DE3329506C2 - Receiver in a spread spectrum system - Google Patents

Abstract

In a spread spectrum system, in which two or more mutually orthogonal spread spectrum signal forms are used for the transmission, the output signals rectified in envelope detectors from filters (1) matched to these signal forms are individually compared with thresholds and the output signals of the Threshold value circuits (12) processed further in an OR gate (13), the output signal of which is used as a synchronization signal. The circuit according to the invention is easier to implement, especially for signals with a large bandwidth, than the known, technically equivalent circuit for determining the respective maximum value of the envelope curves of the filter output signals and switching it through to the threshold. The receiver according to the invention can be used in interference-resistant spread spectrum message transmission systems, in particular in those for the transmission of telegrams which each consist of a fixed number of successive signal forms with an agreed time pattern.

Description

40

The invention relates to a system operating with spread spectrum (spread spectrum system) Receiver intended for digital message transmission, in which the processing of the message transmission signals, composed of two or more mutually orthogonal spread spectrum signal forms agreed for the respective system are carried out by means of mutually parallel, matched filters, each one are adapted to the signal forms agreed upon in the system and each in an envelope curve detector rectified output signals are linked in a synchronization device, which then always emits an alarm signal if one of the signal forms agreed in the system has been received.

From EP 00 64 686 a spread spectrum receiver is known in which the synchronization is not of each rectified in an envelope detector and previously passed through an adapted filter Message transmission signals emanates from one of the actual message transmission signals preceding synchronization preamble signal. The synchronizing preamble signal is generated from the received signal evaluated in a synchronizing correlator and then transferred to a sequence control, which - if the existence of a correct preamble was recognized - those for the agreed Correlators laid out waveforms during one of the correlation peaks of the synchronizing correlator derived time slot synchronized. So there will not be a matched filter or linked a correlator as well as message transmission signals guided via an envelope curve detector wherein the synchronization device then emits an alarm signal for synchronization when one of the systematically agreed signal forms was received, but it is in the synchronizer a synchronization preamble sent out before the actual message transmission signals is evaluated

The following is based on a spread spectrum system in which the message is transmitted through the transmission of individual signal forms s, (1) , which correspond to the message to be transmitted from the signal form set (s, (t) agreed between the sender and receiver of the system ) can be selected. In the following it is assumed that this waveform set consists of a total of m mutually orthogonal spread spectrum waveforms (s, (t)) , all of which have the same waveform duration T and the same constant amplitude A during this waveform.

Such a waveform set can, for example, be approximated with pseudo-random phase-shift keyed (PN-PSK) waveforms of the form

Si (I) = A ■ pi (t) ■ cos (2jrfot)

are formed if the respective pseudo-random functions p, (t), i = 1, .... m are selected appropriately, see e.g. B. the article by R. Gold: "Optimal Binary Sequences for Spread Spectrum Multiplexing" from the journal IEEE Trans.lnform Theory IT-13 (1967), pages 619-621. The center frequency / ö can then be the same for all Si (t). It is also assumed that each of the m waveforms occurs with equal probability. The message detection in the receiver of such a spread spectrum system must be carried out at those times when signal forms from the agreed signal form set arrive at the receiver. Since these points in time are not known from the outset in the receiver, a synchronization device is required which can determine these points in time from the received signal itself and marks it with an alarm. The task of the synchronization device is generally made more difficult by the fact that the zero phase angle of the carrier oscillation of received signal forms are not known, but must be regarded as random variables that are independent of one another from signal form to signal form and that are uniformly distributed in the interval [0.2.x], and that an additional interference signal is superimposed on the received signal forms. In the following it is assumed that this interference signal is an additive Gaussian noise, the one-sided spectral power density of which has the constant value N ₀ within the frequency band occupied by the signal shapes.

If the above-mentioned preselections are taken into account, the circuit structure of an optimal synchronization device with the help of the so-called likelihood test procedure. please refer /. B. the book by A. D. Whalen: "Detection of Signals in Noise", Academic Press, New York, 1971, pages 196-237. In an example of the application of this method an optimal circuit structure is derived on page 217 of this book for the case that

a decision should be made as to whether or not an expected signal form of finite duration with a constant but unknown center frequency has arrived at the receiver. 1. In this circuit structure, a matched filter 1 is used for jpde of the m possible signal forms. The matched filters 1 connected to the antenna 2 are each followed by an envelope curve detector 3, the output signal of which is multiplied by the factor 2 A / Nq in a mixer 4. The resulting products are each fed to a functional unit 5, the output signal of which is equal to the modified Bessel function of the zeroth order applied to the instantaneous input signal at any point in time. This operation is illustrated in FIG. 1 is indicated by the notation / o (·). After adding the output signals from this functional unit 5 in a summing circuit 6, what is known as a test variable R (t) is obtained, which is routed to a threshold value switch 7 with the threshold level b. If the test variable R (t) is greater than the threshold level b, an alarm signal is emitted at output 8. In spread spectrum systems in which the individual, successive signal forms are not arranged in a telegram structure with a fixed time grid, the time of occurrence of such an alarm signal is interpreted directly as the time of arrival of an expected signal form. In spread spectrum systems, in which a fixed number of successive signal forms are combined into a telegram with an agreed time pattern, the so-called Stagger pattern, such an alarm signal can be read into the binary stagger register of a downstream stagger filter. The stagger filter then carries out post-integration over the entire telegram duration, which can lead to a considerable improvement in the synchronization behavior. The mode of operation of a stagger filter will be explained later in connection with the description of an entire receiver with reference to FIGS. 4 described.

The circuit structure of the optimal synchronization device according to FIG. 1 is not particularly well suited for practical use, since function values of the relatively complicated modified Bessel function / <> must either be calculated or determined with the help of a table of values at any point in time. Therefore, in the previously cited book by AD Whalen, reference is made to two possible circuit structures for suboptimal synchronization devices. It has been found that one of the two circuit structures from this book performs the best. This circuit structure is shown in FIG. It in turn uses the m matched filters 1 connected to the antenna 2 and arranged in parallel with the downstream envelope detectors 3 of the circuit structure of the optimal synchronization device according to FIG. 1. The outputs of the envelope detectors 3 are in the circuit according to FIG. 2, however, is connected to the inputs of a device 9 which switches the currently largest input signal through to its output 10 at any point in time. The output signal of this device 9 is now the test variable R '(t), which in turn is routed to a threshold value switch 11 with the threshold level b'. In the circuit structure according to FIG. 2 the disadvantage of a complex function value determination of the circuit structure according to FIG. 1 avoided. However, this is at the expense of the fact that the implementation of the device 9 that is now required for switching through the largest input signal is very problematic, especially with relatively large bandwidths of the signal shapes used.

The object of the invention is to create a circuit structure for suboptimal receiver synchronization in spread spectrum systems which, with completely equivalent synchronization behavior, allows a much simpler technical implementation than the suboptimal synchronization device described last
According to the invention, which relates to a receiver of the type mentioned, this object is achieved in that the output signals of the matched filter are each fed to a threshold switch in the synchronization device and that the outputs of the threshold switch, at which a signal occurs when the the signal fed to the respective threshold value switch by the associated signal-matched filter exceeds the respectively set threshold level, are connected to the inputs of an OR gate, at the output of which the alarm signal is present. Instead of determining the maximum value and switching it through to the threshold, according to the invention, the filter output signals are individually compared with thresholds and the output signals of the threshold value circuits are further processed in the OR gate. The corresponding circuit is easier to implement than the circuit for determining and switching through the maximum value. In terms of behavior, both circuits are equivalent.

The invention is illustrated below with reference to FIGS. 3 described.

The circuit according to FIG. 3 agrees with the circuit structure according to FIG. 3 with regard to the signal-matched filter 1 connected to the antenna 2 and the envelope curve detectors 3. 2 match. The device 9, which is difficult to implement, for switching through the largest input signal and the downstream threshold value switch 11 in the circuit structure according to FIG. 2 are in the circuit structure of FIG. 3 replaced by m threshold value switches 12, the output signals of which are combined with an OR gate 13. Are now the threshold height of all m threshold value switches

12 in the circuit structure of Figure 3 to the same Value set and this value is equal to the threshold level 6 'of the threshold switch 11 in the Circuit structure according to FIG. 2. then with a given input signal at the output 14 of the circuit structure according to FIG. 3 only ever an alarm signal occur when the same input signal is also at the output of the circuit structure according to FIG. 2 the occurrence of an alarm signal. This means that the synchronization behavior of the circuit structures according to FIG. 2 and F i g. 3 completely equivalent is the circuit structure of FIG. 3 is, however, compared to the circuit structure according to FIG. 2 essential easier to implement, since the threshold value switch 12 and the OR gate are designed to be practical

13 common integrated circuits can be used. If you use components in ECL technology, then a synchronization device with the circuit structure according to FIG. 3 in receivers are used by spread spectrum systems, which signal forms with bandwidths far beyond 100 MHz transmitted.

It should also be pointed out that the circuit structure according to FIG. 3 enables the threshold heights of the m threshold value switches 12 to be set differently. This can be advantageous, for example, when certain types of interference signals other than the previously assumed Gaussian noise must be expected.

4 shows the circuit diagram of an exemplary embodiment for a receiver in a spread spectrum system for digital messaging, where for Transmission of two orthogonal spread spectrum waveforms can be used. The receiver synchronization takes place here by means of a device according to the invention. The recipient shown should be used for evaluation of message telegrams are used. It is therefore a spread spectrum system, in which one has a fixed number of consecutive waveforms one consisting of two waveforms Signal form set for a telegram with an agreed time grid, the so-called Stagger pattern, summarizes.

The useful signal appearing at the receiver input after antenna 2 consists of individual bursts (telegrams), each of which contains w message bits. The telegrams have the form

s Jt) = Y a _r s _L U - Γ,) + b _r s _H U - T _r ).

Sl (O ^and Sh (O are spread spectrum signal forms assigned to the logical values L or H , here specifically 0/180 ° PN-PSK signal forms with binary pseudo-random functions Pl (l) or Ph (O of the chip frequency / _c and the duration T ■ pu (ι) or Ph (O should be the condition

PlU) PuU) dt = 0

fulfill (orthogonality). The values of the coefficients a, and b, - are determined by the message according to the table below.

Message bit

L. H

The arrival times Γ of the individual signal forms of a telegram are not known a priori in the receiver. Only the time differences are known

Ty = Tr ₊ X - T _n V = 1, ... IV-I):

which are not all selected equally to facilitate receiver synchronization (staggering). The interfering signal η (^) is superimposed on the received useful signal consisting of the telegrams s * (ι).

A receiver for the telegrams of the type described is implemented with filters 1 adapted to the signal. In this case, the received signal is fed to a filter adapted to si (t) and a filter adapted to su (t) at the same time. In the evaluation part 15, the filtering output signals are rectified in two detectors 16 and they are compared in a comparator 17 at times T ₁ -. to which one expects a correlation peak caused by the useful signal at one of the two filtering outputs. If the output signal of the L channel is greater than that of the H channel at such a comparison time, a decision is made for the relevant message bit for logical L, otherwise for logical H. Since the comparison times T1 are not known a priori in the receiver they are determined with a synchronization system 18.

F i g. 4 shows the basic structure of a receiver including the synchronization system, which corresponds to that according to FIG. 3 up to the OR gate 13 and is therefore not described again up to this point. In degraded reception signal, the output signals SmL can (0 or s ", h (0 of the matched filter 1 are considered to be stochastic ^ signals. In the synchronization system 18 making use of the fact that at the instants T _1. At the output one of the two matched filter 1 is a Nutzsignalspitze is expected. It links the two filter output signals s _m i. (0 ^ur> d s _m ii (0 ^to a so-called. test variables R ", the expected value at the time points Tr is large and usually small. the test variable R " is fed to a filter 19, the so-called stagger filter, which is adapted to the test variable curve to be expected when a telegram is received. A signal peak can therefore always be expected at the output of the stagger filter 19 when a telegram has been received. This leads to the generation of telegram alarms the output signal of the stagger filter 19 is sent to a threshold value circuit 20. With its output signal, which occurs when a threshold level d is exceeded, a clock generator 21 is triggered for the bit clock, ie for a clock pattern determined by the differences AT ₁ , at the rhythm of which the output signal of the comparator 17 is queried by means of a sampling device 22. Due to the structure of the synchronization system 18 described, the telegram alarms only occur when the entire telegram has been received. Only then is the bit clock available. So that the comparator output signal to be assigned to the bit clock is also still available, it must be delayed in a delay device 23 before it is fed to the scanning device 22. The delay time T i has the order of magnitude of a telegram duration, ie T _v « Tw-T]. The setting of the threshold heights b ' and d is expediently based on the probability of false alarms and the probability of detection of the individual telegram steps or of an entire telegram.

For this purpose 3 sheets of drawings

Claims (3)

Patent claims: 1. In a working with spread spectrum system for digital message transmission intended receiver, in which the processing of the message transmission signals, which are composed of two or more mutually orthogonal and agreed spread spectrum signal forms for the respective system, by means of parallel to one another, signal-matched filters are carried out, each of which is adapted to one of the signal forms agreed in the system and whose output signals rectified in an envelope detector are linked in a synchronization device which always emits an alarm signal when one of the system-agreed signal forms has been received characterized in that the output signals in the synchronization device. matched filter (1) are each fed to a threshold switch (12) and that the outputs of the threshold switch (12) at which a signal occurs when the signal fed to the respective threshold switch from the matched filter exceeds the set threshold level (b ') , are connected to the inputs of an OR gate (13), at whose output (14) the alarm signal is present. 2. Receiver according to claim 1, characterized in that the threshold height (b ') of all threshold switches (12) is the same. 3. Device according to claim 1, characterized in that the threshold levels of the threshold value switch (12) are set differently.