GB2364205A - Transmitting an ofdm signal over more than one channel where each channel after the first has a positive or negative time delay - Google Patents

Abstract

The transmission system utilizes transmit diversity over a first and at least one further coded OFDM channel in the same frequency band, where each channel after the first channel has a positive or negative time delay relative to the first channel. Digital filters (10, 10') in each channel (A, B) has different phase and magnitude responses in order to achieve the required time delay and provide different gain values is a function of frequency.

Description

2364205 Broadband communications

Background of the Invention

The present invention relates to broadband wireless communications and in particular, but not exclusively, systems suitable for transmitting the large quantities of data needed for Internet access for users who are not connected to the existing telephone and cable systems.

More specifically the present invention relates to a transmitter station for providing broadband communications suitable for use in the 3 5 G Hz band, where a narrow 14 M Hz band is available for wireless internet access in Europe including Scandinavia and parts of the Middle and Near East, Mexico and South America The band could also become available in the US and Canada, where it is currently assigned to military use The invention is also applicable to situations where a wider bandwidth is available such as the 56 M Hz band at 2 5 G Hz.

Technical Problem The technical problem is to transmit reliably by wireless a large amount of data such as required for digital television or internet data In the frequency band of interest multipath effects and significant fading are serious problems Spread spectrum solutions combined with forward error correction (FEC) can improve the reliability of such channels but still do not provide sufficient reliability for data purposes where 99 99 % accuracy is required to maintain acceptable standards.

Coded Orthogonal Frequency Division Multiplexing (OFDM) Coded OFDM is an established technique for broadband communications in which digital data coded with redundancy for FEC is encoded as a plurality of voltage vectors that are transmitted simultaneously on a set of carriers in the frequency domain.

This technique alone will not achieve the required accuracy.

Solution of the Invention The transmission system of the present invention utilizes transmit diversity over a first and at least one further coded OFDM channel in the same frequency band, where each channel after the first channel has a time delay relative to the first channel.

Preferably the channels are adapted to have different gain and phase values as a function of frequency where such values may be fixed or vary in time.

Advantages of the Invention When used in fixed radio communication links this system can deliver improved fade margin statistics which can be used to reduce transmitter power, increase range, modulation depth and frequency reuse These improvements are also applicable to mobile applications.

This system can reduce the time taken to statistically characterize the radio paths to a given location Where installation of a receiver at a given location requires characterization of the radio paths to the location, this system results in a reduced installation time.

Brief Description of the Drawings

In order that the invention may be well understood an embodiment thereof will now be described, by way of example only, with reference to the accompanying diagrammatic drawings, in which:

Figure 1 shows a block diagram of a transmitter; and Figure 2 shows an example channel response for a multi-channel embodiment of the invention.

Overview The system is a coded OFDM transmitter incorporating transmit diversity.

Detailed Description of a Preferred Embodiment

An implementation of the invention using two transmit channels A and B is described with reference to Fig 1.

A data signal to be transmitted is input at 2 to a baseband coder 4 that generates a baseband coded OFDM signal The signal at this point is represented by digital samples of the real and imaginary components of the signal The output of the coder 4 is then fed to the input of each of two channels A and B The elements of the channels are indicated by the same reference numerals with those in channel B being indicated by the addition of a prime sign (').

In channel A the signal is supplied to a digital filters 10 The output of the digital filter is supplied to an RF modulator, 12 The RF modulator 12 converts the digital signal into an analogue signal and also performs the frequency conversion to translate the signal to the required carrier frequency.

The RF signal output from the RF modulator 12 is supplied to a power amplifier 14.

The output of the power amplifier 14 is supplied to an antennas 16 which radiates the signal for channel A.

The digital filters, 10, 10 ', have complex coefficients They are implemented using standard digital signal processing techniques using either programmable digital signal processors, field programmable gate arrays or dedicated logic circuits Both the phase responses and magnitude responses of the filters are different from each other The difference in phase response of the two filters results in a difference in group delay between the two signal paths Typically for an OFDM signal bandwidth of 3 to 15 M Hz, the filters will be selected to impart a group delay difference of 5 to 12 P s.

The two filters also have different magnitude responses Assume the filter magnitude responses are given as follows:

M 10 (f) forfilter 10 M 1 o (f) for filter 10 ' The filter responses are selected so that the composite power response is constant:

(M O (f))2 + (Mo,(f))2 = k Example magnitude responses for the two channel case are as follows:

Scheme Magnitude response 1 M 1 o(f)=,Mlo O (f)= a,f < O Mo,(f) = 1,Mlo(f) = a,f > O where a is between 0 and 1, typically 0 33 and f is the frequency 2 1 M 10 (f)= I+I Of 1 M 10,(f) =,1 1 1 + 1 +ofa where f is the normalized frequency and a is a scaling factor Preferably, the filter phase and magnitude responses may be varied slowly in time.

Typically the bandwidth of the variations will be less than 1 k Hz to allow the OFDM demodulator time to track the changes in the channel state using existing demodulators.

Alternatively, using an enhanced OFDM demodulator, the bandwidth of the magnitude and phase response may be increased up to a rate equal to that of the OFDM burst rate The phase and magnitude responses may be varied in a periodic or a pseudo-random manner known to both the transmitter and the receiver.

The filtering functions implemented by blocks 10 and 10 ' may be performed at other points in the signal processing chain They may be performed prior to the inverse Fourier transformation in the OFDM coder 4 or performed on the IF signal Similarly the filter may be performed on an analogue or digital version of the signal.

The implementation detailed in Fig 1 applies to a transmitter with two diverse channels In a multi-channel implementation the blocks 10, 12, 14 and 16 are repeated for each channel In general, for each channel, the respective blocks are identical apart from the filter implemented by the equivalent of block 10 The phase responses of each filter are selected to impart a different group delay to each channel Again group delay differences in the ranges 5 to l/2 gs are typical.

An example channel response for the multi-channel case is shown in Figure 2 The factor a is some value between 0 and 1.

The magnitude spectrum satisfies the following requirement:

Z (Mchannel ())2 = k channels In a radio system employing transmit diversity, receive diversity can also be used to advantage If there are two transmitters and two receive antennas, then there are four communication paths If the paths are statistically independent, then substantial gain can result depending upon the Ricean K factor of the paths, and upon the use of an optimal receive combiner and upon the desired link reliability.

These transmit diversity techniques are particularly useful in point to multi-point systems where the benefit of a small increase in base site complexity is distributed across many outstations.

This transmission system can be used with any known error correction coding such as FEC.

Claims (7)

Claims

1 A transmission system comprising means for generating an OFDM signal coded with redundancy for forward error correction from a data signal to be transmitted and means for transmitting said signal over a first and at least one further channel in the same frequency band, where each channel after the first channel has a positive or negative time delay relative to the first channel.

2 A transmission system as claimed in claim 1, wherein the transmitting means provides the channels with different gain and phase values as a function of frequency which values do not vary in time.

1 o

3 A transmission system as claimed in claim 1, wherein the transmitting means provides the channels with different gain and phase values as a function of frequency which values vary in time with a rate less than the OFDM symbol rate.

4 A transmission system as claimed in claim 1, for use with a receiver having at least two antennas in order to define at least four transmission paths.

A transmission system as claimed in claim 2, for use with a receiver having at least two antennas in order to define at least four transmission paths.

6 A transmission system as claimed in claim 3, for use with a receiver having at least two antennas in order to define at least four transmission paths.

7 A transmission system substantially as herein described with reference to the accompanying drawings.