Quartz filter 10 m 2.4 d. Quartz filters "Desna" - Document. Simple Intermediate Frequency Crystal Filter

During the construction of a receiver for amateur communications with double conversion, it was necessary to select and look at the real frequency response of the IF filter, to make sure that it was within the range of 2.5-2.8 kHz, necessary for comfortable reception of SSB stations. Since I have virtually no measuring equipment, I had to use an old friend made on the basis of RTL SDR.

In general, it turned out to be a matter of two minutes. The SDR receiver acts as a spectrum analyzer. In an amicable way, it was necessary to assemble a noise generator, but in the industrial zone there is no better noise generator than the air itself. That’s what I did, I connected an antenna to the input of the filter (an active full-size frame of the 40 meter band), and connected the output to the converter. Due to the fairly high gain of the antenna amplifier, the broadcast acted as a noise source, and the SDR receiver showed the real frequency response of the filter. despite the fact that according to the picture, the suppression behind the passband is only 40db, the real suppression is much higher due to the fact that the air noise level is still not enough to evaluate the dynamic characteristics, but the shape and width of the frequency response is quite possible to estimate.

Speaking of the filter...

Simple quartz filter intermediate frequency

This is the so-called ladder filter, which uses Shirpotreb quartz resonators. In my case these are 10 MHz resonators. Due to the low price, our stores sell them in 5 pieces, this set is just enough for the receiver: 4 pieces will go to the IF filter, and another one will be used in the second local oscillator.

In my case, CS1 = 33pf, Cp1, Cp2 = 62pf. All crystals are 10 MHz. The final bandwidth is 2.5-2.8 kHz, depending on what level you evaluate at.

The selection of capacitances was carried out with a three-section capacitor connected, 3x12-495pF. By rotating we achieve the required width of the frequency response, while the change in band in real time is visible on the computer screen, for me it changed from 5-6 kHz to 200 Hz, while a more or less flat frequency response was within 1-3 kHz, you could choose any band. You can also easily implement band switching, for example, 1.8, 2.5, 3.3 kHz. Almost any quartz can be used, based on the required IF value, which may depend on the capabilities of the local oscillator; in this case, the capacitances will have to be selected experimentally.

You often come across the phrase in articles: “A quartz filter is easier to tune using curve tracers (for example, X1-38, X-1-48, SK-4-59, etc.). Of course, if they are available, then setting up the filter is simple. But this if you have the appropriate device, and even instructions for it. Otherwise, the word “easy” will quickly turn into its opposite, “difficult.” Therefore, this article focuses on setting up a quartz filter using the simplest devices.

Some articles omit information about the type of filter being configured (ladder, bridge, monolithic) when describing general rules settings. However, I came to the conclusion that each of them, along with common ones, also has its own characteristics.

Let's start by setting up a ladder-type filter (Fig. 1).

Fig.1

Experience shows that:

The filter is obtained with the best parameters if all crystals have as close as possible successive resonance frequencies (±10 Hz). However, you should not be upset if this condition is not fulfilled, because a good filter is obtained even with a frequency spacing of up to 1 kHz;

It is best to select quartz by including them in the reference oscillator of the device in which this filter is supposed to be used, and use the lowest frequency of them directly in the reference oscillator. In this case, the tuning elements of the generator should not be touched;

The filter should be configured directly as part of the “native” device;

If quartzes have unequal frequencies, they should be placed in the following sequence: the highest frequency should be installed first at the input, and all subsequent ones - alternately from left to right, by rank, with a decrease in frequency;

Small-sized containers should be used, with a minimum temperature coefficient of capacity (TKE) with an accuracy of no worse than ±1.5%. But don’t despair if you don’t find any, because you will still have to select them during the setup process. In most cases, during the setup process, up to 90% of the containers are replaced with other (albeit close) denominations;

It is better to use filter quartz (taken, for example, from disassembled factory filters).

So, from four filters at a frequency of 10.7 MHz (type FP2P-325-10700M-15), you can assemble four eight-crystal ladder filters (these filters have four pairs of quartz with the same frequencies) with different, but close to 10.7 MHz frequencies. Typically, this is what several radio amateurs do (usually 4 people), each having one filter. The most experienced of them selects four sets of quartz of the same frequency, then quartz with the minimum. he keeps the scatter for himself, and gives the rest back to his friends (or vice versa?!). Generator quartz can also be used with somewhat less success.

At home, a quartz filter can be configured in three ways.

In the first case, you should use (in addition to the device being tuned) another transceiver with a digital scale as an auxiliary device, in the second case - a GSS (standard signal generator) and a frequency meter (with a limit frequency exceeding at least the lowest frequency of your device being tuned, for example 1.9 MHz). A frequency meter measures either the GSS frequency or the GPA frequency of the device under study.

In the third case, a quartz local oscillator is used at one of the operating frequencies (either the GSS or another transceiver without digital scale), and the presence of a digital scale in the device being configured is mandatory.

In all three cases, an RF signal of the operating range is supplied to the input of the device being tuned. In the first two cases, the supplied frequency is slowly changed in the transparency band of the quartz filter, while taking S-meter readings in relative units, and recording them in the table every 200 Hz. Then, according to the table, graphs (frequency response) are constructed. The S-meter readings are plotted vertically, and the frequency is plotted horizontally. By connecting the points marked on the graph with an interpolation (averaging) line, we obtain the frequency response - the amplitude-frequency characteristic of the new filter.

In the third case, everything is done in the same way, only the tuned device itself is adjusted in frequency, taking readings directly from its digital scale and S-meter at the same time.

In this case, the “newly made” filter, as a rule, has:

A different lane than required;

Unevenness in the upper part of the frequency response;

Gentle (and sometimes with emissions) lower slope of the frequency response.

In the future, the filter is configured in the three above directions in order of priority.

At the first stage of tuning (rough tuning), you should obtain a filter bandwidth of up to 2.4 kHz by replacing the capacitors one by one, starting from the filter input, and removing the frequency response. Please keep the following in mind:

If you install additional capacitors parallel to the quartz (especially the outermost ones) and increase their nominal value (up to a certain limit), then the filter bandwidth will decrease. A similar effect will be observed when increasing the capacitance of the capacitors going to the housing. As the values of these capacities decrease, one will observe reverse effect. This property is used to narrow the bandwidth of a quartz filter in telegraph mode. In this way, the bandwidth can be reduced to 0.8 kHz. With further narrowing of the band, the attenuation of the filter in the transparency band sharply increases (to obtain low attenuation in a CW filter, resonators with a quality factor at least an order of magnitude higher than the quality factor of the filter should be used);

The magnitude of the “humps” and dips in the upper part of the frequency response (linearity of the characteristic) will depend not only on the size of the selected capacitances, but also on the resistance value of the load resistors installed at the input and output of the filter. As their resistance decreases, the linearity of the characteristic improves, but the attenuation in the filter passband increases;

If it is impossible to obtain a sufficient steepness of the lower slope, quartz should be installed parallel to the load resistors, similar to those used in the filter, and from all available quartz, the lowest frequency should be selected or its frequency should be lowered by connecting the inductance in series. By selecting the number of turns of this inductance, you can change the steepness of the lower slope;

The filter settings must be repeated several times. If on last stage settings cannot be obtained to achieve an acceptable frequency response, it is necessary to try to adjust the frequency of the sequential resonance of individual quartzes. To do this, a capacitor is installed in series with the quartz, and by selecting this capacitor, generation is achieved at the frequency of the remaining quartz. If this does not help (and this may happen if the difference between the frequencies of the parallel and series resonances of the quartz is small), the quartz should be replaced. The quartz in the filter should be placed in a chain, carefully shielding the input from the output. Figure 2 shows the frequency response of the CF receiver "TURBO-TEST", taken with different meanings capacitor capacities. -

Fig. 2 - For greater clarity, the frequency values are taken without respecting the received sideband and the actual IF value. Figure 3 shows the frequency response of the final filter setup. -

Fig.3

Now several practical advice on setting up a bridge quartz filter. Such a filter is shown in Fig. 4. Coils L1 and L2 contain 2x10 turns of wire with a diameter of 0.31 mm; ferrite rings from the FP2A-325-10,700 M-15 filter are used as cores. The filter bandwidth is 2.6 kHz.

Fig.4

If you have a filter for low frequencies (2...6 MHz), it usually turns out to be more narrowband than required, and if a filter for high frequencies (8...10 MHz) is too broadband. In the first case, the bandwidth should be expanded by connecting inductors to the upper or lower (Fig. 4) quartz, which should be selected experimentally. In the second case, in order to reduce the bandwidth, it is necessary to connect trimming capacitors in parallel with the resonators (similar to coils). The quartz in the filter must be selected with an accuracy of 50 Hz (series resonance frequency), and the frequencies of all upper resonators must be the same and differ from the lower ones (also identical) by 2...3 kHz.

If only crystals of the same frequencies are available, you can change the frequency of the crystals by erasing the silver-plated layer from the crystal (increase the frequency) or by shading with a pencil (lower). But practice shows that the stability of the parameters of such a filter over time leaves much to be desired.

More stable results are obtained by adjusting the frequency by connecting a tuning capacitor in series with quartz. After adjustment, it is advisable to replace the capacitor with a constant capacitance of the same size.

With a large filter bandwidth, a dip (attenuation) may appear in the middle of its frequency response. It should be said that its depth largely depends on the resistance of resistors R1 and R2. Their value can be from hundreds of ohms (with a bandwidth of 3 kHz) at frequencies of 8...10 MHz to several kilo-ohms at more low frequencies ah and with a smaller filter bandwidth. When making a bridge filter, you should great attention pay attention to the symmetry of its shoulders, as well as the windings of the transformers included in it, and, of course, careful shielding of the input from the output. You can read more about bridge filters in.

Literature

1. Goncharenko I. Ladder filters on unequal resonators. - Radio, 1992, No. 1, P. 18.
2. Bunin S.G., Yaylenko L.P. Shortwave Radio Amateur's Handbook. - K.: Technology, 1984, P.21...25.

Fig. 1 Quartz filters with “parallel” capacitances

Arrows AA and BB show the second option for switching on the KPI. Resistors R1, R4 (0 ... 300 Ohms) are installed in the presence of large emissions in the frequency response. Capacitor C4* is selected in the range from 0 to 30 pF.

In order to minimize the number of capacitors, filter circuits containing only parallel capacitances were selected, Fig. 1. Since the filters are symmetrical (with respect to their input-output), it turned out to be possible to use dual KPIs from broadcast receivers with a capacity of 12 - 495 pF. In addition, you will need another single-section variable capacitor, pre-calibrated in pF.

Setting up the filter is as follows.

To configure, you may need a device for measuring amplitude-frequency characteristics X1-38 or similar. I use an oscilloscope and homemade console(see below).

Initially, all capacitors are installed in a position corresponding to a capacitance of 30 ... 50 pF. By controlling the frequency response of the filter on the device screen and rotating the capacitors within small limits, we achieve the required bandwidth. Then, by adjusting variable resistors (use only non-induction ones, for example, SP4-1) at the input and output of the filter, we try to level the peak of the frequency response. The above operations are repeated several times until the desired frequency response is obtained.

Next, instead of each individual section of the KPI, we solder a pre-calibrated capacitor, with the help of which we try to optimize the frequency response of the filter. Using its scale, we determine the capacitance of the permanent capacitor and replace it. Thus, all sections of the KPI are, in turn, replaced with capacitors of constant capacity. We do the same with variable resistors, which we will later replace with constant ones.

The final “finishing” of the filter is done directly on site, for example, in the transceiver. After installing the filter in the transceiver, it may be necessary to correct the values of these resistors; in this case, for optimal matching of the filter with the output of the mixer and the input of the amplifier, the frequency converter and the oscilloscope must be connected according to the diagram shown in Fig. 2.

Fig.2 Connecting a quartz filter for final settings

Several filters were manufactured using the described method. I would like to note the following. Setting up three or four crystal filters with some skill takes no more than an hour, but with 8 crystal filters the time investment is much higher. At the same time, attempts to pre-set first two separate 4-crystal filters, and then connect them, turned out to be fruitless. The slightest scatter of their parameters (and this always occurs) leads to a distortion of the resulting frequency response. It is also interesting to note that theoretically equal capacitances (for example, C1=SZ, in Fig. 1a; C1=C7; SZ=C5, in Fig. 1b) after tuning with a graduated KPI according to the optimal frequency response had a noticeable scatter.

In my opinion, the advantage of this technique is its clarity. The device screen clearly shows how the frequency response of the filter changes depending on the change in the capacitance of each capacitor. For example, it turned out that in some cases it is quite enough to change the capacitance of one capacitor (using a relay) in order to change the filter bandwidth without significantly deteriorating its squareness.

As noted above, to configure the filter, an S1-77 oscilloscope and a converted attachment for measuring frequency response are used.

Why S1-77? The fact is that on its side wall there is a connector on which there is a sawtooth voltage of the scan generator. This makes it possible to simplify the set-top box itself and eliminate the sawtooth voltage generator (RVG) from its circuit. Therefore, there is no need for additional synchronization and it becomes possible to observe a stable frequency response at different sweep durations. Obviously, other types of oscilloscopes can be adapted, perhaps with a little modification.

Since the simplified attachment is used only when working with quartz filters near a frequency of 8 MHz, all other subranges were excluded from it.

Also, in the set-top box you are using, you will need to slightly increase the output voltage. To do this, it is enough to convert the output stage into a resonant one. It must be tuned to resonance each time a new filter is connected to its output.

Fig.3 Attachment to an oscilloscope for setting up quartz filters

Literature.

V. Zalnerauskas. Series of articles “Quartz filters” Radio magazine No. 1, 2, 6 1982, No. 5, 7 1983
S. Bunin, L. Yaylenko “Handbook of shortwave” ed. "Technique" 1984
V. Drozdov “Short-wave transceivers” ed. "Radio and Communications" 1988
Radio magazine No. 5 1993 “Swinging frequency generator”

The quartz filter is, as we know, “half of a good transceiver”. This article presents a practical design of twelve basic selection crystal quartz filters for a high-quality transceiver and computer attachment, allowing you to configure this and any other narrow-band filters. In amateur designs, eight-crystal ladder-type quartz filters made on identical resonators have recently been used as the main selection filter. These filters are relatively simple to manufacture and do not require large material costs.

Computer programs have been written for their calculation and modeling. The characteristics of the filters fully satisfy the requirements for high-quality signal reception and transmission. However, with all the advantages, these filters also have a significant drawback - some asymmetry of the frequency response (flat low-frequency slope) and, accordingly, a low squareness coefficient.

The congestion of amateur radio broadcasts determines quite stringent requirements for the selectivity of a modern transceiver on an adjacent channel, therefore the main selection filter must provide attenuation outside the passband of no worse than 100 dB with a squareness factor of 1.5... 1.8 (at levels -6/-90 dB ).

Naturally, the losses and unevenness of the frequency response in the filter passband should be minimal. Guided by the recommendations set out in, a ten-crystal ladder filter with a Chebyshev characteristic with an uneven frequency response of 0.28 dB was chosen as the basis.

To increase the steepness of the slopes parallel to the input and output of the filter, additional circuits were introduced, consisting of series-connected quartz resonators and capacitors.

Calculations of the parameters of the resonators and filter were carried out according to the method described in. For a filter passband of 2.65 kHz, the initial values were obtained: C1,2 = 82.2 pF, Lkv = 0.0185 Hn, Rn = 224 Ohm. The filter circuit and the calculated values of the capacitor values are shown in Fig. 1.

The design uses quartz resonators for television PAL decoders at a frequency of 8.867 MHz, produced by VNIISIMS (Aleksandrov, Vladimir region). The stable repeatability of crystal parameters, their small dimensions and low cost played a role in the choice.

The selection of the frequency of quartz resonators for ZQ2-ZQ11 was carried out with an accuracy of ±50 Hz. The measurements were carried out using a homemade self-oscillator and an industrial frequency meter. Resonators ZQ1 and ZQ12 for parallel circuits were selected from other batches of crystals with frequencies respectively lower and higher than the main filter frequency by approximately 1 kHz.

The filter is assembled on a printed circuit board made of double-sided foil fiberglass 1 mm thick (Fig. 2).

The top layer of metallization is used as a common wire. The holes on the side where the resonators are installed are countersunk. The housings of all quartz resonators are connected to a common wire by soldering.

Before installing the parts, the filter circuit board is sealed in a tin-plated box with two removable covers. Also, on the side of the printed conductors, a screen-partition is soldered, passing between the leads of the resonators along the central center line fees.

In Fig. Figure 3 shows the installation diagram of the filter. All capacitors in the filter are CD and KM.

After the filter was made, the question arose: how to measure its frequency response with maximum resolution at home?

Was involved home computer followed by checking the measurement results by constructing the frequency response of the filter point by point using a selective microvoltmeter. As a designer of amateur radio equipment, I was very interested in the idea proposed by DG2XK to use computer program low-frequency (20 Hz...22 kHz) spectrum analyzer for measuring the frequency response of narrow-band amateur radio filters.

Its essence lies in the fact that the high-frequency spectrum of the frequency response of a quartz filter is transferred to the low-frequency range using a conventional SSB detector and the computer with installed program spectrum analyzer makes it possible to view the frequency response of this filter on the display.

A Zener diode noise generator is used as a source of the DG2XK high-frequency signal. The experiments I carried out showed that such a signal source allows one to view the frequency response to a level of no more than 40 dB, which is clearly not enough for high-quality filter tuning. In order to view the frequency response of a filter at a level of -100 dB, the generator must have

the level of side noise is below the specified value, and the detector has good linearity with a maximum dynamic range of no worse than 90... 100 dB.

For this reason, the noise generator was replaced by a traditional sweep generator (Fig. 4). The basis is the circuit of a quartz oscillator, in which the relative spectral noise power density is equal to -165 dB/Hz. This means that the generator noise power at 10 kHz detuning in a 3 kHz bandwidth

less than the power of the main oscillation of the generator by 135 dB!

The layout of the original source is slightly modified. So instead bipolar transistors field ones are used, and a circuit consisting of an inductor L1 and varicaps VD2-VD5 is connected in series with the quartz resonator ZQ1. The generator frequency is tunable relative to the quartz frequency within 5 kHz, which is quite sufficient for measuring the frequency response of a narrow-band filter.

The quartz resonator in the generator is similar to a filter. In the sweep frequency generator mode, the control voltage to the varicaps VD2-VD5 is supplied from a sawtooth voltage generator made on a unijunction transistor VT2 with a current generator on VT1.

To manually adjust the generator frequency, a multi-turn resistor R11 is used. The DA1 chip works as a voltage amplifier. The originally conceived sinusoidal control voltage had to be abandoned due to the uneven speed of passage of the frequency response of different sections of the frequency response of the filter, and to achieve maximum resolution, the generator frequency was reduced to 0.3 Hz. Switch SA1 selects the frequency of the “saw” generator - 10 or 0.3 Hz. The frequency deviation of the MFC is set by trimming resistor R10.

The schematic diagram of the detector block is shown in Fig. 5. The signal from the output of the quartz filter is supplied to input X2 if circuit L1C1C2 is used as a filter load.

If measurements are carried out on filters loaded with active resistance, this circuit is not needed. Then the signal from the load resistor is applied to input X1, and the conductor connecting input X1 to the circuit is removed on the detector printed circuit board.

A source follower with a dynamic range of more than 90 dB on a powerful field-effect transistor VT1 matches the filter load resistance and input impedance mixer The detector is designed according to a passive balanced mixer on field effect transistors VT2, VT3 and has a dynamic range of more than 93 dB.

The combined gates of the transistors through the P-circuits C17L2C20 and C19L3C21 receive antiphase sinusoidal voltages of 3...4V (rms) from the reference generator. The detector's reference oscillator, made on the DD1 chip, contains a quartz resonator with a frequency of 8.862 MHz.

The low-frequency signal formed at the output of the mixer is amplified approximately 20 times by an amplifier on the DA1 chip. Since personal computer sound cards have a relatively low-impedance input, the detector is equipped with a powerful K157UD1 op-amp. The amplifier's frequency response is adjusted so that below 1 kHz and above 20 kHz there is a gain rolloff of approximately -6 dB per octave.

The swing frequency generator is mounted on a printed circuit board made of double-sided foil fiberglass (Fig. 6). The top layer of the board serves as a common wire; the holes for the leads of parts that do not have contact with it are countersunk.

The board is sealed in a 40 mm high box with two removable covers. The box is made of tinned sheet metal. Inductors L1, L2, L3 are wound on standard frames with a diameter of 6.5 mm with carbonyl iron trimmers and placed in screens. L1 contains 40 turns of PEV-2 0.21 wire, L3 and L2 - respectively 27 and 2+4 turns of PELSHO-0.31 wire.

Coil L2 is wound on top of L3 closer to the “cold” end. All chokes are standard - DM 0.1 68 µH. Fixed resistors MLT, tuning resistors R6, R8 and R10 type SPZ-38. Multi-turn resistor - PPML. Permanent capacitors - KM, KLS, KT, oxide - K50-35, K53-1.

The establishment of the MCC begins with setting the maximum signal at the output of the sawtooth voltage generator. By monitoring the signal at pin 6 of the DA1 microcircuit with an oscilloscope, using trimming resistors R8 (gain) and R6 (offset) set the amplitude and shape of the signal shown on the diagram at point A. By selecting resistor R12, stable generation is achieved without entering the signal limiting mode.

By selecting the capacitance of capacitor C14 and adjusting the L2L3 circuit, the output oscillatory system into resonance, which guarantees good load capacity of the generator. Using the L1 coil trimmer, the oscillator tuning limits are set within the range of 8.8586-8.8686 MHz, which overlaps the frequency response band of the quartz filter under test with a margin. To ensure maximum restructuring of the GKCH

(at least 10 kHz) around the connection point L1, VD4, VD5 the top layer of foil is removed. Without load, the output sinusoidal voltage of the generator is 1V (rms).

The detector block is made on a printed circuit board made of double-sided foil fiberglass (Fig. 7).

The top layer of foil is used as a common wire. The holes for the leads of parts that do not have contact with the common wire are countersinked.

The board is sealed in a tin box 35 mm high with removable covers. The resolution of the set-top box depends on the quality of its manufacture.

Coils L1 - L4 contain 32 turns of PEV-0.21 wire, wound turn to turn on frames with a diameter of 6 mm. Trimmers in coils from SB-12a armor cores. All chokes are type DM-0.1. Inductance L5 - 16 µH, L6, L8 - 68 µH, L7 - 40 µH. Transformer T1 is wound on a 1000NN ring ferrite magnetic core of standard size K10 x 6 x 3 mm and contains primary winding 7 turns, in the secondary - 2 x 13 turns of PEV-0.31 wire.

All trimming resistors are SPZ-38. During preliminary setup of the unit, a high-frequency oscilloscope is used to monitor the sinusoidal signal at the gates of transistors VT2, VT3 and, if necessary, adjust the coils L2, L3. By adjusting coil L4, the frequency of the reference oscillator is lowered below the filter passband by 5 kHz. This is done so that in the working area of the spectrum analyzer there is less interference that reduces the resolution of the device.

The sweep frequency generator is connected to the quartz filter through a matching oscillatory circuit with a capacitive divider (Fig. 8).

During the tuning process, this will allow you to obtain low attenuation and unevenness in the filter passband.

The second matching oscillatory circuit, as already mentioned, is located in the detector attachment. Having assembled the measurement circuit and connected the output of the set-top box (XZ connector) to the microphone or line input of the sound card personal computer, launch the spectrum analyzer program. There are several such programs. The author used the SpectraLab v.4.32.16 program, located at: http://cityradio.narod.ru/utilities.html. The program is easy to use and has great capabilities.

So, we launch the “SpektroLab” program and, by adjusting the frequencies of the MCG (in manual control mode) and the reference oscillator in the detector attachment, we set the peak of the spectrogram of the MCG at around 5 kHz. Next, by balancing the mixer of the detector attachment, the peak of the second harmonic is reduced to the noise level. After this, the GCH mode is turned on and the long-awaited frequency response of the filter under test appears on the monitor. First, the swing frequency of 10 Hz is turned on and, using R11, adjusting the central frequency, and then the swing band R10 (Fig. 4), we establish an acceptable “picture” of the frequency response of the filter in real time. During measurements, by adjusting the matching circuits, we achieve minimal unevenness in the passband.

Next, to achieve the maximum resolution of the device, we turn on the swing frequency of 0.3 Hz and set in the program the maximum possible number of Fourier transform points (FFT, the author has 4096...8192) and minimum value averaging parameter (Averaging, author 1).

Since the characteristic is drawn in several passes of the GKCh, the storage peak voltmeter mode (Hold) is turned on. As a result, we get the frequency response of the filter under study on the monitor.

Using the mouse cursor, we obtain the necessary digital values of the resulting frequency response at the required levels. In this case, you must not forget to measure the frequency of the reference oscillator in the detector attachment, in order to then obtain true values frequency response points.

Having assessed the initial “picture”, they adjust the frequencies of the sequential resonance ZQ1n ZQ12, respectively, to the lower and upper slopes of the filter’s frequency response, achieving maximum squareness at a level of - 90 dB.

In conclusion, using the printer, we obtain a full-fledged “document” for the manufactured filter. As an example in Fig. Figure 9 shows the spectrogram of the frequency response of this filter. A spectrogram of the GKCh signal is also shown there. The visible unevenness of the left slope of the frequency response at the level of -3...-5 dB is eliminated by rearranging the ZQ2-ZQ11 quartz resonators.

As a result we get the following characteristics filter: level passband - 6 dB - 2.586 kHz, frequency response unevenness in the passband - less than 2 dB, level squareness factor - 6/-60 dB - 1.41; by levels - 6/-80 dB 1.59 and by levels - 6/-90 dB - 1.67; attenuation in the band is less than 3 dB, and attenuation beyond the band is more than 90 dB.

The author decided to check the results obtained and measured the frequency response of the quartz filter point by point. For the measurements, a selective microvoltmeter with a good attenuator was required, which was a microvoltmeter type HMV-4 (Poland) with a nominal sensitivity of 0.5 μV (at the same time, it records signals well at a level of 0.05 μV) and an attenuator of 100 dB.

For this measurement option, the diagram shown in Fig. 1 was assembled. 10. The matching circuits at the input and output of the filter are carefully shielded. Connecting shielded wires are applied good quality. The “earth” circuits are also carefully executed.

Smoothly changing the frequency of the high frequency frequency resistor R11 and switching the 10 dB attenuator, we take microvoltmeter readings, passing through the entire frequency response of the filter. Using measurement data and the same scale, we build a frequency response graph (Fig. 11).

Thanks to the high sensitivity of the microvoltmeter and low side noise of the GKCh, signals are well recorded at a level of -120 dB, which is clearly reflected in the graph.

The measurement results were as follows: level passband - 6 dB - 2.64 kHz; frequency response unevenness - less than 2 dB; the squareness coefficient for levels -6/-60 dB is 1.386; by levels - 6/-80 dB - 1.56; by levels - 6/-90 dB - 1.682; by levels - 6/-100 dB - 1.864; attenuation in the band is less than 3 dB, behind the band is more than 100 dB.

Some differences between the measurement results and the computer version are explained by the presence of accumulating errors in digital-to-analog conversion when the analyzed signal changes over a large dynamic range.

It should be noted that the above graphs of the frequency response of a quartz filter were obtained with a minimum amount of setup work and with a more careful selection of components, the characteristics of the filter can be significantly improved.

The proposed generator circuit can be successfully used to operate AGC and detectors. By applying a signal from a sweeping frequency generator to the detector, we receive a signal at the output of the set-top box to the PC low frequency generator sweeping frequency, with which you can easily and quickly configure any filter and cascade of the low-frequency path of the transceiver.

It is no less interesting to use the proposed detector attachment as part of the panoramic indicator of the transceiver. To do this, connect a quartz filter with a bandwidth of 8...10 kHz to the output of the first mixer. Next, the received signal is amplified and fed to the detector input. In this case, you can observe the signals of your correspondents with levels from 5 to 9 points with good resolution.

G. Bragin (RZ4HK)

Literature:

1. Usov V. Quartz filter SSB. - Radio Amateur, 1992, No. 6, p. 39, 40.

2. Drozdov V.V. Amateur KB transceivers. - M.: Radio and communication, 1988.

3. Klaus Raban (DG2XK) Optimizierung von Eigenbau-Quarzfiltern mit der PC-Soundkarte. - Funkamateur, No. 11, 2001, S. 1246-1249.

4. Frank Silva. Shmutzeffekte vermeiden und beseitig. - FUNK, 1999, 11, S. 38.

Quartz filters "Desna"

Eight-crystal quartz filter “Desna”. Assembled, configured, without housing (shielded box). Quartz filter at a frequency of 8.865 MHz. The filter is assembled on a 75x19 mm printed circuit board. The kit includes 2 reference quartz (SSB, CW). Squareness coefficient at levels 6 and 60 dB – 1.5; attenuation beyond the passband more than 80 dB; unevenness in the passband no more than 3 dB; 6 dB bandwidth – 2.4 kHz; Rin and Rout. from 200 to 280 Ohm (indicated in the passport). It is possible to produce several CFs for one frequency with a spread of no more than 20 Hz.

Four-crystal quartz filter "Desna". Assembled, configured, without housing (shielded box). Quartz filter at a frequency of 8.865 MHz, Kp. 2.1; bandwidth 2.4 kHz. The kit includes 2 reference quartz (SSB, CW). The filter is assembled on a 35x19 mm printed circuit board. It is possible to produce several CFs for one frequency with a spread of no more than 20 Hz.

Four-crystal (cleanup) quartz filter “Desna”. Assembled, configured, without housing (shielded box). Manufactured at the frequency of the main HF. Possibility of changing the band from 2.7 to 0.7 kHz. The filter is made on a 30x15 mm printed circuit board. The kit includes 3 varicaps KV-127.

Radio amateur set "Desna"

The Desna set is intended for the manufacture of quartz filters: an eight-crystal main selection and a four-crystal eraser with a variable bandwidth (0.7 - 2.7 kHz) for devices with one frequency conversion used in amateur radio communications.

For the manufacture of quartz ladder filters, identical quartz resonators from PAL/SECAM television set-top boxes are used. As measurements have shown, these quartzes have a high quality factor, the resonant gap is about 12 - 15 kHz. The manufactured eight-crystal quartz filter from such resonators has the following parameters:

squareness coefficient at levels 6 and 60 dB ~ 1.6;

attenuation beyond the passband more than 80 dB;

unevenness in the passband – 1.5 - 2 dB;

6 dB bandwidth – 2.4  0.15 kHz;

input and output resistance - 20210 Ohm.

The set includes:

selected quartz resonators « NEW» (C = 5 Pf) – 12 pcs.;

quartz resonators of reference oscillators (marked – G) – 2 pcs.

Capacitor KM-12-15pF – 2 pcs. Capacitor KM-91pF – 2 pcs.

Capacitor KM-39pF – 2 pcs. Capacitor KM-110pF – 2 pcs.

Capacitor KM-47pF – 2 pcs. Capacitor KM-120pF – 2 pcs.

Capacitor KM-56pF – 2 pcs. Printed circuit board – 2 pcs.

Varicap KV-127A (B) – 3 pcs.

* Capacitor values are given for quartz resonators only of this type"NEW".

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Conceptual diagrams of CF and PKF:

C1, C7-39pF, C2, C6-12-15pF, C3, C5-47pF, C4-91pF, C8, C11-120pF, C9, C10-110pF. C1, C3-56pF, C2-91pF.

Filters are implemented on printed circuit boards. One of the terminals (marked *) of the outer resonators, and in the PKF and all four, cannot be cut off on the boards; they will be the input/output of the KF and PKF, as well as for connecting additional capacitors in the PKF.

Quartz filter 10 m 2.4 d. Quartz filters "Desna" - Document. Simple Intermediate Frequency Crystal Filter

Simple quartz filter intermediate frequency

Connection diagram for a four-crystal cleanup filter