ITMI972745A1 - CIRCUIT AND PROCEDURE FOR CHECKING THE TIMING DELAY OF THE SYNCHRONOUS SIGNAL OF THE PANEL IN THE DIGITAL RADIO COMMUNICATION SYSTEM - Google Patents

Description

DESCRIPTION

The present invention relates to a digital radio communication system, and in particular, to a circuit and a method for controlling a time delay of a synchronous frame signal according to a distance difference between a switching center and a base station.

In a digital radio communication system, each base station receives the same frame synchronous signal transmitted by a switching center, to switch a channel in response to the received frame synchronous signal. In general, the base station should receive the frame synchronous signal within a delay error of ± 2μsec in order to switch the channel without a call service disconnection.

In the digital radio communication system, a frame synchronous signal transfer rate is determined by the characteristics of a transmission line. That is, the frame synchronous signal undergoes a time delay during transmission, according to the characteristics of the transmission line between the switching center and the base station. In other words, in the event that a distance between the switching center and the base station is very long, the frame synchronous signal transmitted from the switching center to the base station will experience a serious time delay. Conversely, if the distance between the switching center and the base station is very short, the frame synchronous signal transmitted from the switching center to the base station will suffer a shorter time delay.

In light of the foregoing descriptions, it is noted that the time delay of the frame synchronous signal is dependent on the characteristics (i.e., distance) of the transmission line between the switching center and the base station. However, since the base station would have to receive the frame synchronous signal within the delay error in order to switch the channel without disconnecting the call service, the distance between the switching center and the base station cannot be extended without limit. Also, in the event that the frame synchronous signal is distorted due to the characteristics of the transmission line and the surrounding environment during transmission, there is no way to compensate for the distortion of the frame synchronous signal.

It is therefore an object of the present invention to provide a circuit and a method for detecting a time delay of a synchronous frame signal transmitted from a switching center to the base station, in a digital radio communication system.

Another object of the present invention is to provide a circuit and a method for compensating for a time delay of a synchronous frame signal.

To achieve these and other purposes, a circuit for controlling a time state of a frame synchronous signal in a digital radio communication system including a switching center for transmitting the frame synchronous signal to a plurality of base stations, the stations base by instantaneously feeding the received frame synchronous signal back to the switching center, includes a delay detector to compare the frame synchronous signal transmitted to the base stations with the frame synchronous signal fed back from the base stations, to detect the time delay of the frame synchronous signal; and a delay compensator to compensate for the time delay of the synchronous frame signal.

The foregoing and other objects, features and advantages of the present invention will become more apparent in the light of the following detailed description of an exemplary embodiment thereof considered with the accompanying drawings in which:

Figure 1 is a schematic block diagram of a digital radio communication system to which the present invention is applicable; Figure 2 is a schematic block diagram of a base station interface (130) and a base station (141) of Figure 1;

Figure 3 is a detailed block diagram of a delay detector (130) of Figure 2 according to a preferred embodiment of the present invention;

Figure 4 is a detailed block diagram of transmitters (210 and 240) of Figure 2 according to a preferred embodiment of the present invention;

Figure 5 is a time diagram of signals generated by a switching center (100) and a base station (141) according to a preferred embodiment of the present invention; And

Figure 6 is a block diagram of a delay detector (23) according to another preferred embodiment of the present invention.

A preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings, in which the same or similar reference numerals indicate the same elements in the drawings, for understanding. Although in the specific embodiment such detailed elements will be defined and described by way of example in detail to clarify the subject matter of the present invention, the present invention can be implemented with the description of the present invention by those skilled in the art even without the details. Furthermore, an unnecessarily detailed description of widely known construction can be avoided here.

Referring to Figure 1, a digital radio communication system to which the present invention is applicable includes a switching center 100, a plurality of base stations 141-14n, and a mobile terminal 150, where the distances between the switching 100 and the respective base stations 141-14n are all different. The switching center 100 includes a main control unit 110, a signal processor 120, and a base station interface (BSI) 130. The main control unit 110 controls an overall operation of the switching center 100, the signal processor 120 processes signals transferred to and received by the base station interface 130 under the control of the main control unit 110, and the base station interface 130 interfaces signals transmitted to and received by base stations 141-14n. The mobile terminal 150 connects with the nearest base station among the base stations 141-14n, to transmit / receive data for a telephone conversation. A detailed block diagram of the base station interface 130 and base station 141 is shown in Figure 2.

Referring to Figures 1 and 2, the base station interface 130 includes a transmitter 210 for transmitting / receiving data and a signal, a control unit 220 for controlling an overall operation of the base station interface 130, and a delay detector 230 for detecting a time delay of the frame synchronous signal transmitted by the switching center 100. The base station 141 includes a transmitter 240 for transmitting / receiving data and a signal, a control unit 250 for controlling a overall operation of the base station 141, and a delay compensator to compensate for the time delay of the frame synchronous signal.

Referring to Figure 3, the delay circuit 230 according to a preferred embodiment of the present invention includes a counter 302, a buffer 304, and a comparator 306.

Figure 4 illustrates a detailed block diagram of the transmitters 210 and 240 of Figure 2 according to the present invention. As illustrated in the drawing, transmitter 210 includes master 410 and slave 420. Transmitter 240 includes slave 430 and master 440, connected to master 410 and slave 420 of transmitter 210, respectively.

Figure 5 is a timing diagram of signals generated by the switching center 100 and the base station 141 according to the present invention. In the drawing, a signal 500 represents the frame synchronous signal transmitted from the switching center 100 to the base station 141.

A signal 510 represents a signal that the counter generates to detect the time delay between the synchronous frame signal transmitted to the base station 141 and a synchronous frame feedback signal from the base station 141. A signal 520 represents the synchronous frame feedback signal from base station 141 to switching center 100.

Referring to Figures 1 to 5, the switching center 100 and each of the base stations 141-14n include the transmitters 210 and 240 shown in Figure 4 respectively, for transmitting / receiving signals between two pairs of the transmission lines. In the event that the switching center 100 transmits data to the base station 141, the control unit 220 allows the transmitter 210 to transmit the data to the base station 141 via the master 410. Then, the control unit 250 of the base station 141 allows transmitter 240 to receive data transmitted from switching center 100 via slave 430. Meanwhile, in case base station 141 transmits data to switching center 100, control unit 250 allows the transmitter 240 to transmit data to the switching center 100 via the master 440. Then, the control unit 220 of the switching center 100 allows the transmitter 210 to receive the data transmitted from the base station 141 via the slave 420 .

Now, descriptions will be made about how the switching center 100 transmits the frame synchronous signal 500 to the base station 141 via the transmitter 210. The control unit 220 allows the transmitter 210 to transmit the frame synchronous signal to the slave 430 of base station 410 via master 410. slave 430 transfers the received frame synchronous signal to master 440. master 440 transfers the frame synchronous signal to slave 420, to feed it back to switching center 100. Transmitter 210 transfers the synchronous frame signal fed back from the base station 141 to the delay detector 230. The delay detector 230 compares the synchronous frame signal fed back from the base station 141 with the synchronous frame signal that the switching center 100 has transmitted to base station 141, to detect a time delay of the frame synchronous signal. As illustrated in Figure 3, the delay detector 230 according to an embodiment of the present invention includes counter 302, buffer 304, and comparator 306. Counter 302 initiates a counting operation in response to the frame synchronous signal. transmitted to base station 141, and completes the counting operation in response to the synchronous frame signal fed back from base station 141. Buffer memory 304 temporarily stores the synchronous frame signal fed back from base station 141, and transfers it to comparator 306 in response to a control signal received from the control unit 220. The comparator 306 compares the signal 510 generated by the counter 302 with the frame synchronous signal 520 stored in the buffer 304, to detect the time delay of the synchronous signal of panel and providing the control unit 220 with the detected time delay information. The control unit 220 allows the transmitter 210 to transmit the time delay information to the base station 141. The master 410 transmits the time delay information of the frame synchronous signal to the slave 430. The slave 430 transfers the Time delay information of the frame synchronous signal received at the delay compensator 260. The delay compensator 260 delays or shortens the received frame synchronous signal in response to the time delay information, to compensate for the time delay of the frame synchronous signal . The control unit 250 controls the base station 141 based on the compensated frame synchronous signal. Such an operation is performed repeatedly between the switching center 100 and the respective base stations 141-14n, to detect and compensate for the time delay of the synchronous frame signal according to the difference in distance between the switching center 100 and the stations. respective base 141-14n.

Figure 6 is a block diagram of the delay detector 230 of Figure 2 according to another preferred embodiment of the present invention. In the drawing, the delay detector 230 includes a counter 600, temporary memories 610 and 620, and a subtractor 630. The counter 600 performs a counting operation upon receiving the synchronous frame signals fed back from the respective base stations 141- 14n. The buffer 610 stores a count value that the counter 600 generated by executing the counting operation upon receiving the synchronous frame feedback signal from a reference base station (for example, a base station closer to the center). switch 100). The temporary memory 620 stores a count value that the counter 600 has generated by performing the counting operation following the reception of the synchronous frame signal fed back from the remaining base stations other than the reference base station. The subtractor 630 subtracts a signal emitted by the temporary memory 610 from a signal emitted by the temporal memory 620, to generate a difference of signals between them.

Now, referring to Figures 2 and 6, descriptions will be made about how the delay detector 230 according to another embodiment of the present invention detects the time delay of the frame synchronous signal, according to the distance difference between the switching center. 100 and the respective base stations 141-14n. The delay detector 230 detects the single frame signals fed back from the respective base stations, based on the nearest base station (i.e., the reference base station) from the switching center 100. For example, in the case where base station 141 is the closest base station, buffer 610 temporarily stores the synchronous frame signal fed back from base station 141. Meanwhile, buffer 620 temporarily stores the frame synchronous signals fed back from the other control stations. base 141—14n. The subtractor 630 detects a signal difference between the feedback frame synchronous signals generated by the buffer 610 and 620. That is, the subtractor 630 detects a time delay difference between the feedback frame synchronous signal generated by the buffer 620 and the signal single feedback frame generated by the buffer 610. The subtractor 630 calculates the time delay differences between the reference time delay value (output of 610) and the time delay values (output of 620) of the respective signals frame synchronous, and provides control unit 220 with calculated temporary delay differences. The control unit 220 allows the transmitter 210 to transmit the time delay values of the synchronous frame signals to the corresponding base stations. Upon receipt of the delay values, the respective base stations 141-14n delay the frame synchronous signal if the delay value is negative, and shorten the frame synchronous signal if the delay value is positive. In the embodiment of the present invention, a regulation resistor FS in a CP23030 chip is used to delay or shorten the frame synchronous signal.

As can be understood from the foregoing descriptions, the digital radio communication system of the invention detects the time delay of the synchronous frame signal according to the difference in distance between the switching center and the respective base stations, to compensate for the time delay of the signal. frame synchronous, thus providing a stable call service even while switching the channel.

Although a preferred embodiment of the present invention has been described in detail hereinbefore, it should clearly be understood that many variations and / or modifications of the basic inventive concepts taught herein which may appear to those skilled in the art will still fall within the spirit of and the scope of the present invention as defined in the appended claims.

Claims (6)

R I V E N D I C A Z I O N I 1. Circuit for controlling a time delay of a frame synchronous signal in a digital radio communication system including a switching center for transmitting the frame synchronous signal to a plurality of base stations, said base stations instantaneously feeding the synchronous signal received back to said switching center, comprising :, a delay detector for comparing said frame synchronous signal transmitted to the base stations with said frame synchronous signal fed back by the base stations, to detect the time delay of said frame synchronous signal; And a delay compensator to compensate for the time delay of said synchronous frame signal. 2. A circuit for controlling a time delay of a frame synchronous signal according to claim 1, wherein said delay detector comprises: a temporary memory for storing said synchronous frame signal fed back from said base stations; a counter for initiating a counting operation in response to said frame synchronous signal transmitted to said base stations, and completing the counting operation in response to said frame synchronous signal fed back from said base stations; And a comparator for comparing said frame synchronous signal stored in said temporary memory with a count value emitted by said counter, to detect the time delay of said frame synchronous signal. . A circuit for controlling a time delay of a frame synchronous signal according to claim 1, wherein said delay detector comprises: a counter for carrying out a counting operation following the reception of the synchronous frame signals fed back from said respective base stations; a first temporary memory for storing a single frame signal fed back from a closer base station; a second buffer for storing synchronous frame signals fed back from base stations except said closest base station; And a subtractor for subtracting the synchronous frame signal stored in said first temporary memory from the synchronous frame signal stored in said second temporary memory, to calculate a signal difference between them. 4. A circuit for controlling a time delay of a frame synchronous signal according to claim 3, wherein said delay compensator delays the frame synchronous signal if said signal difference is negative, and shortens the frame synchronous signal if said difference of signal is positive. 5. A method for controlling a time delay of a synchronous frame signal in a digital radio communication system including a switching center and a plurality of base stations, comprising the steps which consist of: transmitting the frame synchronous signal from said switching center to said base stations; instantaneously feeding said frame synchronous signal back to said switching center from said base stations; And comparing said frame synchronous signal transmitted to said base stations with said frame synchronous signal feedback from said base stations, to detect the time delay of said frame synchronous signal. 6. A method for controlling a time delay of a synchronous frame signal according to claim 5, further comprising the step which consists in compensating for the time delay of said frame synchronous signal.