DE4024438C2 - Real-time digital frequency meter with spatial sampling - Google Patents

Description

The invention relates to a frequency meter in which a spatial frequency measurement on the envelope of a ste The wave is made by the signal whose Frequency to be measured in a shorted Transmission line is generated.

With such a frequency meter, the frequency measurement takes place solution by spectral analysis, the significant maximum the amount of the Fourier transform of the envelope of the standing wave, which is identified by a number of Diodes is detected, which along the transmission line tion are distributed. Since in practice only one dis krete Fourier transforms with a limited number of Points, this measurement is carried out by determining the that point of the discrete Fourier transform which  the amount corresponds to the maximum, whereupon an interpola tion around this point.

According to the current state of the art, the Interpola tion, if it should be precise, only be done digitally that the points of the discrete Fourier-transformed digita must be lized or, if necessary, also along the transmission line detected voltages, the spec tral analysis is then also done digitally.  

From US Pat. No. 3,541,443 a method for Known frequency measurement based on the investigation of the envelope curve based on standing waves caused by the signal, whose frequency is to be measured in a short-circuited be generated transmission line. This measuring ver driving is two on the transmission line Arrange detectors at two points, experimentally so be determined that one at the output of the detectors Tension ratio, which is above the measured Frequency range changed as linearly as possible. This span The ratio is then digitized to a digital one Get value of the measured frequency. The digitali is using an analog amplifier with an inverter output and a non-inverted output, contr status networks and threshold comparators.

From European patent application EP 0 313 765 A1 known another frequency measurement method, which on the Interferometer principle is based. The arrangement for performing of the method has N detector cells, each detector gate cell a code of the N-bit to be determined represents digital frequency value. With N = 4 detector cells whose characteristics can be designed so that the first Detector cell up to half of the frequency to be measured range a frequency value of -1 and from half of the measuring frequency range a frequency value of +1 gives. From the second to the fourth detector cell Frequency range increasingly finely divided and the number the zero crossings of the characteristic curve increase.

With the present invention, a frequency meter is intended create who works precisely and is easy to set up is.  

The invention relates to a digital real-time frequency meter that works with spatial scanning and is provided with:

• - A transmission line that short-circuited on the output side is and a signal on the input side with the unknown, receives frequency to be measured, this signal in the Transmission line standing waves generated;
• - Detectors distributed along the transmission line and the amplitude of the standing wave envelope scan that arises inside the transmission line;
• - First means to discriminate the spatial frequency, the proportion of which is equal to m, where m is an integer which is greater than 1, these means being connected at their inputs in parallel to the outputs of the detectors and which is periodic Fre have frequency response, with alternating passbands and stop bands, which are separated by transitions, which are evenly distributed over the entire frequency range of the frequency meter, their number doubling when one passes from one spatial frequency discriminator to another, further this number assumes a single transition near half of the entire frequency range of the frequency ^meter for a first spatial frequency discriminator device in order to achieve 2 ^m-1 transitions in another;
• - Second frequency discriminator means, the number of which is equal to m is and that at their inputs parallel to the outputs of the detectors are connected and via a frequency word, each complementary to that of the first spatial frequency discriminator means; and
• - A set of m comparators, each of which is the output si gnal of a first spatial frequency discriminator means with that of the second spatial frequency discriminator compare the frequency response of which is complete is mental to your own frequency response, and together Give word out of m bits, which is characteristic of the to measuring frequency is.

According to an embodiment variant, the second rooms Lichen frequency discriminator means, their frequency response complementary to that of the first spatial frequency discriminator nator means are, by a single second spatial Fre quency discriminator device replaced, its frequency response is of the bandpass type, with an output signal level, which is the mean signal level at the outputs of the first corresponds to spatial frequency discriminator means, the m comparators each the output signal of a first room Lichen frequency discriminator means with that of the second compare spatial frequency discriminator means.

Further features and advantages of the invention result from the following description and from the drawing to which Reference is made. The drawing shows:  

Figure 1 is a block diagram of a frequency meter according to the invention.

Fig. 2 is a diagram each showing the frequency response of the spatial frequency discriminator means used in the frequency meter according to the invention;

Fig. 3 is a schematic diagram of an embodiment of the frequency meter;

Fig. 4 is a diagram, the curves of which each represent the frequency response, which appears at the output of the differential amplifier in the schematic diagram of Fig. 3;

Fig. 5 shows a practical embodiment of a frequency meter according to the Invention;

Fig. 6 shows another practical embodiment of the frequency meter; and

Fig. 7 shows an embodiment variant, which consists in that two of the frequency meters shown in the previous figures are connected in cascade.

In Fig. 1 a transmission line 1 can be seen, one end 2 is short-circuited and the other end 3 a signal sin wt receiving whose frequency is to be measured. A standing wave is formed in this transmission line, the spatial frequency Fs of which is linked to the frequency f of the incoming signal by the following relationship.

f = c Fs / 2 (1)

Where c is the speed of propagation of the waves in the transmission line. N square detectors, each of which is illustrated by a diode 11 , 12 , 13 , 14 , 15 and 16 , followed by a low-pass filter 21 , 22 , 23 , 24 , 25 and 26 , are connected on the input side to taps which are uniformly along the transmission line 1 are distributed. The dividing step of these taps corresponds, in order to satisfy the scanning theorem, to half the minimum spatial period of the envelopes of standing waves that can arise in the transmission line 1 when a signal to be measured has the maximum frequency permissible for the frequency meter. Knowing the distance of the short circuit from the nearest square detector enables the mirror effect generated by the short circuit to be exploited to simulate a double length transmission line for spatial sampling that picks up the signal at two ends whose frequency is to be measured.

The N outputs of the square detectors are connected to the N conductors of a bus line 4 , which are connected to the inputs of two banks of m spatial frequency discriminators 31 , 32 , 33 and 41 , 42 , 43 . The first bank of spatial frequency discriminators 31 , 32 , 33 consists of m spatial frequency discriminators that have a periodic frequency response, with alternating pass and stop bands that are separated by transitions that are evenly distributed over the entire frequency range of the frequency meter are, their number is doubled from one spatial frequency discriminator to the other, if one assumes in a spatial frequency discriminator 31 with a single transition near half of the entire frequency range of the frequency meter, and ultimately a number 2 in another spatial frequency discriminator 33 to achieve ^m-1 transitions, in the intermediate stages 2 ¹ , 2 ^2. , , 2 ^m-2 transitions exist. The second bank of m spatial frequency discriminators 41 , 42 , 43 consists of spatial frequency discriminators, the frequency response of which is complementary to that of the spatial frequency discriminators 31 , 32 , 33 of the first bank. The outputs of each pair of spatial frequency discriminators 31 , 41 or 32 , 42 and 33 , 43 of the two banks, whose frequency response is complementary, are connected to the inputs of a comparator 51, 52 and 53 , respectively, which have a binary signal on the output side generated which has one or the other state, depending on whether the frequency to be measured is within the pass band or the stop band of the spatial frequency discriminator belonging to the first bank in the pair under consideration. The outputs of the comparators 51 , 52 , 53 emit a binary word of m bits, which is characteristic of the relative position of the frequency to be measured in the interior of the entire frequency band of the frequency meter and is applied to an encoder 60 , which has a recoding thereof Word from m bits into a natural binary code.

The diagrams shown in FIG. 2 each represent the frequency response of the first and the second bank of spatial frequency discriminators, as a function of the temporal frequency of the signal applied to the transmission line 1 , which is derived from the spatial frequency of the standing wave in the transmission line 1 derives the linear relationship ( 1 ).

The curve V ₁ corresponds to the frequency response of the spatial frequency discriminator 31 of the first bank. It shows a single transition near the center of the entire frequency range of the frequency meter between a stop band that occupies the low frequency range and a pass band that occupies the upper frequency range.

The curve V ' ₁ corresponds to the frequency response of the spatial frequency discriminator 41 of the second bank. Their shape is complementary to curve V ₁ . It shows a single transition near the center of the entire frequency range of the frequency meter between a pass band that occupies the low frequency range and a stop band that occupies the upper frequency range.

The combination of these two frequency responses V ₁ and V _'1 at the additive and at the subtractive input of the comparator 51 makes it possible to take a binary signal at the output of the comparator 51 when the frequency of the signal to be measured is within the stop band of the spatial frequency discriminator 31 of the first bank and within the lower frequency range of the frequency meter, or a signal in state 1 if the frequency of the signal to be measured lies in the pass band of the spatial frequency discriminator 31 of the first bank and in the upper frequency range of the frequency meter.

The curve V ₂ corresponds to the frequency response of the spatial frequency discriminator 32 of the first bank. It has two transitions, which are close to the mean values of the low and the high frequency range of the frequency meter and delimit a central pass band which lies between two stop bands, the width of the pass band corresponding to that of the two blocked regions.

The curve V ' ₂ corresponds to the frequency response of the spatial frequency discriminator 42 of the second bank. Their shape is complementary to that of curve V ₂ .

The combination of these two frequency responses V ₂ , V ' ₂ at the additive and at the subtractive input of the comparator 52 makes it possible to take a binary signal at the output of the comparator 52 when the frequency of the signal to be measured is in the stop band of the spatial frequency discriminator 32 and in the first half of the low frequency range or in the second half of the upper frequency range of the frequency meter, or a signal in state 1 if the frequency of the signal to be measured is in the pass band of the spatial frequency discriminator 32 and in the second half of the low frequency range or first half of the upper frequency range of the frequency meter.

The state of the binary signal at the output of the comparator 52 enables the signal frequency to be measured to be determined in relation to an alternating series of 1 + 2 ¹ ranges, where the total frequency range of the frequency meter is divided. In combination with the state of the binary signal at the output of the comparator 51, it enables the signal frequency to be measured to be determined in relation to a sequence of 2 ² regions of the same width, which occupy the total frequency range of the frequency meter.

The curve V _m corresponds to the frequency response of the last spatial frequency discriminator 33 of the first bank. It has 2 ^m-1 transitions between passband and stopband, which are evenly distributed within the total frequency range of the frequency meter.

The curve V ' _m corresponds to the frequency response of the last spatial frequency discriminator 43 of the second bank. Their shape is complementary to that of the curve V _m .

The combination of these two frequency responses at the additive and at the subtractive input of the comparator 53 makes it possible to take a binary signal in state 0 at the output thereof if the frequency of the signal to be measured is in a stop band of the spatial frequency discriminator 33 , or a signal in state 1 when the frequency of the signal to be measured is in a pass band of the spatial frequency discriminator 33 so as to determine the signal frequency to be measured with respect to an alternating series of 1 + 2 ^m-1 ranges, thereby dividing the overall frequency range of the frequency ^meter ,

Because of this binary signal, which is completed by the total of the output signals of the other comparators 51 , 52 , the signal frequency to be measured can be determined by determining its position with respect to a succession of 2 ^m areas of the same width, which covers the entire frequency range of the frequency meter and form a kind of gradation, the finer the larger the number m, the finer.

The spatial frequency discriminators are synthesized in that the frequency responses of the narrow-band frequency discriminators can be combined, ver in the total frequency range of the frequency meter divides lie and the points of the discrete Fourier transform tion, which is calculated from the tensions that are emitted by the N square detectors.

These points of the discrete Fourier transform form namely a real spectrum since the transmission line is short-circuited and the detected voltages are symmetrical with respect to the short-circuit. They have the following values:

Here p (n) is the normalized position of the nth detector (generally 1, 2, 3... Or 0, 5-1, 5-2, 5...), The detectors being numbered in increasing order , starting from that which is connected to the free end 3 of the transmission line to transition to that which is connected in the vicinity of the short-circuited end 2 of the transmission line, while k is the order of the sampling sample of the discrete Fourier transform, which in increasing number of transmitters is numbered by moving from the low frequencies to the high frequencies; V _n is the voltage detected by the nth detector.

To implement a filter whose frequency response has a certain shape, only the points of the discrete Fourier transforms on the abscissa values have to be used

weighted with the frequency response X (F) considered:

If F (k) is expressed by its value, we get:

which can also be written by permuting the summations:

The latter expression shows that the searched frequency response X (f) can be obtained by a linear combination of the detected voltage values V _n if they are weighted with the real coefficients C _n of the following value:

The previous considerations included the effects the scanning is not taken into account, but they are large because the number N of detectors is generally small, so that in practice the weighting coefficients depending on the desired performance must be optimized.

Fig. 3 shows a schematic diagram of the digital frequency meter, wherein each pair of spatial frequency discriminators, which are connected to the input of a comparator 51 ', 52 ', 53 ', is formed by a single differential amplifier 71 , 72 or 73 which receives the voltages V _n at its inputs, which the detectors emit, each because of a resistor whose function corresponds to the weighting. Each resistor has a weighting coefficient C " _n , which is positive if it is connected to the non-inverting input of the differential amplifier, or negative if it is connected to the inverting input of the differential amplifier, corresponding to the sum of weighting coefficients C _n , C ' _n equal order of the discriminators of the couple under consideration.

Fig. 4 shows the output voltages V ₇₁ to V _{73 of} the dif ferential amplifier 71 to 73 in Fig. 3, which directly form the difference in the output signals of the complementary spatial frequency discriminators of the type shown in Fig. 2. The output comparators 51 'to 53 ' compare with the reference quantity 0 and consequently operate as polarity detectors.

Fig. 5 shows an embodiment of a digital frequency meter, in which the differential amplifier of each pair of discriminators consists of two successive inverting operational amplifier stages 710 , 711 and 720 , 721 as well as 730, 731, each with a negative feedback resistor 712 , 713 and 722 , 723 and 732 , 733 are provided.

Fig. 6 shows the circuit diagram of a simplified exporting tion of the frequency meter, wherein the Differenzverstär ker of the pairs of spatial frequency discriminators a first common stage 700 and different second stages 714, 715, have 716th The common use of the first stage 700 of the differential amplifier reduces the number of operational amplifiers used and the number of weighting resistors. It is justified by the following equation, which represents the frequency response X "m (f) of the same pair of spatial frequency discriminators:

If the coefficients Xn are chosen so that the term C "m, n-Xn is negative, regardless of the respective pair of spatial frequency discriminators, it can be seen that the weighting coefficients of all pairs of spatial frequency discriminators can be broken down into a set of Weighting coefficients (C "m, n-Xn), which are all negative and vary for each pair of spatial frequency discriminators, and into a set of weighting coefficients Xn, which are all positive and are invariant for all pairs of spatial frequency discriminators. The set of positive weighting coefficients Xn is realized by means of the first common inverting operational amplifier stage 700 , which is connected on the input side via resistors to the various outputs of the detectors, while the set of negative weighting coefficients is achieved by the second, individual and inverting operational amplifier stages 714 , 715 , 716 is formed, which are connected on the input side via resistors to the output of the first stage and to the various detectors. This circuit implementation results in practice in that a single spatial frequency discriminator is used as the second discriminator of each pair, the frequency response of which is of the all-pass type and the output side emits a signal whose level is the average output level of the first spatial frequency discriminator of each pair equivalent.

Fig. 7 shows the circuit diagram of an embodiment, which consists in the fact that two frequency meters of the type described above are connected in cascade, with a shared encoder, using transmission lines of different lengths. The first circuit arrangement 100 works with a transmission line 101 , the taps of which have a distance which is selected as a function of the entire operating frequency range, and supplies a word of m 'bits which represents the frequency to be measured. The second circuit arrangement 200 works with a transmission line 201 , the intermediate handles have a greater distance, for an operating frequency band that is 2 ^{m '} times smaller, and supplies a binary word of m "bits, which is the frequency to be measured with a Represents accuracy that is 2 ^{m '} times as large as that of the binary word of the first stage 100 , but the ambiguities are resolved by the binary word of this first circuit arrangement. The binary word from the first circuit arrangement 100 composed of m' bits and that Binary word of m "bits output by the second circuit arrangement 200 are applied to a common encoder 300 , which outputs a measured value for the frequency in the natural binary code on m '+ m" bits.

The accuracy of these two cascaded circuit arrangements is that of an arrangement which outputs m '+ m "bits as a frequency measurement and requires approximately 2 ^{m' + m '} detectors, while only 2 ^m' + 2 ^{m '} are present.

In practice, the scanning in these two cascade-connected circuit arrangements has the effect that the sensitivity of the second circuit arrangement 200 periodically tends to zero depending on the frequency. The com parature 400 has the task of determining whether the second circuit arrangement 200 is operating in a zone of low sensitivity. If so, the frequency measured by the second circuit must be replaced by that corresponding to the zone of low sensitivity. In the event that the short circuit at the end of the transmission line 200 is at a distance from the first detector which is equal to half the pitch between the detectors, this value to be replaced is 0. This replacement is carried out by AND gates 500 which are controlled by the comparator 400 and are inserted between the second circuit arrangement 200 and the encoder 300 .

Claims (8)

1. Digital real-time frequency meter that works with spatial sampling with

• - A transmission line ( 1 ) which is short-circuited at the output ( 2 ) and at the input ( 3 ) receives a signal to measure the frequency, this signal generating a standing wave in the transmission line ( 1 ); and
• - Detectors ( 11 , 12 , 13 , 14 , 15 , 16 ), which are distributed along the transmission line ( 1 ) and scan the amplitude of the envelope of the standing waves, which are generated in the transmission line ( 1 ), characterized by :
• - First spatial frequency discriminator means ( 31 , 32 , 33 ), the number of which is equal to m, where m is an integer greater than 1, the inputs of which are parallel to the outputs of the detectors ( 11 , 12 , 13 , 14 , 15 , 16 ) are connected and the frequency response is periodic with alternating passbands and stop bands, which are separated by transitions that are regularly distributed within the total frequency range of the frequency meter, the number of which doubles when one passes from a first filter device to another, whereby furthermore, this number assumes a single transition near half the total frequency range of the frequency ^meter for a first spatial frequency discriminator device ( 31 ) to achieve 2 ^m-1 transitions in another ( 33 );
• - Second spatial frequency discriminator means ( 41 , 42 , 43 ), the number of which is equal to m and whose inputs are connected in parallel to the outputs of the detectors ( 11 , 12 , 13 , 14 , 15 , 16 ), and whose frequency response is complementary to each that is the first spatial frequency discriminator medium ( 31 , 32 , 33 ); and
• - A set of m comparators ( 51 , 52 , 53 ), each comparing the output signal of a first spatial frequency discriminator means ( 31 or 32 , 33 ) with that of the second frequency discriminator means ( 41 or 42 , 43 ), the frequency response of which is complementary to each one, and which together output a word of m bits, which is characteristic of the frequency to be measured.

2. Frequency meter according to claim 1, characterized in that it further comprises an encoder ( 60 ) which is arranged at the output of the set of m comparators ( 51 , 52 , 53 ) and which is output by the comparators ( 51 , 52 , 53 ) Word of m bits converted into a natural binary code. 3. Frequency meter according to claim 1, characterized in that the first and the second spatial frequency discriminator means are formed jointly by differential amplifiers ( 71 , 72 , 73 ) which are connected on the input side to the detectors via weighting resistors, the amount of m comparators ( 51 ', 52 ', 53 ') then compare each output signal of the differential amplifiers ( 71 , 72 , 73 ) with a voltage of zero to determine the sign. 4. Frequency meter according to claim 3, characterized in that the differential amplifiers ( 71 , 72 , 73 ) each have two successive inverting operational amplifier stages ( 710 , 711 or 721 , 722 and 731 , 732 ), each with a negative feedback resistor ( 712 , 713 and 723 , 726 and 733 , 734 ) are provided. 5. Digital real-time frequency meter that works with spatial sampling with

• - A transmission line ( 1 ) which is short-circuited at the output ( 2 ) and receives a signal of unknown frequency at the input ( 3 ), this signal in the transmission line ( 1 ) generating standing waves; and
• - detectors (11, 12, 13, 14, 15, 16) which are distributed over tragungsleitung along the (1) and the amplitude of the envelope of the standing waves inside the Übertra supply line (1) scan, characterized by:
• - First spatial frequency discriminator means, the number of which is equal to m, where m is an integer greater than 1, the inputs of which are connected in parallel to the outputs of the detectors ( 11 , 12 , 13 , 14 , 15 , 16 ) and whose frequency response is periodic with alternating passbands and stopbands separated by transitions which are regularly distributed over the entire frequency range of the frequency meter, the number of which doubles when one passes from a first spatial frequency discriminator means to another, and this number of assumes a single transition near half the total frequency range of the frequency ^meter for a first spatial frequency discriminator means to achieve 2 ^m-1 transitions in another;
• - Second spatial frequency discriminator means, whose inputs are connected in parallel to the outputs of the detectors ( 11 , 12 , 13 , 14 , 15 , 16 ), and whose frequency response is of the all-pass type, with a level of the output signal which corresponds to the average level corresponds to the output signals of the first spatial frequency discriminator means; and
• - A group of m comparators, each of which compares the output signal of a first spatial frequency discriminator with the output signal of the second spatial frequency frequency discriminator means to jointly output a word of m bits, which is characteristic of the frequency to be measured.

6. Frequency meter according to claim 5, characterized in that it further comprises an encoder ( 60 ) which is arranged at the output of the group of m comparators and the word emitted by these m bits converted into a natural binary code. 7. Frequency meter according to claim 5, characterized in that the first and the second spatial frequency discriminator contain differential amplifiers which are connected to the outputs of the detectors via weighting resistors and which consist of two successive inverting operational amplifier stages, the first stage ( 700 ) of the Common to the set of differential amplifiers is the second, individual amplifier stages ( 714 , 715 , 716 ). 8. Arrangement of frequency meters according to one of claims 1 to 5, characterized in that at least two of these frequency meters are present, of which the first ( 100 ) has a transmission line ( 101 ), the intermediate taps have a distance which is a function of the total Operating frequency range of the arrangement is chosen to provide a binary word of m 'digits, where m' is an integer greater than 1, which is representative of the frequency to be measured, and that the second frequency meter ( 200 ) has a transmission line ( 201 ), whose intermediate taps have distances which are selected as a function of an operating frequency band which is 2 ^{m '} times smaller than that of the arrangement in order to deliver a binary word of m "digits which indicate the accuracy of the binary word of m 'Increase digits that the first frequency meter ( 100 ) outputs.