KR100382520B1 - Multi Channel Data Interface Method in Radio Communication System - Google Patents

Abstract

The present invention reduces the number of signals required for an interface in a system in which a transmission system and a reception system are synchronized with the same clock and transmit and receive multi-channel data in frame units using data sinks such as data symbols and data strobes in a mobile communication system. The present invention relates to a multi-channel data interface method in a mobile communication system. As described above, the present invention provides a method for determining whether there is data to be transmitted in a communication system transmitting an arbitrary channel, synchronizing and transmitting data to a clock according to the checking result, and transmitting the data. Comparing the transmission channel index with the channel to which the data is to be transmitted, increasing the transmission channel index after loading data in the data symbol according to the comparison result and informing that the data is to be transmitted to this channel; Determining whether the transmission channel index exceeds the total channel number range, and if the transmission channel index does not exceed the total channel number range, feeds back to the comparison step, and when the total channel number range is exceeded, Terminating the data transfer.

Description

Multi-channel data interface method in mobile communication system

The present invention reduces the number of signals required for an interface in a system in which a transmitting system and a receiving system transmit and receive multi-channel data in units of frames using data sinks such as data symbols and data strobes in synchronization with the same clock in a mobile communication system. The present invention relates to a multi-channel data interface method in a mobile communication system.

In general, in the conventional data interface method using a multi-channel, as the number of channels increases, the number of signals required for the interface increases linearly.

1 is a block diagram showing a configuration of a multi-channel data interface device between a conventional transmission and reception system, and FIG. 4 is a timing diagram for explaining an operation of transmitting and receiving data by dividing an arbitrary channel in units of frames in the above-described manner.

Referring to Fig. 1, the transmission system is composed of a plurality of sub transmission systems under the main transmission system. If there is data to be transmitted in the channel 1 transmission system, the data strobe of channel 1 is low and the data is loaded on the data symbol of channel 1 in synchronization with a clock as shown in the timing diagram shown in FIG. Any channel N transmission system from the channel 2 transmission system transmits data in the same manner. To signal the end of a frame in a channel-1 transmission system, the channel1's data sink is sent low in synchronization with the clock. The channel 2 transmission system and the channel N transmission system announce the end of the frame in the same manner. Therefore, each channel transmits and receives data in units of frames in the same timing form.

2 is a flowchart for explaining the operation of the transmission system of any channel operating in the same manner as the above-described transmission and reception system.

Referring to FIG. 2, a random channel for transmitting data in a transmission system maintains a data strobe and a data sink of an initial value of 1 (S21).

If the data is transmitted or not (S22), if the data is transmitted, the data strobe is low (Low), the data is loaded on the data symbol of the channel and transmitted to the receiving system (S24).

However, when the data is not transmitted, it is checked whether to transmit the sink (S23). When performing the sync transmission, the data sink value is set to 0 and the data is loaded on the data symbol (S25).

3 is a flowchart for explaining an operation of a reception system of an arbitrary channel.

Referring to Fig. 3, the receiving system is configured from the channel 1 receiving system to an arbitrary channel N receiving system similarly to the transmitting system. In the channel 1 receiving system, the data strobe of channel 1 is irradiated in synchronization with a clock (S32). If the channel 1 signal is low, data is received from the data symbol of channel 1 (S34). From the channel 2 receiving system to the channel N receiving system, the end of the frame is recognized in the same manner to configure the frame.

Like the transmission system, each channel transmits and receives data in frame units at the same timing.

However, in the multi-channel data interface method using the above-described conventional method, each signal except for a clock is required as many as the number of channels in the case of a transmission / reception system for transmitting and receiving multi-channel data. Since the number of necessary signals is increased, there is a problem in that a lot of cost is generated accordingly.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems of the prior art, and in a mobile communication system, a transmission system and a reception system are synchronized with the same clock and use data sinks such as data symbols and data strobes. The present invention relates to a multi-channel data interface method in a mobile communication system capable of reducing the number of signals required for an interface in a system for transmitting and receiving a frame unit.

According to an aspect of the present invention for achieving the above object, a multi-channel data interface method in a mobile communication system comprises the steps of checking whether there is data to be transmitted in a communication system for transmitting any channel; Synchronizing and transmitting data to a clock according to the checking result; comparing a transmission channel index and a channel to transmit the data in the process of transmitting the data; and loading the data into data symbols according to the comparison result. Increasing the transmission channel index after notifying that the data is transmitted to this channel, determining whether the increased transmission channel index exceeds the total channel number range, and exceeding the total channel number range according to the determination result. If not, feedback to the comparison step, the entire channel If hayeoteul exceeds the range, a step of terminating the data transmission.

Preferably, if the transmission channel index is different from the channel to transmit the data according to the comparison result, the clock with the data strobe high is maintained to indicate that data is not transmitted to this channel. Alternatively, if the transmission channel index is the same as the channel to which data is to be transmitted, data is transmitted to the channel while the clock having the data strobe low is maintained.

In addition, the channel transmission method for transmitting the data is performed through a unified transmission system, and the method for receiving the transmitted data is also performed through any unified channel reception system.

1 is a block diagram showing the configuration of a multi-channel data interface device between conventional transmission and reception systems.

2 is a flow chart for explaining the operation of the transmission system of any channel operating in the same manner as the above-mentioned transmission and reception system.

3 is a flowchart for explaining an operation of a reception system of an arbitrary channel.

4 is a timing diagram illustrating an operation of transmitting and receiving data by dividing an arbitrary channel in units of frames in the above-described manner.

Hereinafter, a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

5 is a block diagram showing a device configuration of a multi-channel interface according to the present invention.

Referring to FIG. 5, the conventional N arbitrary channel transmission systems are unified into one transmission system, and the N arbitrary channel reception systems are also unified into one reception system.

If a transmission / reception system is driven through this structure, only data symbols and data strobes exist for the signals required for the interface regardless of the number of channels.

This operation of the transmission and reception system according to the present invention will be described in more detail.

6 is a flowchart of a transmission system operating in the above manner.

Referring to FIG. 6, in the initial state, the transmission system maintains the data strobe high (data strobe = 1) and the transmission channel index is 1 (S600).

Check whether there is data to be transmitted (S601).

If there is no data to send or no frame sink is sent to indicate the end of the frame, the initial state is maintained.

If there is data to be sent, it enters a process of transmitting frame data by keeping the data strobe low (Data strobe = 0) at the first clock in synchronization with the clock (S603 and S604).

In the process of transmitting the frame data, a transmission channel index is compared with a channel for transmitting data (S605). As a result of the comparison, if the transmission channel index is different from the channel to which data is transmitted (S607), the clock is held with the data strobe high (Data strobe = 0), indicating that no data is transmitted to this channel. After that, the transmission channel index is increased by one (S608). If the comparison shows that the transmission channel index is the same as the channel to which the data is to be transmitted, data is sent to this channel by loading data in the data symbol while keeping the data strobe low (Data strobe = 0). After notifying (S606), the transmission channel index is increased by one.

Next, it is compared whether the transmission channel index is larger than the total number N of channels (S609).

If it is not large, since the data corresponding to all channels have not been transmitted, the process returns to comparing the transmission channel index with the channel to transmit the data. If the comparison is greater than N, all data has been transferred and will return to its initial state.

After the frame transmission is completed, the clock is synchronized to the clock (S602), and the data strobe is low (S610) for the first clock and high (S611) for the second clock to enter the process of transmitting the frame sync.

In the process of transmitting the frame sink, the transmission channel index is compared with the channel to which the frame sink is to be transmitted (S612). As a result of the comparison, if the transmission channel index is different from the channel to which the frame sink is to be transmitted, the data strobe is held high (Data strobe = 1) (S614) to indicate that the frame sink is not transmitted to this channel before transmission. The channel index is increased by 1 (S615).

If the comparison shows that the transmission channel index is the same as the channel to which the frame sink is to be transmitted, the clock with the data strobe low (Data strobe = 0) is maintained (S613), indicating that the frame sink is transmitted to this channel. After that, the transmission channel index is increased by one (S615).

Next, it is compared whether the transmission channel index is larger than the total number N of channels (S616). If the comparison result is not large, the frame sinks corresponding to all channels are not transmitted. Therefore, the process returns to comparing the transmission channel index and the frame sink with the channel to be transmitted. If the comparison is greater than N, all frame syncs have been transmitted and are returned to the initial state.

Next, Fig. 7 is a flowchart of a receiving system operating in the above manner. Referring to FIG. 7, the operation of the reception system will be described. First, the reception system maintains the reception channel index to 1 at an initial state (S700). The received data strobe is checked to stay in the initial state if the data strobe is High (Data strobe = 1) (S701).

If the received data strobe is low (S702), the data strobe is checked again at the next clock, and the low level (S703) frame data is received (S704). Enter the process of receiving.

In the process of receiving the frame data, since the data strobe is checked and it is known that no data is transmitted to this channel, the reception channel index is increased by one without receiving data (S705).

If the result of the test is low, the data is transmitted to this channel. Therefore, the data received in the data symbol is received in the channel corresponding to the reception channel index, and then the reception channel index is increased by one. Next, it is compared whether the reception channel index is larger than the total number N of channels (S706). If it is not large, data corresponding to all channels are not received, and thus, the process returns to the process of checking the data strobe as shown in the timing diagram of transmitting and receiving data in units of frames according to the present invention shown in FIG. 8. If the comparison is greater than N, all data has been received and it will return to its initial state.

In the process of receiving the frame sync, the data strobe is checked and it is found that the frame sync is not transmitted to this channel when high, so that the receiving channel index is increased by 1 without receiving the frame sync.

If the result of the check is low, the frame sink is transmitted to this channel. Therefore, after receiving the frame sink in the channel corresponding to the receiving channel index (S708), the receiving channel index is increased by one (S709).

Next, it is compared whether the reception channel index is greater than the total number N of channels (S710). If it is not large, frame sync for all channels is not received, and the process returns to checking the data strobe. If the comparison is greater than N, all frame syncs have been received and are returned to the initial state.

According to the present invention mentioned above has the following effects.

In the multi-channel data interface method according to the present invention, when the transmission system and the reception system are synchronized with a clock, the number of channels for transmitting and receiving data increases in a system that transmits data of a multi-channel by data symbols, data strobes, and data sinks in units of frames. Although there is a problem that the number of signals required for the interface increases, the present invention can be usefully used in a system in which the number of signals required for the interface is limited by suggesting a new method, and the effect increases as the number of channels increases.

Claims (3)

Checking whether there is data to be transmitted in a communication system transmitting any channel; Synchronizing and transmitting data to a clock according to the checking result; Comparing a transmission channel index with a channel to transmit the data in the process of transmitting the data; Increasing the transmission channel index after loading data in the data symbol according to the comparison result and notifying that data is transmitted on this channel; Determining whether the increased transmission channel index exceeds a total channel number range; In the mobile communication system, if the total channel number range is not exceeded according to the determination result, the feedback step is fed back to the comparison step, and when the total channel number range is exceeded, the data transmission is terminated. Multi-channel data interface method. The method of claim 1, wherein in the comparing step, If the transmission channel index is different from the channel to which the data is to be transmitted according to the result of the comparison, it is notified that data is not transmitted to this channel by keeping the clock with the data strobe high or transmitting the data. And if a channel index is equal to the channel to which data is to be transmitted, transmitting data to the channel while maintaining a clock with the data strobe low. The mobile communication system of claim 1, wherein the channel transmission method for transmitting the data is performed through a unified transmission system, and the method for receiving the transmitted data is also performed through any unified channel receiving system. Multi-Channel Data Interface Method in.