KR200291277Y1 - Auto circuit-breaker reset device of the mobile communication system - Google Patents

Abstract

The present invention detects the surge current flowing through the power inlet of the back board that supplies power in each board of the mobile communication base station and detects the circuit breaker and detects the voltage state of the power line where the surge current is generated. A hot swap controller for releasing the function, a transistor connected to the gate terminal of the hot swap controller to control a bias voltage supplied to the board, and a surge current connected to the power input terminal of the hot swap controller to detect and input the surge current. A circuit automatic reset circuit of a mobile communication system including a sense resistor unit for inputting a detection signal to a hot swap controller is provided.

As described above, the present invention includes a reset function in a hot swap circuit connected to a power input terminal of a mobile communication base station board to check a power off state due to a surge current and reset the hot swap circuit according to the checking result, thereby providing a power off state. Is reset so that the administrator can automatically reset the system without having to search for the base station, thereby maximizing the management efficiency of mobile communication base station equipment and power-off state due to surge current. The system will reset the system by actively checking without administrator control, thus significantly improving the functionality of the hot swap circuit.

Description

Automatic circuit-breaker reset device of the mobile communication system

The present invention relates to a circuit automatic reset circuit of a mobile communication system. Especially, a reset function is provided in a hot swap circuit connected to a power input terminal of a mobile communication base station board to check a power-off state due to a surge current and according to the checking result. A circuit automatic reset circuit of a mobile communication system for resetting a hot swap circuit.

In general, a mobile communication base station system allocates a call channel to a mobile communication terminal in its sector to process a call. In this case, the mobile communication terminal frequently moves away from a base station to which a communication channel is allocated during a call and moves to a cell or another sector under the control of another base station. In this case, the neighboring base station is a new channel instead of the radio frequency channel in use. This function allows the call to be maintained by performing a handover or handoff function. However, the above-described base station uses the strength of the received signal and the carrier to interference ratio (C / I) and the like as parameters for determining the necessity of handoff of the mobile communication terminal.

Here, such a mobile communication base station system typically performs a handover or handoff function under the function control of the base station controller. The base station generally includes a plurality of boards such as RF boards or LICA boards in a back board that supplies power. Line interface control assembly). However, such boards are usually provided with a hot swap circuit to replace the board without powering off the back board. Such boards have a circuit-breaker to protect the boards from surge current that may occur when the board is inserted into the backboard or powered on. When the circuit is cut off, the mobile communication base station directly visits the base station, resets the system again, and operates the mobile station.

Then, referring to FIG. 1, the hot swap circuit of the conventional mobile communication base station as described above is connected to a back board 70 for supplying power in each board of the mobile communication base station to supply the power voltage of the corresponding board 71. The hot swap controller 72 detects a surge current flowing through the voltage input terminal and turns off the power of the board, and the transistor 73 connected to the gate terminal of the hot swap controller 72 to control a bias voltage supplied into the board. Is made of.

A sense resistor 74 is connected to the power input terminal vcc of the hot swap controller 72 to detect a surge current flowing through the power input terminal and input the detection signal to the hot swap controller 72.

Here, the hot swap controller 72, the sense resistor unit 74, and the transistor 73 may be provided in plural in the board.

Meanwhile, referring to the operation of the hot swap circuit of the mobile communication base station as described above, when the board 71 equipped with the hot swap circuit, for example, the LICA board is mounted on the back board 70 by the hot swap function, it is currently mounted from the back board 70. The power supply voltage is applied to the hot swap controller 72 of the hot swap circuit of the LICA board 71.

At this time, when the board is first mounted on the back board 70, since the gate voltage G of the transistor 73 is 0 [V], the power supply to the board 71 is blocked.

Here, when the board 71 is completely mounted on the back board 70 and is normally connected, the hot swap controller 72 supplies a power supply voltage input from the back board 70 by the hot swap controller 72 to a corresponding bias terminal, that is, VCC. Supply to transistor 73 through. At this time, when the signal applied through the gate terminal is greater than 0.8 [V], the hot swap controller 72 gradually increases the pin voltage of the gate of the transistor 73 so that the gate voltage of the hot swap controller 72 is completely high. When the signal is reached, the transistor 73 is turned on completely.

Accordingly, the transistor 73 switches the bias voltage supplied from the back board and supplies the same into the board.

Here, if, for example, the board is mounted on the backboard or the power pack of the base station is turned on / off due to the reset mode power reset, an unexpected current may occur in the power line, wherein the surge current is 1.5 us In the case of 50 mV or more during the above, the surge current is detected by the sense resistor unit 74 connected to the power input terminal vcc of the hot swap controller 72 and input to the hot swap controller 72. Then, the hot swap controller 72 changes the high signal applied to the gate terminal of the transistor 73 through the gate terminal to the low signal to execute the circuit breaker function. Therefore, since a low signal is applied to the gate terminal of the transistor 73, the transistor 73 is turned off and the surge current generated thereby is blocked from flowing into the board.

However, the hot swap circuit of the conventional mobile communication base station as described above has no function for releasing the power-off state due to the surge current, that is, the circuit breaker function. Since the system must reset the system by visiting the base station directly, it causes a problem that the management of the mobile communication base station is quite inconvenient and the maintenance cost is high.

Therefore, the present invention is designed to solve the above conventional problems, and includes a reset function in a hot-swap circuit connected to a power input terminal of a mobile communication base station board to check a power-off state due to a surge current and to check the result of the check. Therefore, by resetting the hot-swap circuit, the power off state can be canceled and the administrator can reset the system automatically without having to find the base station in order to reset the system, thereby maximizing the management efficiency of mobile communication base station equipment. It is an object of the present invention to provide a circuit automatic reset circuit of a mobile communication system.

Another object of the present invention is to provide a circuit automatic reset circuit of a mobile communication system, which actively checks a power-off state due to a surge current without a manager's control and resets the system accordingly. .

The present invention for achieving the above object is to detect the surge current flowing through the power inlet of the back board for supplying power in each board of the mobile communication base station circuit breaker board and the surge current of the power line A hot swap controller for releasing the circuit breaker function by detecting a voltage state, a transistor connected to a gate terminal of the hot swap controller to control a bias voltage supplied to the board, and a power input terminal connected to a power input terminal of the hot swap controller. Provided is a circuit automatic reset circuit of a mobile communication system comprising a sense resistor unit for detecting an incoming surge current and inputting the detected signal to a hot swap controller.

1 is an explanatory diagram for explaining a hot swap circuit of a conventional mobile communication system.

2 is an explanatory diagram illustrating a circuit of the present invention.

<Detailed Description of Codes>

1: Backboard 2: Hot Swap Controller

3: first transistor 4: second transistor

5: sense resistor portion 6: sense resistor portion

7: reset detection resistance 8: board

R1-R2: Resistor C1-C2: Capacitor

Hereinafter, the present invention will be described in detail based on the accompanying drawings.

The present invention is connected to the back board (1) for supplying power in each board of the mobile communication base station as shown in Figure 2 to supply the power voltage of the board and to detect the surge current flowing through the power inlet board A hot swap controller 2 for turning off the power supply and detecting a current level of the power line to release the circuit breaker function, and a transistor connected to a gate terminal of the hot swap controller 2 for controlling a bias voltage supplied to the board. 4 and a sense resistor unit 5 and 6 connected to the power input terminal vcc of the hot swap controller 2 to detect a surge current flowing through the power input terminal and input the detection signal to the hot swap controller 2. )

Here, the hot swap controller 2, the sense resistor unit 5, and the transistors 3 and 4 may be provided in plural in the board. In this case, the gate terminal GATE1 of the hot swap controller 2 is connected to the gate terminal of the first transistors 3 and 4, and the hot swap controller 2 is connected to the gate terminal of the second transistors 3 and 4. Is connected to the gate terminal GATE2 of the hot swap controller 2, and a surge generated in the voltage line between the VVC1 of the hot swap controller 2 and the connection terminals D1 to D4 of the first transistors 3 and 4 The first sense resistor unit 5, which detects a current and inputs it to the detection terminal SENSE 1 of the hot swap controller 2, is connected, and the power inlet terminal VCC2 and the second transistor of the hot swap controller 2 are connected. A second sense resistor 5 is connected between the connection terminals D1-D4 of 3 and 4 to detect the surge current generated in the voltage line and input the detected current to the detection terminal SENSE 2 of the hot swap controller 2. have.

In addition, a reset detection resistor 7 which is connected to a voltage line applied from the back board and detects the disappearance of the surge current is connected to the fault terminal of the hot swap controller 2.

And R1-R2 are resistors, and C1-C2 are capacitors.

Next, the operation and effects of the present invention as described above will be described.

According to the present invention, when a board equipped with a hot swap circuit, for example, an LICA board is mounted on a back board by a hot swap function, the power supply voltages, for example, vcc and 3.3 v Is applied.

At this time, when the board is first mounted on the back board, the gate voltage of the transistors 3 and 4 is 0 [V], so that power to the board 8 is cut off.

However, when the board 8 is fully mounted and normally connected to the back board 1, the hot swap controller 2 may supply the power voltage input from the back board 1 to the corresponding bias terminal, that is, VCC1 and VCC2. It supplies to the transistors 3 and 4 through.

In this case, when the signal applied through the gate terminals GATA1 and GATA2 is greater than 0.8 [V], the hot swap controller 2 gradually increases the pin voltage of the gates of the first transistors 3 and 4, and the signal. Is 2 [V] or more, the pin voltage of the gate of the second transistors 3 and 4 starts to increase gradually, and when the gate voltage of the hot swap controller 2 becomes a completely high signal, the transistors 3 and 4 Completely turned on.

Then, the hot swap controller 2 supplies the power supply voltage input from the back board 1 to the first and second transistors 3 and 4 through corresponding bias terminals, that is, VCC1 and VCC2.

In this case, the hot swap controller 2 applies a high signal to the gate terminals of the first and second transistors 3 and 4 through gate terminals GATE1 and GATE2, respectively, to allow the first and second transistors 3 and 4 to operate. Turn on each). Accordingly, the first and second transistors 3 and 4 switch bias voltages supplied from the back board and supply them to the board, respectively.

Here, if, for example, the board is mounted on the backboard or the power pack of the base station is turned on / off due to the reset mode power reset, an unexpected current may occur in the power line. For example, when applied to 50 mV or more for 1.5 us or more, it is detected by any one of the sense resistors 5 respectively connected to the power input terminals (vcc, 3.3 V) of the hot swap controller 2 and to be detected, for example, on the vcc line. The detected signal is then input to the hot swap controller 2. Then, the hot swap controller 2 changes the high signal applied to the gate terminal G1 of the first transistors 3 and 4 through the gate terminal GATE1 to a low signal to execute the circuit breaker function. Therefore, since a low signal is applied to the gate terminal of the first transistors 3 and 4, the first transistors 3 and 4 are turned off and the surge current generated thereby is blocked from flowing into the board.

At this time, the hot swap controller 2 checks whether a detection signal as the surge current disappears through the reset detection resistor 7 to the fault stage. At this time, when the detection voltage of the reset detection resistor 7 input through the fault stage is input below 0.4 [v], for example, the circuit breaker of the board is released and the hot swap controller 2 is reset. After the normal initialization process, the first and second transistors 3 and 4 are normally driven.

As described above, the present invention includes a reset function in a hot swap circuit connected to a power input terminal in a mobile communication base station board to check a power-off state due to a surge current and reset the hot swap circuit according to the checking result, thereby providing power. Since the OFF state is released and the administrator can automatically reset the system without having to find the base station in order to reset the system, it has the advantage of maximizing the management efficiency of mobile communication base station equipment accordingly.

In addition, according to the present invention, since the system is reset by actively checking the power-off state due to the surge current without the control of the manager, there is also an effect of significantly improving the functionality of the hot swap circuit.

Claims (2)

The circuit breaker function is released by detecting the surge current flowing through the power inlet of the back board that supplies power in each board of the mobile communication base station and detecting the voltage state of the power line where the surge current is generated. A hot swap controller, a transistor connected to a gate terminal of the hot swap controller to control a bias voltage supplied to the board, a surge current connected to a power input terminal of the hot swap controller to detect a surge current flowing through the power input terminal, and detecting the detected signal. A circuit automatic reset circuit of a mobile communication system, characterized in that it comprises a sense resistor section for input to a hot swap controller. The circuit automatic reset circuit of claim 1, wherein a reset detection resistor is connected to a voltage line applied from a back board to detect a disappearance of a surge current.