.

Next, the overcurrent detection and protection operation according to the present invention will be described in more detail with reference to FIGS. 2 and 3.

FIG. 2 is a view for explaining the overcurrent detection and protection operation performed in the normal state according to the present invention, and FIG. 3 is a view for explaining the overcurrent detection and protection operation performed in the short state according to the present invention.

First, as shown in Figure 2, the present invention monitors the power flowing from the power converter to the smart card.

Then, when the steady state level (High) is sensed by turning on the TR1 and TR2 to input a low level signal to the second control unit.

That is, since 3.3V, which is the divided voltage of the 12V power supply, is turned on in the TR turn-on state, the power supply becomes 0V, and a low level signal is input to the second controller.

Then, when the low level signal is input (that is, in a normal state), the second controller makes the enable port of the power converter high level to enable the output power of the power converter.

On the other hand, as shown in FIG. 3, when the short state level Low is sensed, TR1 and TR2 are turned off to input a high level signal to the second controller.

That is, since 3.3V, which is the divided voltage of the 12V power supply, is turned on in the TR turn-off state, the high voltage signal is input to the second controller as it is.

Then, when a high level signal is input (that is, in a short state), the second controller makes the enable port of the power converter low level to disable and cut off the output power of the power converter.

This protects the internal circuits from overcurrent by an external smart card.

Description of the Related Art [0002]
101: first control unit 102: smart card power output unit
103: power converter 104: short circuit detection unit
105: second control unit

Claims (2)

The control pin voltage is maintained at the first level, which is the basic level for applying the first power supply for the smart card, and the control pin voltage is set from the first level, which is the second level, to the data response when the smart card driven by the second power source is inserted. A first control unit for converting to a level;
It is connected to the first control unit through the control pin, and outputs the first power for the smart card as a basic power under the control of the first control unit, the control pin voltage at the first level under the control of the first control unit A smart card power output unit for outputting a second power supply for the smart card by dividing a voltage of the input power when converted to the second level; And
Apparatus for controlling power and overcurrent applied to a smart card comprising a power converter for adjusting the voltage distribution value of the power output unit for the smart card. The method of claim 1,
The power converter monitors the power flowing to the smart card to turn on the built-in switch if a steady state level is detected, input a low level signal, and if the shorted state level is detected, turn off the embedded switch to a high level. Short detection unit for inputting a signal of; And
When a low level signal is input from the short detection unit, the enable port of the power converter is set to a high level to enable the output power of the power converter, and a high level signal is input from the short detection unit. And a second control unit for disabling the output power of the power converter by putting the enable port of the power converter in a low level state.

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