Multi-diversity synchronization technique for improving...

Details Multi-diversity synchronization technique for improving... Multi-diversity synchronization technique for improving...

1999-06-17

2003-04-08

Yao, Kwang Bin (Department: 2662)

Multiplex communications

Communication techniques for information carried in plural...

Combining or distributing information via time channels

C370S350000, C370S514000, C370S516000, C375S267000, C375S299000, C455S101000, C455S133000

Reexamination Certificate

active

06546026

ABSTRACT:

BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to the field of wireless telecommunications and, more particularly to a multi-diversity synchronization technique for improving synchronization performance in a wireless telecommunications application.
2. Description of the Related Art
In many wireless standards such as the TIA standard IS-136 format based on Time Division Multiple Access (TDMA) using Differential Quadrature Phase Shift Keying (DQPSK) modulation, a radio receiver is required to be able to derive timing synchronization from information contained in the received signal. Often there are a small number of data symbols contained in the transmitted signal that are known a priori to the receiver. The receiver may then use its knowledge of these symbols to locate them in the received transmission.
FIG. 1
illustrates a typical frame
10
within a transmitted signal according to the TIA standard IS-136 format. Each frame
10
is forty milliseconds in duration and consists of 1944 bits or 972 symbols (i.e., each symbol comprises 2 bits). Each frame
10
contains six time slots
20
of equal duration and size (i.e., 162 symbols), which include data from a plurality of signals transmitted by different mobile units to a base station or transmitted to a plurality of mobile units from the base station. Each full rate traffic channel uses the data fields in two time slots
20
(e.g., slots
1
and
4
,
2
and
5
, or
3
and
6
) and thus, each frame supports three full rate traffic channels. A mobile unit will transmit or receive bursts of information, which are each allotted a time slot
20
in a frame
10
, whereby a plurality of mobile units can transmit or receive over a given channel.
The format of a time slot
20
varies depending on whether it is transmitted by the base station or by a mobile unit.
FIG. 2
a
illustrates the time slot
20
format of a signal transmitted from a mobile unit to a base station. The number of bits of each field are represented within parenthesis. The G field (6 bits) represents a guard time used to separate the present transmission burst from the previous burst. The R field (6 bits) represents a ramp time necessary to fully activate the radio transmitter. The three DATA fields (one field of 16 bits and two fields of 122 bits) hold the channel data, such as voice information. The SYNC field (28 bits) contains a sequence of symbols, which has been chosen to have good correlation properties and may be used, for example, in synchronization, equalizer training and slot identification. The SACCH (Slow Associated Control Channel) field (12 bits) is a signaling channel for transmission of control and supervision messages between the mobile units and the telecommunications system. The CDVCC (Coded Digital Verification Color Code) field (12 bits) is used to distinguish the current traffic channel from traffic co-channels.
FIG. 2
b
illustrates the time slot
20
format of a signal transmitted from a base station to a mobile unit. The number of bits of each field are represented within parenthesis. The SYNC, SACCH and CDVCC have the same number of bits and functions as described above with reference to
FIG. 2
a.
There are only two DATA fields, however, each containing 130 bits, but they are still used to hold channel information, such as voice information. There is a RSVD field (1 bit) and a CDL (Coded Digits Control Channel Locator) field (11 bits), which may be used by the mobile unit to assist in the location of a Digital Control Channel.
Thus, in the TIA standard IS-136 format, there are twenty-eight known bits, or fourteen symbols, in each SYNC field (collectively referred to herein as the “synchronization word” or “sync word” for short) that may be used by the receiver to determine time synchronization. Typically, the receiver would correlate the received signal with the a priori known sync word and use the location of the maximum correlation to determine the absolute timing reference. Alternative measures of determining the similarity between the received signal and the known sync word such as the conventionally known Mean Squared Error (MSE) based metrics can also be used as the basis for locating the sync word in a received signal.
There are conflicting design goals that impact the selection of the contents of the sync word for a telecommunications system design. For reliable synchronization performance, the sync word should have good correlation properties (i.e., an autocorrelation function equal to zero for time offsets other than zero) and be as long as possible to average out the effects of noise in the synchronization process. For efficiency purposes, it is desirable to waste as few bits as possible on non-information carrying overhead symbols such as the symbols contained in the sync word. For practical real-world systems, the synchronization word is short enough that synchronization errors are a real concern, particularly in a fading environment where the effective Signal-to-Noise Ratio (SNR) can be locally very poor during a deep fade.
The consequences of incorrectly determining the position of the sync word can be severe. When a sync word location is incorrectly determined in a burst transmission based TDMA system like IS-136 the entire frame of data contained in the mis-synchronized burst can be lost causing a significant degradation in Bit Error Rate (BER) or Frame Error Rate (FER) performance. This results in poorer speech quality in voice applications, or reduced throughput in data applications. The problem can be particularly troublesome in a high mobility fading environment where the entire contents of an otherwise acceptable frame of data can be lost if a deep fade happens to hit the sync word symbols. With denser constellations such as, those being proposed in the IS-136+ enhancements to the TIA standard IS-136 format where coherent 8-PSK (Phase Shift Keying) modulation will be used, the tolerance for synchronization errors will be even less due to the reduced margin between adjacent symbols. Fractional symbol timing errors that caused little degradation with a widely spaced 4-point constellation will have a much more significant impact on the denser 8-point constellation of 8-PSK as the eye opening is not nearly as wide.
Wireless receivers designed to work in a fading environment, particularly base stations, often take advantage of antenna diversity (i.e., use of several antennas spaced apart for receiving diverse signals) in order to mitigate the effects of fading. Antenna diversity works by exploiting the fact that it is unlikely that fades will occur at the same time in all received signals (assuming the antennas are spaced far enough apart so that the fading processes are effectively independent), and hence there is better information in the combined signal than in any individual signal. As known in the art, Maximal Ratio Combining (MRC), where the diverse signals are weighted proportionally to their received energy, is an example of a method for combining multiple antenna signals to improve receiver performance.
A high level functional block diagram of a typical synchronization scheme
50
is illustrated in FIG.
3
. Baseband signals r
0
to r
L−1
are received from signal receiving circuitry (not shown). Each baseband signal r
0
to r
L−1
was originally received as a radio frequency (RF) signal from its respective antenna and converted by the signal receiving circuitry into digitized baseband signals (having complex in-phase I and quadrature Q components). Here the sync word positions are independently located in their individual diversities by separate single diversity sync locators
52
0
to
52
L−1
(where L is the number of antennas or diversities). Once the locations S
0
to S
L−1
of the sync words have been determined, the baseband signals r
0
to r
L−1
may be combined in a multi-diversity demodulator
54
that can make use of the combined information found in the multiple diversities to output information OUTPUT BITS to be used by the re

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