KR960004957B1 - Transceiving delay time compensation method of digital communication terminal devices - Google Patents

Abstract

a transmission delay time measurement procedure which measures transmission delay time generated from a transmission means by receiving the transmitted test signal through a modulation apparatus after transmitting the test signal through the transmission means when the transmission delay measurement mode is established; a receiving delay time measurement procedure which measures receiving delay time generated from a receiving means by receiving the transmitted test signal through the receiving means after transmitting the test signal through a signal generation apparatus when receiving delay measurement mode is established; a delay modification procedure which permits the transmission data into the transmission means.

Description

Transceiver delay time correction method of digital communication terminal device

1 is a TDD transmission and reception timing diagram.

2 is a schematic block diagram of a general digital communication terminal device.

FIG. 3 is a timing diagram illustrating a delay in transmitting and receiving in FIG.

Figure 4 is a flow chart of the transmission and reception delay time correction according to the present invention.

5 is a diagram illustrating connecting a communication terminal device and a demodulation device to measure a transmission delay time of the communication terminal device.

6 is a diagram illustrating connecting a communication terminal device and a signal generating device to measure a reception delay time of the communication terminal device.

* Explanation of symbols for main parts of the drawings

2: duplexer 4: frequency synthesis unit

6: LNA 8: demodulator

10: data processor 12: modulator

14 amplifier 16 MPU

18: EEPROM 20: transceiver

22: communication terminal device 24: demodulation device

26: signal generator.

The present invention relates to a transmission / reception delay time correction method of a digital communication terminal device, and more particularly, to a transmission / reception delay time correction method for adaptively correcting a transmission / reception delay time for different transmission / reception delay characteristics of each communication terminal device.

In general, in digital communication using a time division duplexing (TDD) method or a time division muteple access (TDMA) method, synchronization with the other party must be precisely synchronized with each other. As an example, when two first and second communication apparatuses ST1 and ST2 communicate in a TDD scheme, as shown in FIG. 1, transmission and reception are alternately performed in time. That is, in one time period T _n , the first communication device ST1 transmits and the second communication device ST2 receives.

In the next time interval T _{n + 1} , on the contrary, the second communication device ST2 transmits and the first communication device ST1 receives.

In order for the transmission and reception to be performed alternately as described above, synchronization between the first and second communication devices ST1 and ST2 must be precisely performed.

In reality, however, a malfunction occurs due to an inconsistent synchronization and an error due to a delay of a signal generated by various circuit elements of a communication device. In particular, the delay caused by the filter, which is essential for the communication device, has a fatal effect on synchronization. For example, a SAW filter widely used in a transceiver of a communication device generates a delay of about 10 [mu] s. In addition, similar to the filter, in other circuit elements, a delay of several orders of magnitude occurs due to the transfer characteristics. CT-2, which is widely used in Europe and Southeast Asia, has a data transfer rate of 72Kbps and has a period of 13.88μ per bit. Accordingly, in the case of CT-2, data loss occurs because a delay of about 1 bit occurs during transmission and reception. In the case of wireless communication, the propagation speed of the signal is propagated at the speed of light, so the delay time due to the propagation can be ignored.

In order to prevent such a synchronization error, synchronization has been achieved by correcting the transmission and reception delay time by applying the transmission data to the transmitter of the communication device in advance as much as the delay time in consideration of the delay in transmission and reception. To this end, after calculating the average delay time by statistical scatter analysis to measure the delay time of transmission and reception for a plurality of communication devices for the same model, it is transmitted to the transmitter of the communication device in advance by the average delay time at the time of transmission. Transmission and reception delay time has been corrected by allowing data to be applied. Here, the transmission / reception delay time refers to a delay time obtained by adding a transmission delay time occurring in the transmission / reception section of the communication apparatus and a reception delay time occurring in the reception section of the communication apparatus.

On the other hand, even for the communication device of the same model, the transmission and reception delay time caused by the different transmission and reception delay characteristics for each communication device is different. Therefore, as described above, if the same average delay time is applied to all communication devices of the model, the transmission / reception delay time may not be corrected.

As described above, conventionally, the same delay time is applied to all communication devices of the corresponding model to correct the transmission and reception delay time, so that the deviation of each communication device is ignored, so that there is still a problem of synchronization error during transmission and reception.

Accordingly, an object of the present invention is to provide a transmission / reception delay time correction method capable of accurately correcting transmission / reception delay time with respect to different transmission / reception delay characteristics of each communication terminal device.

Another object of the present invention is to provide a transmission / reception delay time correction method capable of accurately correcting transmission / reception delay time with respect to average transmission / reception delay characteristics of communication terminal devices of a specific model and transmission / reception delay characteristics for each communication terminal device. have.

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

In the following description, it should be noted that like elements in the drawings represent like reference numerals wherever possible.

In addition, in the following description, numerous specific details such as specific circuit configurations and components or operating times are shown to provide a more general understanding of the invention. It will be apparent to those skilled in the art that the present invention may be practiced without these specific details.

2 is a schematic block diagram of a general digital communication terminal device to which the present invention is applied. In FIG. 2 the duplexer 2 separates the transmit and receive paths. That is, the output signal of the amplifier 14 is transmitted to the antenna or the signal received through the antenna is applied to the low noise amplifier (LNA) 6. The frequency synthesizer 4 generates a frequency corresponding to the transmission / reception channel under the control of the MPU 16 and applies it to the demodulator 8 and the modulator 12, respectively. The LNA 6 low-noise amplifies the received signal applied through the duplexer 2 and applies it to the demodulator 8. The demodulator 8 demodulates the signal input from the LNA 6 by the frequency output from the frequency synthesizer 4 and then applies it to the data processor 10. The data processor 10 encodes and transmits the transmission data to be transmitted to the modulator 12 when operating in the transmission mode under the control of the MPU 16, and inputs data from the demodulator 8 when operating in the reception mode. Decode and output The modulator 12 modulates the frequency output from the frequency synthesizer 4 by data applied from the data processor 10 and outputs the modulated frequency to the amplifier 14. The amplifier 14 amplifies the signal modulated by the modulator 12 and applies it to the duplexer 2. The MPU 16 controls the respective parts of the communication device as a whole and performs measurement and correction of the transmission / reception delay time according to the flowchart of FIG. 4 as described later. The EEPROM 18 stores the average transmission delay time, average reception delay time, and the like as described above. In FIG. 2, the demodulator 8 and the modulator 12 have various filters therein as described above. In addition, a portion composed of the duplexer 2, the frequency synthesizer 4, the LNA 6, the demodulator 8, the modulator 12, and the amplifier 14 becomes the transceiver 20, and the transceiver ( In 20, a portion consisting of the modulator 12, the amplifier 14, and the duplexer 2 becomes a transceiver, and a portion composed of the duplexer 2, the LNA 6, and the demodulator 8 becomes a receiver.

FIG. 3 is a timing diagram showing that a transceiver delay occurs in FIG.

4 is a flow chart of the transmission and reception delay time correction according to the present invention, after measuring the unique transmission delay time and the reception delay time for each communication terminal device, and adding the transmission delay time and the reception delay time during the transmission operation. The execution of the MPU 16 which transmits transmission data in advance by time is shown.

5 illustrates the connection of the communication terminal 22 and the demodulation device 24 to measure the transmission delay time of the communication terminal device 22 as shown in FIG. 2. The demodulation device 24 is connected to the MPU 16 by FIG. ). The demodulator 24 uses a conventional demodulation analyzer.

6 illustrates an example in which the communication terminal 22 and the signal generator 26 are connected to measure the reception delay time of the communication terminal 22 as shown in FIG. 2, and the signal generator 26 is connected to the MPU. Connect with (16). The signal generator 26 uses a conventional modulator.

Hereinafter, with reference to Figures 2 to 6 attached to the operation example of the present invention will be described in detail.

In the present invention, as shown in FIG. 5, the communication terminal device 22 is connected to the demodulation device 24, and the transmission delay measurement mode is set to measure the transmission delay time occurring in the transmission unit of the communication terminal device 22. As described above, the communication terminal device 22 is connected to the signal generator 26 and set to a reception delay measurement mode to measure the reception delay time generated at the receiving unit of the communication terminal device 22. Accordingly, a unique transmission and reception delay time is measured for each communication terminal device. At this time, the transmission delay measurement mode and the reception delay measurement mode are set as one of the test modes of the MPU 16, respectively. Next, the transmission / reception delay time is correctly corrected by applying the transmission data to the transmitter in advance as much as the transmission / reception delay time measured as described above.

First, as shown in FIG. 5, when the communication terminal 22 and the demodulator 24 are connected, the MPU 16 is set to the transmission delay measurement mode, and the power is turned on, the MPU 16 proceeds to step 402 of FIG. In step 404, it recognizes that the test mode is set. In step 404, it is checked whether the test mode is a transmission delay measurement mode. At this time, since the transmission delay measurement mode is set, step 406 is performed. In step 406, the transmission delay time T _DS generated by the transmitter is measured. This will be described in more detail as follows. First, the MPU 16 applies a preset test signal to the data processor 10. Here, the test signal may be set to data having a specific pattern. The test signal applied to the data processor 10 is modulated and transmitted at the transmitter. The demodulator 24 then receives and demodulates the signal transmitted from the transmitter and applies it to the MPU 16. Therefore, when the delay time of the demodulation device 24 and the data processor 10 is constant, the transmission delay time can be measured. That is, since the delay time generated during the transmission is the sum of the delay times generated by the data processor 10, the transmitter, and the demodulator 24, the delay time of the data processor 10 and the demodulator 24 is excluded. The transmission delay time T _DS generated at the transmitter can be calculated. Thereafter, in step 408, the deviation between the measured transmission delay time T _DS and the average transmission delay time T _DA , that is, the transmission delay deviation T _D is calculated and stored in the EEPROM 18 in step 410, and then ends. Here, the average transmission delay time T _DA refers to the average delay time at the time of transmission calculated by statistical dispersion analysis by measuring the delay time at the time of transmission for a plurality of communication devices with respect to the same model as described above. Save it in advance).

Next, as shown in FIG. 6, when the communication terminal device 22 and the signal generator 26 are connected, the MPU 16 is set to the reception delay measurement mode, and the power is turned on, the MPU 16 is connected to (402) in FIG. Recognizing that the test mode is set in step 404 is performed. In step 404, it is checked whether the test mode is a transmission delay measurement mode. At this time, since it is set to the reception delay measurement mode, step 412 is performed to recognize that the reception delay measurement mode is performed, and step 414 is performed. In step 414, the reception delay time R _DS generated by the receiver is measured. This will be described in more detail as follows. First, the MPU 16 applies the test signal as described above to the signal generator 26. The signal generator 26 modulates and transmits an applied test signal. Then, the receiving unit receives and demodulates the signal transmitted from the signal generator 26 and applies it to the data processor 10, and the data processor 10 applies it to the MPU 16. Therefore, when the delay time between the signal generator 26 and the data processor 10 is constant, the reception delay time R _DS can be measured. That is, since the delay time generated upon reception is the sum of the delay times generated by the signal generator 26, the receiver and the data processor 10, the delay time between the signal generator 26 and the data processor 10 is increased. If not, the reception delay time R _DS generated by the receiver can be calculated. Thereafter, in step 416, the deviation between the measured reception delay time R _DS and the average reception delay time R _DA , that is, the reception delay deviation R _D is calculated and stored in the EEPROM 18 in step 418, and then ends. Here, the average reception delay time R _DA refers to the average delay time at the time calculated by statistical dispersion analysis by measuring the delay time at the time of receiving a plurality of communication devices for the same model as described above. Save it in advance).

After the communication terminal 22 is set to the normal operation mode for the MPU 16 without connecting the demodulator 24 or the signal generator 26 as shown in FIG. If it is turned on, the MPU 16 checks whether or not the test mode is set in step 402 and is not a test mode. Therefore, in step 420, the average transmission delay time T _DA , the average reception delay time R _DA, and the transmission delay deviation T _{D are determined.} Calculate the intrinsic delay time T _DT plus the reception delay deviation R _D and store it in the EEPROM 18 in step 422. Next, in step 424, the communication mode is checked, and in case of the reception mode, the normal reception mode is performed as is in step 428. In the case of transmission mode, the transmission data is operated while operating in the normal transmission mode in step 426. It is applied to the transmitter in advance as much as the intrinsic delay time T _DT . Therefore, the transmission and reception delay time is corrected accurately. Thereafter, if the power is turned off in step 430, the process ends. If the power is not turned off, the process is performed again from step 424.

Therefore, the transmission and reception delay time is accurately corrected for the transmission and reception delay characteristics that are different for each communication terminal device.

Meanwhile, in the above described average transmission delay time T _DA and the average reception delay time R _DA and the transmission delay deviation T _D and received in addition all of the delay deviation R _D, but illustrates that for calculating a specific delay T _DT, transmission delay deviation T _D And transmit delay time _TDS is corrected for each communication terminal device even if the delay time T _DS and the delay time R _{DS which} are measured as described above are added together without considering the delay delay difference R _D. can do. However, when the inherent delay time T _DT is set in consideration of the transmission delay deviation T _D and the reception delay deviation R _D , when the transmission delay time T _DS and the reception delay time R _DS cannot be measured for the communication terminal device, It is to allow a correction as in the prior art.

As described above, the present invention has the advantage that the synchronization error can be prevented by adaptively correcting the transmission / reception delay time with respect to different transmission / reception delay characteristics for each communication terminal device.

Claims (3)

A digital communication terminal having a transmitting means for modulating and transmitting input transmission data, a receiving means for demodulating data from a received signal, a nonvolatile memory means and a control means, and a predetermined schedule set by the control of the control means. A signal generator for transmitting a test signal of a pattern and a demodulator for demodulating data from a received signal, the method for correcting a transmission / reception delay time of the communication terminal device, wherein the transmission when the transmission delay measurement mode is set A transmission delay time measurement process for measuring a transmission delay time generated by the transmission means by transmitting the test signal through the means and receiving the transmitted test signal through the demodulation device, and when the reception area measurement mode is set The test signal is transmitted through the signal generator and the test signal transmitted is transmitted through the receiving means. A reception delay time measurement process for measuring a reception delay time generated by the reception means by receiving the transmission data in advance by an inherent delay time plus the transmission delay time and the reception delay time when operating in a transmission mode; Transceiving delay time correction method of a digital communication terminal device characterized in that it comprises a delay correction process applied to. 2. The transmission and reception of a digital communication terminal apparatus according to claim 1, wherein the transmission delay time measurement process and the reception delay time measurement process include storing the measured transmission delay time and the reception delay time in the memory means, respectively. Delay time correction method. Transmission means for modulating and transmitting input transmission data, reception means for demodulating data from received signals, nonvolatile memory means for storing in advance average transmission delay time and average reception delay time for a plurality of communication terminal apparatuses; And a digital communication terminal device having a control means, a signal generator for transmitting a test signal of a predetermined pattern preset by the control means, and a demodulation device for demodulating data from the received signal. A method for correcting a transmission / reception delay time of an apparatus, the method comprising: transmitting the test signal through the transmission means and receiving the transmitted test signal through the demodulation device when the transmission delay time measurement mode is set; After measuring the transmission delay time that occurs, between the measured transmission delay time and the average transmission delay time A transmission delay time measurement process for storing a new delay deviation in the memory means, and when the reception delay time measurement mode is set, transmitting the test signal through the signal generator and receiving the transmitted test signal through the reception means. A reception delay time measurement process of storing a reception delay difference between the measured transmission delay time and the average reception delay time in the memory means after measuring the reception delay time generated by the reception means by Transmitting and receiving of the digital communication terminal apparatus comprising a delay correction process of applying the transmission data to the transmitting means in advance by the inherent delay time plus the average transmission delay time, the average reception delay time, and the transmission delay deviation and the reception delay deviation. Delay time correction method.