KR100251777B1 - Wireless exchage system and method for synchroning wireless basestation - Google Patents

Abstract

PURPOSE: A wireless switching system for synchronizing wireless base stations with each other and method for the same are provided to generate a reference clock of synchronization between the base stations for supporting CDMA, and thereby synchronizing there stations with each other. CONSTITUTION: A switching center(100) includes a circuit for generating a super-frame pulse that synchronizes a plurality of wireless base stations(110,120) with each other. The switching center(100) transmits the super-frame pulse generated in the circuit to the base stations(110,120). The switching center(100) is connected to base stations(110,120) via a wired interface line. The base stations(110,120) receive the super-frame pulse transmitted from the switching center(100) via the wired interface. The base stations are synchronized with each other by the super-frame pulse received.

Description

Wireless switching system and method for synchronizing wireless base stations {WIRELESS EXCHAGE SYSTEM AND METHOD FOR SYNCHRONING WIRELESS BASESTATION}

The present invention relates to a radio switching system, and more particularly, to a radio switching system and a method for synchronizing between radio base stations by generating a signal for synchronizing between radio base stations.

In general, in order to provide services such as an incoming / outgoing call and a handover by using a wireless switching system, two or more base stations should be installed and multiple radio cells should be configured so that each radio cell overlaps.

If the clocks for the time division multiplexing scheme used in each base station of the conventional radio switching system are not synchronized, interference occurs between radio links in which a communication path is formed through each base station, which causes trouble to the call.

In the conventional wireless switching system, in order to synchronize the clocks for the time division multiplexing schemes of each base station, the adjacent base stations are connected by separate wires, and the base station set as the master generates the clock for the time division multiplexing scheme. Through the generated clock is supplied to another base station that is a slave.

In the conventional radio switching system as described above, since a separate wired is required to supply the clock from the base station set as the master to the other base station set as the slave, the cost is increased. In addition, in the conventional radio switching system, a separate design for implementing a mode for setting a master and a slave is further required.

Accordingly, an object of the present invention is to provide a wireless switching system for synchronizing between wireless base stations by generating a synchronization reference clock for time division multiple access between wireless base stations.

Another object of the present invention is to provide a method for implementing synchronization between radio base stations in a radio switching system.

The present invention for achieving these objects is provided with at least a circuit for generating a super frame pulse for synchronizing between the wireless base station, the circuit for generating a super frame pulse in the circuit for generating the super frame pulse connected via a wired interface line An exchange each transmitting to base stations; And a plurality of wireless base stations receiving the super frame pulse transmitted from the exchange through the wired interface line and synchronizing a clock by the received super frame pulse. In addition, the present invention is a process of generating a super frame pulse of a predetermined period using a frame synchronization pulse in the exchange, and the process of transmitting the generated super frame pulse to the plurality of wireless base stations through the wired interface line And receiving the super frame pulses of the predetermined period from the plurality of radio base stations, and synchronizing clocks by the super frame pulses.

1 is a block diagram of a wireless switching system to which the present invention is applied.

2 is a circuit diagram for generating a super frame pulse for synchronizing between wireless base stations in an exchange in accordance with the present invention.

3 is a waveform diagram of a signal used in the circuit shown in FIG.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of a system to which the present invention is applied and includes a switch 100 for controlling a wireless base station and wireless base stations 110 and 120.

The operation of the exchange system according to the embodiment of the present invention will be described with reference to FIG. The exchange 100 supplies the generated super frame pulses to the wireless base stations 110 and 120 connected through a wired line. The wireless base stations 110 and 120 use a clock of a time division multiplexing scheme in synchronization with the super frame pulses supplied from the exchange 100.

FIG. 2 is a circuit diagram for generating a super frame pulse for synchronizing between wireless base stations according to the present invention, wherein the first and second counters 200 and 220 and the first, second and 3D flip-flops 240, 250, 280 and 1, 2, 3 An inverter 210, 230, 270, an exclusive OR gate 260, and an AND gate 290 are included.

FIG. 3 is a waveform diagram of a signal used in the circuit shown in FIG. 2, and each signal is as follows. 2 and 3, the signal (A) is a first frame sync pulse Fsx, and is input to the first counter 200 and the exclusive oar gate 260, and the signal (B) is the second frame. As the frame sync pulse / fp, it is input to the 3D flip-flop 280. The signal (C) is a clock of 500 Hz, and is output from the first counter 200 to the second counter 220, and the signal (D) is output from the second counter 220. Signal is input to the clear end of the 2D flip-flop 250. The (E) signal is output from the first D flip-flop 240 and is input to the exclusive oar gate 260, and the (F) signal is output from the third D flip-flop 280 and input to the AND gate 290. . The (G) signal is output from the exclusive ogate 260 and input to the AND gate 290, and the (H) signal is a super frame pulse according to an embodiment of the present invention and is output from the AND gate 290. .

2 and 3, the operation of the circuit for generating the super frame pulse according to the embodiment of the present invention will be described. The first counter 200 receives the first frame sync pulse Fsx as the enable signal as shown in (A) shown in FIG. 3 as an enable signal, and receives a pulse of 2 MHz as a clock (C) shown in FIG. A pulse of 500 Hz, such as a signal, is supplied to the clock of the second counter 220. The second counter 220 receives a " 1010 " and performs a predetermined counting operation in synchronization with a clock supplied from the first counter 200, and outputs a ripple carry out signal such as the signal (D) shown in FIG. Output The second inverter 230 inverts the ripple carry out signal output from the second counter 220 and applies it to the load terminal of the second counter 220. The ripple carry-out signal is supplied to the clock of the first D flip-flop 240 and is applied to the clear terminal of the second D flip-flop 250. The first D flip-flop 240 receives the high signal Vcc through the input terminal 1D, receives the ripple carry-out signal as a clock, and outputs the signal (E) shown in FIG. 3. The 2D flip-flop 250 receives an output signal again, receives a 2 MHz clock inverted by the first inverter 210, and outputs a latched input signal. The 3D flip-flop 280 receives a second frame synchronization signal (/ fp) such as the signal (B) shown in FIG. 3, and receives a 4 MHz pulse inverted by the third inverter 270 as a clock. The signal (F) shown in FIG. 3 is output. The exclusive oragate 260 receives the first frame synchronization signal A shown in FIG. 3 and the signal E output from the second D flip-flop 240, and according to an exclusive logical sum shown in FIG. 3. (G) Outputs the signal. As shown in FIG. 3, the (G) signal output from the exclusive oragate 260 exhibits a glitch phenomenon which is a hunting of a pulse waveform due to an unspecified cause that is limited in a relatively short time. The AND gate 290 receives the (F) signal output from the D flip-flop 280 and the (G) signal output from the exclusive oar gate 260, and according to the logical sum, the AND gate 290 is the same as the (H) signal shown in FIG. A super frame pulse is output according to an embodiment of the present invention. The super frame pulse has a waveform characteristic such that a pulse of 12 ms period and the first frame synchronizing signal A are combined.

A method of synchronizing between wireless base stations in a wireless switching system according to an embodiment of the present invention will be described with reference to FIGS. The switch 100 includes a circuit for generating a super frame pulse signal as shown in FIG. 2, and generates a super frame pulse signal H as shown in FIG. 3 to transmit a wireless base station 110, 120 through a transmission line. To supply. All wireless base stations 110 and 120 use the supplied super frame pulse signal as a reference clock for time division multiplexing. Therefore, in the wireless switching system according to the embodiment of the present invention, all wireless base stations are supplied with the super frame pulse signal, and the clock can be synchronized with the super frame pulse signal.

As described above, the present invention generates a super frame pulse in a wireless switching system and supplies it to all wireless base stations through a wired connection line between an existing exchange and a base station, so that a separate line is not required for synchronization between wireless base stations.

Claims (5)

In a wireless switching system for synchronizing between wireless base stations, At least a circuit for generating a super frame pulse for synchronizing between the wireless base stations, wherein the circuit for generating the super frame pulse generates a super frame pulse and transmits the super frame pulse to the wireless base stations connected through a wired interface line, respectively. ; And a plurality of wireless base stations configured to receive the super frame pulse transmitted from the switch via the wired interface line and synchronize a clock by the received super frame pulse. Wireless switching system. The circuit of claim 1, wherein the circuit for generating the super frame pulse comprises: A first counter configured to receive a first frame synchronization signal and to perform a predetermined counting operation; A second counter that receives a signal output from the first counter as a clock and performs a predetermined counting operation; A first flip-flop that receives a ripple carry-out signal output from the second counter as a clock and outputs an input signal; A second flip-flop that inverts the pulse applied to the clock of the first counter and outputs a signal received by being applied as a clock; A third flip-flop that outputs a second frame synchronization signal input in response to an applied clock; An exclusive oar gate receiving the first frame synchronization signal and the signal output from the first flip-flop and outputting the signal based on an exclusive OR; And an AND gate which receives a signal output from the exclusive ogate and a signal output from the third flip-flop and outputs the result based on a logical product. The method of claim 2, wherein the super frame pulse, A radio switching system for synchronizing between radio base stations, characterized in that the waveform is the same as the sum of the pulse of 12 ms and the first frame synchronization signal. A method for synchronizing between wireless base stations in a wireless switching system connected by a wired interface line between a switch and a plurality of wireless base stations, Generating a super frame pulse of a predetermined period by using a frame synchronization pulse in the exchange; Transmitting, by the exchange, the generated super frame pulse to the plurality of wireless base stations through the wired interface line; And receiving the super frame pulses of the predetermined period from the plurality of wireless base stations, and synchronizing clocks by the super frame pulses. The method of claim 4, wherein the super frame pulse, A method of synchronizing between radio base stations in a radio switching system, characterized by a waveform equal to the sum of a pulse of 12 ms and the frame synchronizing signal.

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