KR100400265B1 - Time hopping circuit for time slot division in TD-CDMA - Google Patents

Abstract

According to the present invention, a time slot is hopped for each frame in accordance with a hop code string of a plurality of code-divided users who share one time slot in a TD-CDMA scheme. Time-division allows individual users to be allocated different time slots to distribute the traffic traffic over time slots and distribute them statistically uniformly to increase the number of code-divided subscribers that can be accommodated in each time slot. The present invention relates to a time hopping apparatus for time slot allocation in a CD.

To this end, the present invention provides a first spreading quadrature channel code generator for simultaneously generating a code sequence for channel spreading at one output terminal and a code sequence for generating a hopping offset at the other output terminal at each output period, and the first spreading channel code generator. A first hopping sub code generator for generating a code string for determining a hop offset by receiving a hopping code string output from an orthogonal channel code generator and sub-coding each frame period, and outputting from the first hopping sub code generator A first hop offset generator that receives a code string for determining a hop offset to be generated and generates a hop offset for determining a time slot to hop in the next frame, and then adds a hop offset from the first hop offset generator and a slot index. A first adder for determining a time slot of the frame, A transmitter for determining a time slot of a next frame and transferring hopping code phase information and a slot index to a receiver;

A second spreading orthogonal channel code generator for receiving the hopping code phase information output from the transmitter to generate a code sequence for channel spreading, and a hopping code string output from the second spreading orthogonal channel code generator; A second hopping sub code generator for generating a code string for determining a hop offset by sub-coding each frame period, and a code frame for determining a hop offset output from the second hopping sub code generator. A second hop offset generator for generating a hop offset for determining a timeslot to hop at, and a second adder for determining a time slot of a next frame by adding a hop offset from the second hop offset generator and a slot index. It is configured to include a receiver, and evenly distributes the traffic in use By maintaining a constant ratio of spreading power and reverse spreading power in a timeslot, signal interference and traffic jams can be reduced, thereby increasing the number of subscribers of a next-generation mobile communication terminal per time slot.

Description

Time hopping circuit for time slot division in TD-CDMA

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to time slot allocation in TD-CDMA. In particular, a plurality of code-divided users sharing one time slot can be assigned to an individual hop code column. Code-sliced subscription that can be accommodated for each time slot by distributing traffic in time slots and distributing traffic in time slots by individually hopping time slots for each time slot. The present invention relates to a time hopping apparatus for time slot allocation in a time division-CD.

As is well known, Time Division-Code Division Multiple Access (TD-CDMA) is one of the standard methods of the next generation mobile communication terminal (IMT-2000), and is an asynchronous (W) frequency division duplex (FDD) method. Unlike the CDMA and the synchronous CDMA2000, a TDD (Time Division Duplex) method simultaneously performs transmission and reception at one frequency.

TD-CDMA (TD-CDMA) is a combination of CDMA direct spread technology and TDMA. The CDMA method, which spreads each timeslot into a series of code sequences, is mixed and made available to multiple users.

As shown in Fig. 1, the TD-CDMA structure proposed by the European Telecommunications Standard Institute (ETSI) of Europe is basically composed of 15 timeslots of 10 frames per frame. Both uplink and downlink can be used. In this case, at least one slot should be allocated to uplink and downlink in one frame, and time slots may be symmetrically or asymmetrically assigned to uplink and downlink according to a purpose.

However, since the conventional TD-CDMA structure employs a fixed allocation scheme using the same timeslot allocated for each frame, traffic may be concentrated in one specific timeslot.

As a result, many users using the same timeslot use spread spectrum code division (DS-CDMA) to exclude interference from each other. However, when traffic is concentrated in a specific timeslot, the user may despread it. The power ratio of the spread interference signals to the power of the signal is increased, which causes a decrease in call quality or traffic jamming, thereby lowering CDMA subscriber capacity per timeslot.

Therefore, the present invention is proposed to solve the above problems of the prior art,

Fixed timeslot per frame by multiple CDMA users sharing one timeslot

By differently assigning each frame to a code sequence that has a set of statistical characteristics, instead of using C, multiple CDMA users sharing time slots in the current frame share the same timeslot again in the next frame. By reducing the probability of doing so, the traffic in use is uniformly distributed to maintain the ratio of spreading power and reverse spreading power in each time slot to reduce signal interference and traffic jam, thereby reducing the number of subscribers of next generation mobile communication terminals. It is an object of the present invention to provide a time hopping device for time slot allocation in a time division-CD.

The present invention for achieving the above object,

A first spreading quadrature channel code generator for generating a code sequence for channel spreading at one output terminal and a code sequence for generating a hopping offset at every other frame period, and at the first spreading quadrature channel code generator A first hopping sub code generator for generating a code string for receiving a hopping code string to be output and sub-coded every frame period to determine a hop offset, and a hop offset output from the first hopping sub code generator is determined. A first hop offset generator for generating a hop offset for determining a time slot to hop in the next frame by receiving a code string, and adding a hop offset and a slot index from the first hop offset generator to obtain a time slot of a next frame. A first adder for determining the time of the next frame Sending unit for determining the blots, and the transmission phase information and the code hopping slot index for the receiver and;

A second spreading orthogonal channel code generator for receiving the hopping code phase information output from the transmitter to generate a code sequence for channel spreading, and a hopping code string output from the second spreading orthogonal channel code generator; A second hopping sub code generator for generating a code string for determining a hop offset by sub-coding each frame period, and a code frame for determining a hop offset output from the second hopping sub code generator. A second hop offset generator for generating a hop offset for determining a timeslot to hop at, and a second adder for determining a time slot of a next frame by adding a hop offset from the second hop offset generator and a slot index. Characterized in that it comprises a receiver.

In addition, the code string output from one output terminal of the first or second spreading orthogonal channel code generator is a channel spreading orthogonal channel code having a fast period, and the code string output from the other output terminal is a hopping having a slow period. Characterized in that the code.

In addition, the first or second hopping sub code generator is characterized in that the hopping code having a slow period is sub-coded for each frame period to bundle and generate a chip of a certain length.

The first or second hop offset generator may generate a hop offset for each frame period by deciphering a hopping code sequence generated by the first or second hopping sub code generator.

1 is a structure of a conventional time division-CD-DMA (TD-CDMA).

2 is a block diagram of a transmitter of a time hopping apparatus for time slot allocation according to the present invention;

3 is a block diagram of a receiver of a time hopping apparatus for time slot allocation according to the present invention;

* Description of the symbols for the main parts of the drawings *

10, 50: orthogonal channel code generator for first and second spreading

20, 60: sub code generator for first and second hopping

30, 70: first and second hop offset generators 40, 80: first and second adders

100: transmitter 200: receiver

Hereinafter, the present invention will be described with reference to the accompanying drawings.

2 is a block diagram illustrating a transmitter of a time hopping apparatus for time slot allocation according to the present invention, and FIG. 3 is a block diagram of a receiver of a time hopping apparatus for time slot allocation according to the present invention.

As described above, the present invention is largely divided into a transmitter and a receiver, and functionally, a time hopping function for statistically and uniformly distributing call traffic in each time slot, and a time when each user of the transmitter and the receiver hops for communication. It has a synchronization function for synchronizing slots.

In addition, a method of generating a hopping code sequence includes generating a code sequence using a channel spreading code sequence of TD-CDMA and a separate hopping code generator using a code sequence having statistical characteristics such as pseudo noise (PN) codes. There may be a method. In the present invention, a method using a channel spreading code sequence of TD-CDMA will be described as an example.

As shown in FIG. 2, the transmitter 100 generates a code sequence for channel spreading at one output terminal and a spreading quadrature channel code generator for simultaneously generating a code sequence for generating a hopping offset at each output period. A hopping sub code generator 20 for receiving a hopping code string output from the spreading orthogonal channel code generator 10 and generating a code string for determining a hop offset by sub-coding each frame period. And a hop offset generator 30 that receives a code string for determining a hop offset output from the hopping sub code generator 20 and generates a hop offset for determining a time slot to hop in a next frame. The hop offset from the offset generator 30 and the slot index are added to determine the time slot of the next frame. It has been composed of a divider (40).

In addition, as shown in FIG. 3, the internal block structure of the receiver 200 is substantially the same as that of the transmitter 100, except that a hopping code sequence such as a transmitter is performed after time synchronization between the transmitter and the receiver is performed. And a slot index for allocating the phase information of the code string from the transmitter to generate the same time slot as the transmitter.

That is, a second spreading orthogonal channel code generator 50 which receives the hopping code phase information output from the transmitter 100 and generates a code sequence for channel spreading, and the second spreading orthogonal channel code generator 50. A second hopping sub code generator 60 for generating a code sequence for determining a hop offset by receiving the hopping code string outputted from the subfield and sub-coding each frame period, and the second hopping sub code generator 60. A second hop offset generator 70 for receiving a code string for determining a hop offset output from the second hop offset generator and generating a hop offset for determining a time slot to hop in the next frame, and from the second hop offset generator 70. And a second adder 80 for determining the time slot of the next frame by adding the hop offset and the slot index.

The operation of the time hopping apparatus for time slot allocation according to the present invention configured as described above is as follows.

First, in the present invention, the transmitting side does not transmit an output signal when the user who occupies the time slot is not in use (i.e., there is no data to be sent), and when the user is in use (i.e., there is data to be sent). It will be described under the assumption that it is a gated transmission mode for transmitting an output signal only.

First, a first hopping subcode generator for generating a code sequence for determining a hop offset in the first hop offset generator 30 at a front end of the first hop offset generator 30 for determining a time slot to hop in a next frame. (20) is connected.

When the first hopping sub code generator 20 uses the TD-CDMA orthogonal channel code, the TD-CDMA channel spreading code is used in a sub code sequence for each frame. A first spreading orthogonal channel code generator 10 of CDMA is connected.

In this case, the first spreading orthogonal channel code generator 10 used in the TD-CDMA has a fast cycle (Chip Rates unit) code sequence for channel spreading through one output terminal (3.84 for the TD-CDMA of the ETSI standard). Mchips / s) and the slow output code string (400 chips / s when applied to ETSI's TD-CDMA) to generate a hopping offset once per frame by referring to the frame period through the other output stage. At the same time.

In the hopping sub code generator 20, the hopping code of the slow period is converted into a sub code string (in units of 4 chips when applied to TD-CDMA of ETSI) for each frame period and output to the hop offset generator 30.

The hopping sub code sequence is generated by referring to the frame clock. When using a channel code of TD-CDMA, the hopping code sequence of a slow cycle is sub-ordered considering the frame period, that is, a constant length K = log Create a bundle of ₂ M chips (M = number of timeslots).

In this case, a slow-period hopping code for hopping is generated with a period K = log ₂ M (M = number of timeslots) times faster than the frame period, and is then bound by K pieces of frame-length hopping subcode sequences. Create At this time, when the K value is not an integer, the integer is rounded up.

The first hop offset generator 30 decodes the generated hop code sequence and generates a hop offset for each frame period, and outputs the hop offset to the first adder 40.

In the first adder 40, a slot index added separately and the hop offset are added to determine a time slot in a next frame. The hopping code generated by the first spreading channel code generator 10 should have not only random and orthogonal characteristics but also run properties when the sub code deteriorates. do.

Time Division-Each user spread with a channel code such as TD-CDMA scheme is given a slot index. The slot index refers to a number for allocating each time slot. Indicates the sort order. The number of slot indices is equal to the number of time slots. For example, if there are 15 time slots in a frame, one of 0 to 14 or a plurality of timeslots as necessary. In the TD-CDMA scheme, a plurality of users are shared by using a spread spectrum scheme for each timeslot, such that slot index columns exist as many spreading codes as are used.

Due to the nature of the hopping code sequence, the number of hop offsets is equally stochastic and random, so the probability that multiple users who share one time slot will generate the same hop offset is low. In other words, the probability of meeting in the same time slot in the next frame is lowered so that the traffic in the call can be statistically distributed evenly over the low time slot.

The receiver 200 initially receives the hopping code phase information and the slot index of the transmitter from the transmitter.

First, the second spreading quadrature channel code generator 50 on the receiving side generates the same hopping code sequence having the same phase and the same slow period as the transmitting side by using the hopping code phase information received from the transmitting side.

When the hopping code sequence generated as described above passes through the second hopping sub code generator 60 and the second hop offset generator 70 in the same manner as the transmitting side, the same hop offset as the transmitting side is generated for each frame. When this is added to the slot index received from the transmitting side through the second adder 80, the same time slot as the transmitting side is determined, so that the synchronization of the transmitting side and the time slot can be performed for each frame.

As described above, according to the present invention, a plurality of CDMA users who perform one time slot, as in the conventional case, do not use fixed timeslots for each frame, but differently for each frame according to a code string having a series of statistical characteristics. In addition, multiple CDMA users sharing a time slot in the current frame can use different timeslots in the next frame, reducing the probability of sharing the same timeslot again, thereby spreading the traffic in use evenly in each time slot. It is possible to increase the number of subscribers of the next generation mobile communication terminal per time slot by reducing the signal interference and traffic jam phenomenon by maintaining the ratio of spreading power and reverse spreading power.

Claims (5)

An apparatus for allocating timeslots in a TDD frame of time division-CDMA A first spreading quadrature channel code generator for generating a code sequence for channel spreading at one output terminal and a code sequence for generating a hopping offset at every other frame period, and at the first spreading quadrature channel code generator A first hopping sub code generator for generating a code string for receiving a hopping code string to be output and sub-coded every frame period to determine a hop offset, and a hop offset output from the first hopping sub code generator is determined. A first hop offset generator for generating a hop offset for determining a time slot to hop in the next frame by receiving a code string, and adding a hop offset and a slot index from the first hop offset generator to obtain a time slot of a next frame. A first adder for determining the time of the next frame Sending unit for determining the blots, and the transmission phase information and the code hopping slot index for the receiver and; A second spreading orthogonal channel code generator for receiving the hopping code phase information output from the transmitter to generate a code sequence for channel spreading, and a hopping code string output from the second spreading orthogonal channel code generator; A second hopping sub code generator for generating a code string for determining a hop offset by sub-coding each frame period, and a code frame for determining a hop offset output from the second hopping sub code generator. A second hop offset generator for generating a hop offset for determining a timeslot to hop at, and a second adder for determining a time slot of a next frame by adding a hop offset from the second hop offset generator and a slot index. Other in time division-CDM characterized by including a receiver Time hopping device for random slot allocation. The method according to claim 1, The code string output from one output terminal of the first or second spreading orthogonal channel code generator is a channel spreading orthogonal channel code having a fast cycle, and the code string output from the other output terminal is a hopping code having a slow cycle. Time hopping apparatus for time slot allocation in time division-CDMA. The method according to claim 1 or 2, The first or second hopping sub-code generator generates the hopping code having the slow period by sub-coded every frame period and bundles chips of a predetermined length to generate time slots in time division-CD. Time hopping device for assignment. The method according to claim 2 or 3, And the slow period is 2.5 sec periods. Time hopping apparatus for time slot allocation in time division-CDMA. The method according to claim 1, The first or second hop offset generator generates a hop offset for each frame period by deciphering the hopping code sequence generated by the first or second hopping sub code generator. Time hopping device for time slot allocation.