DE10130943A1 - Signal generator has baseband unit, in-quadrature modulator and optical display device that displays digital baseband signal stored in memory in predefined display format - Google Patents

Abstract

The signal generator has a baseband unit (2) that produces a digital baseband signal, an in-quadrature modulator (5) that modulates the baseband signal, a recording memory (15) that records a time section of the digital baseband signal and an optical display device (23) that displays the digital baseband signal stored in the memory in a predefined display format.

Description

The invention relates to a signal generator for generation a digitally modulated radio frequency signal, for example a mobile radio signal according to GSM (Global System for Mobile Communications) standard or a W-CDMA (Wideband Code Division Multiple Access) standard.

Signal generators that have been customary to date generally do not have via a display of the currently generated baseband signal. At most, a static display of the theoretical generated signal, but not the actually current generated signal, available. Observing the change of the signal depending on the time or a Signal evaluation of the actually generated Baseband signal is not possible.

The invention is therefore based on the object To create signal generator with which a representation of the currently generated baseband signal is possible.

The object is solved by the features of claim 1.

According to the invention, a recording memory is provided, the one period in the manner of a snapshot (Snap Shot) of the baseband signal. That so Recorded baseband signal can, if necessary, according to Signal processing in a definable form of representation, for example as a constellation diagram, spectrum, code Domain power representation or as CCDF (Complementary Cumulative Distribution Function) display become. This creates a "pseudo real time" display.

The subclaims relate to advantageous further developments the invention.

With the display device according to the invention Signal change can be observed which is the baseband signal  for example in a noise unit, a fading unit or a distortion unit. It can also Signal processing controlled in the baseband unit be by the signal for example before and after a Pulse shaping filter or before and after one Sampling rate converter (resampler) is observed. See full ad the code domain power of a CDMA signal it is advantageous the signal at the symbol clock level in front of the pulse shaping filter because the maximum memory depth is used and none Symbol clock regeneration is necessary.

It is advantageous that a decimation unit for Is available that the data stream of the digital Base signal by a predeterminable decimation factor decimated. Thus, the baseband signal can be, for example a decimated system clock level can be observed and the Decimation factor can be applied to the signal to be observed, for example the symbol length or slot length, optimal be adjusted.

There are applications in which the signal is triggered in the recording memory can be saved. For however, a number of applications are triggering useful, for example, when the memory depth is shorter than the desired observation period or if the baseband signal is periodic, for example frame- is periodic and periodic sections of the signal for a certain evaluation should be combined.

The invention is described below with reference to the Drawing described in more detail. The drawing shows:

Fig. 1 is a block diagram of an embodiment of the signal generator according to the invention;

2 shows an example of an image displayed on the display device of the signal generator according to the invention the constellation diagram of a QPSK signal.

Fig. 3 shows an example of an image displayed on the display device of the signal generator according to the invention the constellation diagram of a W-CDMA signal; and

Fig. 4 shows an example of a CCDF (Complementary Comulative Distribution Function) representation on the display device of the signal generator according to the invention.

Fig. 1 shows a block diagram of the signal generator 1 according to the invention. The signal generator 1 is used to generate a digitally modulated radio-frequency signal, for example a digitally modulated mobile radio signal according to the GSM standard, the GSM EDGE standard or a W-CDMA standard for the 3rd generation of mobile radio (UMTS).

A baseband unit generates a baseband signal with an I (in-phase) component and a Q (quadrature phase) component. The digital baseband signal generated by the baseband unit 2 can have an I / Q via a plurality of signal change units, for example a noise unit 3 which applies noise to the baseband signal and a fading unit 4 which applies fading (variable fading) or distortion to the baseband signal -Modulator 5 are supplied. There is a signal path for the I component and a signal path for the Q component between the baseband unit 2 and the I / Q modulator 5 . The I / Q modulator 5 modulates the digital baseband signal into an analog signal, which is converted by the high-frequency unit 5 into the corresponding high-frequency band. The digitally modulated high-frequency signal is available at an output 7 of the signal generator 1 .

The baseband unit 2 has a data source 8 which, with a symbol clock f _sym, generates data symbols consisting of an I component and a Q component. A pulse shaping filter 9 a and 9 b is provided for the I component and Q component. The pulse shaping filters 9 a and 9 b have, for example, low-pass characteristics and transform the pulses at the output of the data source 8 into a pulse shape that is favorable for transmission. The sampling rate is increased to the system clock rate f _sys in a respective sampling rate converter (resampler) for the I component and Q component 10 a or 10 b. The system clock rate f _sys can be 80 MHz, for example.

There may be an input 11 a for the I component of an externally deliverable signal and input 11 b for the Q component of an externally deliverable analog signal. This external analog signal experiences a band limitation in a low-pass filter 12 a or 12 b and is converted to a digital I component or digital Q component on analog / digital converters 13 a or 13 b. This external I component can be added on an adder 14 a to the I output component of the baseband unit 2 , while the external Q component can be added on an adder 14 b to the Q output component of the digital base unit 2 .

According to the invention, there is a recording memory 15 with which a time segment of the digital baseband signal can be recorded in each case. For this purpose, an I input 16 a of the recording memory 15 can be connected via a first switching device 17 a and a Q input 16 b of the recording memory 15 via a second switching device 17 b to a plurality of positions in the signal path of the I component or the Q component , In the illustrated embodiment there is a signal tap at the output of the data source 8 , a signal tap at the output of the pulse shaping filter 9 a or 9 b, a signal tap at the inputs of the adder 14 a or 14 b, a signal tap at the output of the adder 14 a or 14 b, a signal tap at the output of the noise unit 3 and a further signal tap at the output of the fading unit 4 or at the input of the I / Q modulator 5 .

Preferably, one or more decimation units 18 a and 18 b and 19 a and 19 b are located at the input of the recording memory 15 . While the decimation units 18 a and 18 b decimate the data stream of the digital baseband signal by a decimation factor N, the data stream is decimated by the decimation units 19 a and 19 b in each case by a decimation factor N: 10, for example 10 times smaller, the decimation factor N being free is selectable. Via a third switching device 20 a, the I input 16 a can be connected either directly to the output of the first switching device 17 a or to the output of one of the decimation units 18 a and 19 a. Accordingly, the Q input 16 b of the recording memory 15 can either be connected directly to an output of the second switching device 17 b or to an output of one of the decimation units 18 b and 19 b.

The start of the time period which the recording memory 15 records can be controlled by a trigger signal TS which is fed to a trigger input 21 of the recording memory 15 . The trigger signal TS is generated, for example, by a digital signal processor 22 , which also uses a control bus 23 with the digital baseband unit 2 , the noise unit 3 , the fading unit 4 , the I / Q modulator 5 , the high-frequency unit 6 and the decimation units 18 a, 19 a, 18 b and 19 b are related. The connection of the control bus 23 is marked (*). The digital signal processor 22 controls the entire signal processing and is therefore able to generate the trigger signal TS at the corresponding signal tap in synchronism with the baseband signal.

Furthermore, a display device 23 is provided, by means of which the digital baseband signal stored in the recording memory 15 can be represented in a predefinable manner of representation, if necessary after appropriate representation preparation in the digital signal processor 22 . The display device 23 is, for example, a display. The recording memory according to the invention 15, in conjunction with the inventive display device 23 is a "pseudo-real time" Signal Indicator and a signal analysis in the signal generator 1, for example showing a complementary cumulative distribution function CCDF, a constellation diagram of the I signal and Q signal over time, of the spectrum or a code domain power representation. Regarding the code domain power representation in general, but not in the case of a signal generator, reference is made to DE 100 56 258 A1 by the same applicant.

Fig. 2 shows an example of a representation of a constellation diagram for a QPSK signal. The four state points in the I / Q level and the transitions when the state changes can be seen. Fig. 3 shows an example of a plurality of overlapping W-CDMA signals in the constellation diagram.

Fig. 4 shows a CCDF representation. The "Complementary Cumulative Distribution Function" (CCDF) specifies the frequency with which W the contributions of the complex samples a certain predetermined amount, z. B. exceed the average power. If the limit is interpreted as the radius of a circle around the origin, the radius is entered to the right and the frequency of the samples lying outside this circle is shown upwards.

To a certain extent, the recording memory 15 enables a “snapshot” of the signal, that is to say a recording of the signal in a limited period of time. In the exemplary embodiment, after the signal has been recorded in the recording memory 15 , the recording memory 15 is read out by the digital signal processor 22 and the next signal recording can be started immediately. The recorded signals are displayed either directly on the optical display device 23 or in the digital signal processor 22 to be carried out analysis and pre-processing on the display device 23 is illustrated according to graphically. It is also possible to display external signals supplied via inputs 11 a and 11 b. This can be used, for example, to check whether the fed-in signal shows the expected behavior or whether the measurement setup is correctly wired.

Since not an idealized, theoretically calculated signal, but the actually measured signal is shown, all effects of the baseband signal generation, for example the bit resolution of the digital components, transient processes and the effect of the analog band limitation filters 12 a and 12 b, can be seen and an evaluation the signal quality is possible. When using the output signal of the signal generator 1 as a stimulus for a test object, it can thus already be examined in the signal generator 1 which signal errors the output signal of the signal generator 1 has. This simplifies the evaluation of the signal influence by the test object.

Furthermore, effects of parameter changes in the setting of the signal generator 1 , for example changes in the type of modulation, the noise amplitude or the fading, can be recognized directly on the display device 23 . It is also possible to monitor external interfaces. In the increasingly complex digital transmission systems, for example of the 3rd generation mobile radio (UMTS), the signal display in "pseudo-real time" enables the set parameters to be checked, making operation sensible in the face of increasing complexity. For example, the effect of limiting effects (clipping) or the connection of a second base or mobile station on the code domain of a CDMA signal of the signal displayed on the display device 23 is possible and facilitates the selection of the parameters concerned.

Depending on the form of presentation and depending on whether the signal has been generated internally or externally, a signal tap at different points makes sense. A tap on the level of the symbol clock f _sym before the pulse shaping filters 9 a, 9 b is z. B. useful for a code domain power representation, since the maximum memory depth is used and no symbol clock regeneration is necessary. A tap on the level of the system clock f _sys enables maximum time resolution of the internal and external signals. At the level of a system clock f _sys / N decimated by the decimation units 18 a, 19 a, 18 b, 19 b (for example, reducing the system clock from 80 MHz to a decimated system clock of 40, 20, 10 or 5 MHz) is an optimal adaptation display of internal and external signals possible. The decimation factor N can either be set automatically, for example adapted to the signal bandwidth, or can be specified manually in order to view and evaluate the signal in different magnification levels (zoom levels).

For certain forms of representation, it is necessary that the period of time recorded by the recording memory 15 has a certain length, since the combination of medium and short signal sections is not easily possible. For the display of spectra and a time-dependent signal display, this minimum length depends on the desired resolution. For a code domain power representation, it makes sense to be able to record at least two symbols of maximum length, since the determination of the channel power of a code channel requires at least one complete symbol. When the detected from the recording memory 15 time portion detects at least two symbols, it is ensured that even with a measurement untriggered a complete symbol is included in the detected time period.

It is also possible to combine a plurality of signal sections from a plurality of time sections recorded in succession. In some forms of representation, subsections of the baseband signal can be combined without triggering. This applies, for example, to the CCDF representation shown in FIG. 4, an averaged spectrum or the constellation diagram shown in FIGS. 2 and 3.

If the signal section to be analyzed is longer than the maximum time period that can be recorded by the recording memory 15, a suitable choice of the trigger signal TS allows a plurality of time periods to be joined together without gaps. This enables analysis of longer signal sections even with a limited memory depth of the recording memory 15 . In the case of a frame-periodic W-CDMA signal which is divided into a plurality of time slots, the individual time slots of a frame can be recorded in succession if the recording memory 15 does not have an entire frame due to its limited memory depth can capture. The entire frame can be assembled without gaps from the individual partial recordings. This method can also be used to display an eye diagram at the symbol level.

Claims (10)

1. Signal generator ( 1 ) with
a baseband unit ( 2 ) which generates a digital baseband signal,
an I / Q modulator ( 5 ) which modulates the digital baseband signal,
a recording memory ( 15 ) which records a period of the digital baseband signal, and
an optical display device ( 23 ) which represents the digital baseband signal stored in the recording memory ( 15 ) in a predeterminable form of presentation. 2. Signal generator according to claim 1, characterized in that between the baseband unit ( 2 ) and the I / Q modulator ( 5 ) at least one or more signal change units ( 3 , 4 ) are provided and that the signal at the input and / or output of each Signal changing unit ( 3 , 4 ) can be fed to the recording memory ( 15 ). 3. Signal generator according to claim 2, characterized in that one of the signal changing units ( 3 , 4 ) is a noise unit ( 3 ) and / or a fading unit ( 4 ) and / or a distortion unit. 4. Signal generator according to one of claims 1 to 3, characterized in that the baseband unit ( 2 ) has at least one sampling rate converter (resampler) ( 10 a, 10 b) and the signal at the input and / or output of each sampling rate converter ( 10 a, 10 b) the recording memory ( 15 ) can be fed. 5. Signal generator according to one of claims 1 to 4, characterized in that the baseband unit ( 15 ) has at least one pulse shaping filter ( 9 a, 9 b) and the signal at the input and / or output of each pulse shaping filter ( 9 a, 9 b) Recording memory ( 15 ) can be fed. 6. Signal generator according to claim 5, characterized in that on the display device ( 23 ) code domain power of a CDMA signal is shown and the recording memory ( 15 ) the signal at a symbol clock rate (f _sym ) before the pulse shaping filter ( 9 a, 9 b ) is supplied. 7. Signal generator according to one of claims 1 to 6, characterized in that one or more decimation units ( 18 a) are provided in front of the recording memory ( 15 ), which decimate the data stream of the digital baseband signal by a decimation factor N, by, only every N- te data element is selected. 8. Signal generator according to claim 7, characterized in that the beginning of the period, which the recording memory ( 15 ) records, is controlled by a trigger signal (TS). 9. Signal generator according to claim 8, characterized, that the trigger signal (TS) is selected so that several Period are joined together without gaps. 10. Signal generator according to claim 8, characterized, that the trigger signal (TS) is selected so that the Periods of periodic periods of a cover periodic baseband signal.