KR20000014855A - Frequency hopping/time division duplex type double mode terminal apparatus - Google Patents

Abstract

PURPOSE: A double mode terminal apparatus is provided to realize a network call mode and a direct call mode in a single terminal apparatus, using a frequency hopping/time division duplex (FH/TDD) method. CONSTITUTION: The apparatus comprises a duplexer (115) which receives a radio signal from the air and transmits the radio signal responding to a control signal, a receiving part (117) which inputs the radio signal received from the duplexer and demodulates the input signal into an original signal, a control part (111) which inputs and examines the demodulated signal and keeps a network call mode if the signal is a network call synchronizing signal and keeps a direct call mode if the signal is a direct call synchronizing signal, a double mode TDD timing part (121) which inputs the examined network call synchronizing signal to generate a TDD phase pulse for a network call and inputs the examined direct call synchronizing signal to generate a TDD phase pulse for a direct call, a memory (113) which stores a frequency data of a transmitting-and-receiving radio signal and a data of the moment responding to the operating of the control part, a transmitting part (119) which modulates a signal generated by the operating of the control part to a radio signal and transmits the radio signal to the duplexer. Thereby, the weight of the terminal apparatus is reduced as well as the manufacturing cost is lowered.

Description

Dual mode terminal equipment using frequency hopping / time division full duplex

The present invention relates to a terminal device using a frequency hopping / time division duplex (FH), and more particularly, a network call (NW) mode and a direct call (DC) mode. The present invention relates to a dual mode terminal device using a frequency hopping / time division full-duplex method in which the dual mode is implemented.

Typically, in a cellular system, when a terminal device exists in an area outside the cell area or in a poor service area of a cell, network communication through the base station cannot be made to the terminal device. Therefore, there was a demand for direct communication between the terminal and the other terminal period. In a conventional terminal device, a receiver for network call synchronization for a network call through a base station is provided, and a receiver for direct call synchronization for a direct call with another terminal is provided separately. Therefore, there is a problem in weight reduction of the terminal device because the terminal device should be provided with two receivers, and there is a problem of increased power consumption and price increase since two receivers should be provided.

Accordingly, an object of the present invention is to provide a dual mode terminal apparatus using a frequency hopping / time division full duplex method capable of implementing a network call mode and a direct call mode.

In order to achieve the above object, the present invention provides a duplexer for receiving a radio signal from the air and for transmitting a radio signal through an antenna according to a predetermined control, and inputting and inputting a radio signal received from the duplexer. A receiver which demodulates the signal into an original signal, and a signal demodulated by the receiver, inputs a signal and examines the input signal, and maintains the synchronous mode when the signal is a synchronous signal, or when the checked signal is a direct call In case of the synchronization signal, the control unit maintains the direct call mode and the network synchronizer signal checked by the control unit is input to generate a network call TDD phase pulse, and the direct call synchronization signal checked by the control unit is input to the direct call TDD phase pulse. A dual mode TDD timing unit for generating a signal, frequency data of a transmission / reception radio signal, channel information data, and And a memory for storing data temporarily generated according to a control operation of the controller, and a transmitter for wirelessly modulating a signal generated under the control of the controller and transmitting the signal to the duplexer.

1 is a block diagram illustrating an internal configuration of a dual mode terminal device for performing a function in an embodiment of the present invention.

FIG. 2 is a circuit diagram illustrating a configuration of the dual mode TDD timing unit of FIG. 1. FIG.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that in the following description, only parts necessary for understanding the operation according to the present invention will be described, and descriptions of other parts will be omitted so as not to distract from the gist of the present invention.

1 is a block diagram showing the internal configuration of a dual-mode terminal device for performing a function in an embodiment of the present invention, in particular using the frequency hopping / time division full-duplex method, and implements the network call mode and direct call mode It is a block diagram showing the internal structure of a dual mode terminal device.

The controller 111 performs an overall control operation of the dual mode terminal device. The memory 113 stores frequency data and channel information data, and stores temporary data generated according to the control operation of the controller 111.

The duplexer 115 receives a network signal from a base station of a cell located through the air and transmits it to the receiver 117. The receiver 117 inputs a signal received from the duplexer 115, demodulates the signal, and transmits the demodulated signal to the controller 111. The controller 111 inputs a signal received from the receiver 117 and inspects the signal. If the received signal is a network synchronizer signal of a base station where the dual mode terminal device is located, the control unit 111 checks synchronization data of the network synchronizer signal and performs synchronization between the base station and the terminal device. The control unit 111 then transfers the network synchronizer signal to the dual mode time division duplex (TDD) timing unit 121. The dual mode TDD timing unit 121 inputs a network synchronizer signal received from the controller 111 and generates a networked TDD phase pulse for implementing a network communication mode in correspondence to the network synchronizer signal to the controller 111. The control unit 111 switches the mode of the dual mode terminal device to the network communication mode in response to the network communication TDD phase pulse received from the dual mode TDD timing unit 121.

The control unit 111 inputs a signal received through the duplexer 115 and demodulated and transmitted by the receiving unit 117. If the signal is a direct call request signal for requesting a direct call from another terminal device, the control unit 111 inputs the signal and inspects the signal. The direct call synchronization signal of the signal is transmitted to the dual mode TDD timing unit 121. The dual mode TDD timing unit 121 inputs a direct call synchronization signal received from the control unit 111 and generates a direct call TDD phase pulse for implementing a direct call mode for direct communication with another terminal device according to the direct call synchronization signal. To the controller 111. The control unit 111 switches the mode of the dual mode terminal device to the direct call mode according to the direct call TDD phase pulse received from the dual mode TDD timing unit 121. In this case, when the mode of the dual mode terminal device is set to the network call mode, when the direct call request signal is received from the other terminal device, the control unit 111 maintains the network unit with the base station for the network call mode. In response to the signal, a direct call synchronization with another terminal device is performed.

The transmitter 119 wirelessly modulates the signal generated by the controller 111 and transmits the modulated signal to the air through the duplexer 115.

Accordingly, the dual mode terminal device configured as shown in FIG. 1 implements a direct call mode by performing a direct call synchronization with another terminal device requesting a direct call while maintaining a network call mode with a base station located therein. Makes it possible.

FIG. 2 is a circuit diagram illustrating an internal configuration of the dual mode TDD timing unit of FIG. 1.

The duplexer 115 of FIG. 1 receives an air signal through an antenna and transmits the signal to the receiver 117 of FIG. 1. The receiver 117 inputs a signal received from the duplexer 115, demodulates the input signal into an original signal, and transmits the original signal to the controller 111 of FIG. 1. The controller 111 inputs a signal received from the receiver 117 and inspects the signal. If the inputted signal is a network synchronizer signal for synchronizing with the base station where the dual mode terminal device is located, the control unit 111 loads the network synchronizer signal NW_RFSYNC from the network communication mode counter 211 (LD: load). ) Is input to the signal input terminal LD1, and the system clock is input at a predetermined system clock frequency, for example, TDD timing of a system clock of 40 KHz and Tx 5 ms and Rx 5 ms. The network call mode counter 211 starts operation in response to the input of the network synchronizer signal to the load signal input terminal LD1 and the input of the system clock. The network call mode counter 211 performs a counting operation, outputs a counted network synchronizer signal corresponding to the received network synchronizer signal, and transmits the counted network synchronizer signal to the input terminal A of the multiplexer 213.

In addition, if the signal received from the receiving unit 117 is a direct call synchronization signal, the control unit 111 transmits the direct call synchronization signal DC_RFSYNC to the load signal input terminal LD2 of the direct call mode counter 217, and also provides a predetermined system clock frequency. For example, the system clock is input with TDD timing of 40KHz, Tx 5ms, and Rx 5ms. In response to the input of the direct call synchronization signal to the load signal input terminal LD2 and the input of the system clock, the direct call mode counter 217 starts operation. The direct call mode counter 217 performs a counting operation, outputs a counted direct call synchronization signal corresponding to the received direct call synchronization signal, and transmits the counted direct call synchronization signal to the input terminal B of the multiplexer 213.

The multiplexer 213 inputs a network call mode / direct call mode selection signal NW / DC_SEL from the control unit 111, inputs a network synchronizer signal received from the network call mode counter 211, and outputs the signal from the direct call mode counter 217. A call synchronization signal is input directly, and operation starts in accordance with the input signal. The multiplexer 213 examines a network call mode / direct call mode selection signal received from the control unit 111. If the network call mode / direct call mode selection signal is a network call mode signal, the network synchronizer signal counting data received from the network call mode counter 211 is gated and transmitted to the decoder 215. The decoder 215 inputs the network synchronizer signal gating data to generate a network communication TDD phase pulse corresponding to the network synchronizer signal gating data. In this case, the number of the network communication TDD phase pulses is counted by the system clock and is a number obtained by dividing Tx 5ms / Rx 5ms 1 Cycle by the system clock period. That is, in one embodiment of the present invention, the networked TDD phase pulse may generate 400 symbols.

The multiplexer 213 gates the direct call synchronization signal counting data received from the network call mode counter 211 when the network call mode / direct call mode selection signal test result is the direct call mode signal. It passes to the decoder 215. The decoder 215 inputs the direct call synchronization signal gating data to generate a direct call TDD phase pulse corresponding to the direct call synchronization signal gating data. In this case, the number of the direct-call TDD phase pulses is the number divided by the system clock period by counting the system clock and Tx 5ms / Rx 5ms 1 Cycle. That is, in one embodiment of the present invention, the direct call TDD phase pulse may generate 400 symbols.

Thus, the dual mode TDD timing circuit as shown in FIG. 2 makes it possible to generate network talk TDD phase pulses and direct talk TDD phase pulses.

As described above, the present invention provides a dual mode terminal apparatus using the frequency hopping / time division full duplex method, so that the user can maintain the network synchronizer with the base station in the cell, that is, implement the network communication mode, It is possible to implement a direct call mode with another terminal device when there is a direct call request. Therefore, in the conventional terminal device, the receiver for network synchronization and the receiver for direct call synchronization for the direct call with the other terminal are not provided separately, thereby making it possible to reduce the power consumption and reduce the power consumption and the economical cost. Has an advantage.

Claims (4)

A dual mode terminal apparatus using a frequency hopping / time division full duplex method, A duplexer for receiving a radio signal from the air and for transmitting the radio signal through an antenna according to a predetermined control; A receiver which inputs a radio signal received by the duplexer and demodulates the input signal into an original signal; A control unit for inputting a demodulated signal at the receiving unit, and examining the input signal to maintain the synchronous mode when the signal is a synchronous signal, or maintaining the direct synchronous mode when the signal is a direct call synchronization signal; , A dual mode time division full-duplex timing unit configured to generate a network call time division full-duplex phase pulse by inputting a network synchronizer signal examined by the controller, and generate a direct call time division full-duplex phase pulse by inputting a direct call synchronization signal examined by the controller; , A memory for storing frequency data of transmission / reception radio signals, channel information data, and data generated temporarily according to a control operation of the controller; And a transmitter configured to wirelessly modulate a signal generated under the control of the controller and transmit the modulated signal to the duplexer. The method of claim 1, The dual mode time division full-duplex timing unit, A network call mode counter configured to receive an input of a network synchronizer signal and a system clock generated by the controller, and to output counting data counting the network synchronizer signal; A direct call mode counter for receiving a direct call synchronization signal generated by the controller and the system clock to start operation, and outputting counting data counting the direct call synchronization signal; Inputting a network synchronization mode / direct call mode selection signal generated by the control unit, a network synchronization signal counting data output from the network communication mode counter, and a direct call synchronization signal counting data output from the direct communication mode counter; A multiplexer for gating the synchronizer signal counting data when the network call mode / direct call mode selection signal is a network call mode selection signal; And a decoder configured to input network-synchronized signal gating data gated by the multiplexer to generate network-division time-division full-duplex phase pulses. The method of claim 2, And the multiplexer gates the direct call synchronization signal counting data when the input network call mode / direct call mode selection signal is a direct call mode selection signal. The method of claim 2, The decoder inputs the direct call synchronization signal gating data when the signal gated by the multiplexer is the direct call synchronization gating data to generate a direct call time division full duplex phase pulse. Mode terminal device.