DE19523343A1 - Leakage energy measurer between adjacent channels in burst mode TDMA appts., esp. transmitter - Google Patents

Abstract

A calculator consists of a mixer (8) which combines transmissions from the measured object (1) and from a receiving oscillator (6). A Hilbert converter (2) filters the appropriate frequencies to an analogue/digital converter (3) using a frequency scanning oscillator (7). A digital processor (4) analyses the data and sends the result to a display unit (5).

Description

The invention relates to an apparatus and a method for measuring leakage performance, which is measuring performance transmissions in neighboring channels of a transmitter in time relieved.

Traditionally, leakage performance is measured in neighboring channels of a transmitter the evaluation of Signa len in the steady state in the frequency domain.

Fig. 7 shows an example of waveforms within a transmission channel and a channel which is adjacent to the Übertragungska nal. In the transmission channel (see FIG. 7a), information is transmitted in a constant time range in a bundle (burst), using a time-sharing transmission method. The time interval of the bundle is usually referred to as a slot, while the repeated pulse sequence in a bundle is usually called a frame. If e.g. B. a suddenly changing signal such as a TDMA (time division multiple access) signal bundle is generated in the transmission channel, an interference wave is generally induced in the adjacent channel (ie, in the channel that the adjacent frequency band assigned).

Fig. 7 (b) shows an example of a waveform of a leakage power in the adjacent channel. Leakage power is generated in the second, third and higher channels above and below the transmission channel. A peak value in the adjacent channel represents the peak power.

Figure 8 illustrates an exemplary device that measures leakage performance using conventional methods. First, a mean value is measured for a period with a power meter between the time range with signal bundle and the time range without signal bundle. The mean power is then calculated during the time range in which the signal bundle lies, the duty cycle of the time range with signal bundles for the entire period being taken into account. The value of the leakage power, which is determined with this method, is an average value; a performance peak as shown in Fig. 7b, however, cannot be determined here.

In another known measuring method, for. B. a Spectrum analyzer used. This procedure calculated the average power over the time range with signal bundles, after taking measurements with a common spectrum analyzer Time range have been executed.

However, measurements made with a spectrum analyzer involve sampling the waveform. To ensure that maximum power can be determined accurately, generally more than one sample per frame is required. If the scan time is taken into account, if a slot is 15 msec long and a frame contains 6 slots, 90 msec is required to obtain a scan. If a spectrum analyzer takes 500 samples, it takes 45 seconds to measure the leakage peak. Such a measurement method is too time-consuming and therefore not effective.

Recently the need has arisen for a short time Event, such as an interference wave on the rise and the fall of a burst wave in a TDMA transmission measure up. The above power meter or spectrum analyzer However, sator only allow the measurement of an average the leakage performance of a frame in the adjacent channels; however, you cannot have a short-term event, such as a Measure the TDMA burst.

It is an object of the invention, a device and a ver drive to measure the leakage performance in neighboring channels to provide for a transmitter that the above men fix gel. In particular, it is an object of the invention Measure a transition from power to neighboring Allow channels (ACP transition) of a transmitter in the time domain Lichen, being a technique of digital signal processing is used.

This object is achieved with the features of the claims.

According to the A / D converter can the analog-digital perform conversion in real time because the frequency of the A / D converter is approximately 220 kHz. In addition, you can the real and imaginary generated by the Hilbert converter parts can be processed in real time. In addition, the Be work does not take an extraordinary amount of time if the reduction function is only carried out as required.

Because the characteristics of the bandpass filter meet the requirements of any telecommunications system, data can can be obtained with good reproducibility. In addition is  the bandpass filter on the carrier channel, the upper adj beard channel and the lower adjacent channel. In the power calculation part is the sum of the squares of the real part and the imaginary part, so the To maintain leakage performance of the adjacent duct. To this The calculated results are achieved in real time. For this reason, a short change, which is in one Signal bundle is observed, and a corresponding lei power transition precisely measured in the time domain.

Fig. 1 is a block diagram of a first embodiment of the invention;

Fig. 2 is a block diagram of the digital signal processing system shown in Fig. 1;

Fig. 3 is a flow diagram humor the general method of measuring the tip leakage power in Convention describes in detail with the teachings of the invention;

Fig. 4 illustrates the steps of the frequency conversion by means of the signal processing used according to the invention;

Figure 5 shows the signal processing operation as a function of frequency, time and power;

Fig. 6 (a) shows an example of the leakage performance of the Trägerka channel;

Fig. 6 (b) shows an example of the leakage performance of the upper adjacent channel (+25 kHz);

Fig. 6 (c) shows an example of the leakage power of the lower adjacent channel (-25 kHz);

Fig. 7 shows an example of the waveforms of the transmission channel and the adjacent channel; and

Fig. 8 shows an example of the conventional measurement of the leakage power.

The embodiments of the invention are related to the Figures explained.  

Fig. 1 illustrates a block diagram of the first embodiment of the invention. The signal measured by the device under test 1 and the frequency f _{L of} the local oscillator 6 are, as shown in FIG. 1, mixed by a mixer 8 , and the resulting signal is in a medium frequency band at a frequency f _IF . Subsequently, the signal of interest with the average frequency is extracted either from the sum signal or the difference signal through the low-pass filter (TPF) 2 . An analog-digital conversion is then carried out by means of the A / D converter 3 , the sampling rate being equal to the frequency f _{SP of} the sampling frequency oscillator 7 . As a result, the filtered signal is digitized.

A selection from the medium frequency f _IF in the low frequency range (around 220 kHz) is carried out in order to facilitate the analog-to-digital conversion. For this reason, the mixer 8 can advantageously be composed of different stages, so as to gradually reduce the signal frequency if necessary.

The data digitized by the A / D converter 3 is processed by a digital signal processing system (DSV) 4 as described below. Finally, the leakage performance of the adjacent channel is determined and displayed in a display unit 5 .

Fig. 2 is a block diagram of the digital signal processing equipment used in accordance with the invention. Fig. 4 shows the steps of frequency conversion with the measuring device used in the invention and the measuring method used. In the digital signal processing system 4 , high-frequency signal components of frequency bands that are not of interest are first removed by the second low-pass filter 402 from the f _IF medium-frequency signal 401 , as shown in FIG. 2. The f _IF signal is digitized with the sampling frequency f _SP . As shown in Fig. 4 (b), the second low-pass filter is designed to filter out high-frequency signal components larger than f _SP / 4.

After filtering, the input signal is converted into a vector form by Hilbert converter 403 as a set of complex signals. The Hilbert converter 403 outputs two signals corresponding to the real and imaginary parts of the input signal (ie a real part (I) and an imaginary part (Q)). Of the two signals (f _H ± f _IF ) resulting from the Hilbert conversion, only the signal of interest is extracted by the third low-pass filter 404 . For example, the (f _H + f _IF ) component could be extracted through the third low pass filter. Thereafter, the data is reduced by the reducing part 405 as needed. The decrease occurs to ensure that a sufficient number of samples are taken so that the information contained in the data is not lost, while at the same time the sample rate is kept to a minimum so as not to extend further processing. In one embodiment, e.g. B. 1/4 of the data cut out to provide values for the calculation of the leakage len.

After the number of data bits is reduced by reduction, the signal is filtered by a band pass filter 406 . The band pass filter 406 has filter characteristics according to the characteristics of the telecommunications equipment used for transmission. For example, filter 406 is sensitive to filter characteristics in accordance with various requirements such as: B. D-MCA designed and can be implemented either by analog or digital methods. In addition, depending on the bandwidth required and the number of samples, the filter 406 can be designed such that the carrier channel and each adjacent channel is filtered. The bandpass filter can e.g. B. be designed so that three channels with the frequency bands of the carrier channel, the upper adjacent channel and the lower adjacent channel are let through.

After the bandpass filtering, the sum of the squares of the real and imaginary parts (ie I² + Q²) is determined in the power calculation unit 407 . This calculated value represents the leakage power of the adjacent channel and corresponds to a short-term value of the transition in the time domain.

Fig. 5 illustrates the effects of three-dimensional signal processing described above (ie, frequency, time and power). Figure 5 shows that three channels are processed simultaneously, although it will be apparent to those skilled in the art that five or more channels can be added if necessary. In addition, the averaging process is carried out based on the processed results. For example, an average ACP within the TDMA slot, an average ACP within the TDMA frame, a peak ACP and an average ACP of the digital modulation part, etc. can be obtained.

The processed results of the digital processing system 4 are displayed in the display unit 5 . Fig. 6 shows a representation of the leakage power of an adjacent channel. Fig. 6 (a) shows the carrier channel, Fig. 6 (b) the upper adjacent channel (+25 kHz) and Fig. 6 (c) the lower adjacent channel (-25 kHz).

It should be noted that in the description of the block diagram of the first embodiment of the invention, only the first ACP was measured. However, in order to measure the second, third and higher order, further embodiments of the invention can be constructed so that the mean frequency of the local oscillator frequency f _{L is} suitably offset and the signal processing is carried out several times, so that the leakage power in the other bands of interest is determined becomes. In addition, with respect to the filter characteristics of the band-pass filter 406 , if the filter characteristics of the band-pass filter 406 are changed in accordance with that of the telecommunication system such as PDC, PHS, NADC, etc., the ACP for each system can be measured accurately. Furthermore, the invention could be designed in such a way that the signal observations are carried out by performing the APC measurement and modulation analysis with the same data and the same time, the measured results and the demodulated data being synchronized.

So far, the device for measuring leakage performance of an adjacent channel. Among other things an embodiment of the invention can be considered a method of measuring the leakage power of an adjacent one Channel by performing a number of steps.

Fig. 3 is a flowchart that explains the measurement process. Mixing the output of the local oscillator and the signal from the object to be measured produces a medium frequency signal (step 110 in Fig. 3). The output signal generated by the mixer is converted into a digital signal by an A / D converter at a sampling rate determined by the output of the sampling frequency oscillator (step 130). Subsequently, the digital data is converted into a complex signal by a Hilbert converter (step 150), and the low-pass filter removes unnecessary frequency components from the output signal of the Hilbert converter (step 160). The band pass filter filters the output of the low pass filter to produce a signal that has a frequency characteristic corresponding to the transmitting device (step 180). Finally, the power calculation unit calculates the leakage power derived from a set of complex numbers output by the band pass filter (step 190).

In addition, the method for Measurement of the leakage power of the adjacent channel so out the output data of the low-pass filter the reduction unit is reduced (step 170) and that the output signal of the reducing unit is the bandpass filter is supplied (step 180).

According to the above description of the invention a device and a method for measuring the leakage of an adjacent channel, the measuring an ACP transition into neighboring channels enable a station in the time domain.

Claims (4)

1. Device for measuring the leakage between adjacent channels of an object to be measured ( 1 ), preferably a transmitter, with:
a mixer ( 8 ) which mixes an output of a receiving oscillator ( 6 ) and a signal of the object to be measured ( 1 );
an A / D converter ( 3 ) which converts an output signal of the mixer ( 8 ) into a digital signal using the output of a sampling frequency oscillator ( 7 );
a Hilbert converter ( 403 ) that converts the digital data into a complex signal;
a low pass filter ( 404 ) which removes unnecessary frequency components from the complex signal of the Hilbert converter ( 403 ) to provide a low pass filtered complex signal;
a bandpass filter ( 406 ) filtering the low-pass filtered complex signal, the output signal of which has a frequency characteristic corresponding to a frequency characteristic of the transmitter; and
a power calculation unit ( 407 ) that calculates the leakage power derived from the bandpass filtered output signal of the bandpass filter ( 406 ) in real time. 2. The apparatus of claim 1, wherein the low-pass filtered complex signal is reduced by a reduction unit ( 405 ) to a certain level and wherein the output signal of the reduction unit ( 405 ) is fed to a bandpass filter ( 406 ). 3. A method for measuring the leakage power between adjacent channels of an object to be measured, preferably a transmitter, with the following steps:
Mixing an output of a local oscillator ( 6 ) with a signal of the object to be measured for transmitting the signal to a medium frequency;
Converting an output signal of the mixer ( 8 ) with an A / D converter ( 3 ) into a digital signal with the output of a sampling frequency oscillator ( 7 );
Converting the digital data into a complex signal by a Hilbert converter ( 403 );
Removing unnecessary frequency components from a Hilbert converter ( 403 ) signal by a low pass filter ( 404 );
Converting an output signal of the low pass filter ( 404 ) using a band pass filter ( 406 ) whose output signal has a frequency characteristic corresponding to the frequency characteristic of the transmitter; and
Real-time calculation of the leakage power from the converted output of the bandpass filter ( 406 ) using a power calculation unit ( 407 ). 4. The method of claim 3, wherein a reduction operation is performed on the low pass filter output by a reducing unit, and wherein the output signal of the reducing unit ( 405 ) is supplied to the bandpass filter ( 406 ).