SU1081564A1 - Phase shift calibrator - Google Patents

Description

The invention relates to electrical measurements and can be used when installing calibrated phase shifts in the frequency range of 1-600 Mfu. A phase shifter is known that contains a controlled oscillator with frequency and phase tuning devices, the output of which is connected to two identical scaling circuits, with the bit inputs of the first scaling circuit connected to the output of the code recorder and the outputs are connected to two valve groups one input first of which is connected to the input of the entire device, and the output through the analog memory device is connected to one input of the second group of gates, the output of which is connected to a low-pass filter. The gauge is a small frequency band due to the difficulty in building a tunable frequency multiplier. For example, to obtain a phase shift with a resolution of 1 ° for frequencies igy - 1 MHz, it is necessary to multiply it 360 times, therefore, a frequency of 360 MHz should be supplied to the scaling circuits, and if it is 100 MHz, then this frequency should be 36 GHz. The closest technical solution to the invention is a phase shift calibrator that contains a generator, scaling circuits, a phase-shifting unit, mixers and filters, and the mixers with filters connected between the outputs of the two-channel frequency converter and the phase discriminator are connected to at the inputs of which the common generator is turned on, and the outputs and inputs of the bits of one of the scaling circuits are connected respectively to the settable phase shift code generator and the digital black indicator Without the keys and the memory register, while the control inputs of the imaging unit and whose digital indicator is connected to the output of the second conversion circuit p2l. A disadvantage of the known phase shift calibrator is that the phase setting accuracy is low, which is determined by: the error in converting the phase angle of a self-oscillating stroboscopic converter that can reach 2.5, the error in the second frequency conversion, the error in the filters and the amplitude skew of the input signals. Moreover, all these errors are additive in nature and despite the fact that the system is covered by feedback, they are algebraically summed, and the total error of the phase can reach 3–4. The purpose of the invention is to improve the accuracy of the phase shift setting. The goal is achieved by the fact that the phase shift calibrator containing the first phase-shifting unit, the first and second mixers, the master oscillator, the recalculators, the settable phase-shift code generator that is connected to the bit inputs of the first recaller, the digital counting unit connected to the outputs bits of the same recalculation device through the key block and the memory register, and the control inputs of the shaper of the code of the installed phase shifts and the key block are connected to the first the output of the second recounting device, a high-frequency generator, first and second controlled dividers, third and fourth mixers, a local oscillator and a constant voltage calibrator, the first and second strobe pulse shaping unit, the second phase-shifting node, the frequency multiplier, and amplifiers were introduced; the output of the high-frequency generator is connected via the first and second controlled dividers to the input of the first phase-shifting unit, the output of which is connected to the second output of the calibrator and to the first inputs of the third and fourth mixes It, for the DC voltage calibrator code, is connected to the second inputs of the first and fourth mixers respectively, the local oscillator is connected via the first strobe pulse shaping unit to the third input of the first mixer and the second input of the second mixer, and through the second strobe pulse shaping unit to the second input the third mixer and the third input of the fourth mixer, the output of the first mixer through the first amplifier connected to the first control divider, the output of the second mixer through the second amplifier Yuchen to the second phase shifting node, the output of the third mixer through the amplifier connected to the first phase shifting node, the output of the fourth mixer through the fourth amplifier connected to the second controlled divider, the output of the setting generator through the second phase shifting node and the multiplier connected to the inputs of the first and second shifters , the first and second outputs of which are connected respectively to the first and second inputs of the strobe-pulse shaping units, and the first inputs of the first and second mixers are connected to the code the first controlled divider and the first output of the calibrator. On; FIG. 1 is a block diagram of a phase shift calibrator; in fig. 2 are timing diagrams illustrating the essence of his work} in FIG. 3 is a block diagram of a strobe pulse formation unit. . Phase shift calibrator containing high frequency generator 1, is connected to one of the inputs of the first control of splitter 2, the output of which is connected directly to the first output of the entire device, to the first inputs of the first 3 and second 4 mixers and through the second controlled divider 5J first phase-shifting unit 6 - to the second output of the entire device and to the first inputs of the third 7 and fourth 8 mixers, constant voltage calibrator 9 two outputs of which are connected respectively to the second inputs of the first 3 and fourth 8 mixers g the heterodyne frequency generator 10 is connected through the first strobe pulse forming unit 11 to the third input of the first mixer 3 and the second input of the second mixer 4, and through the second strobe pulse forming unit 12 to the second input of the third mixer 7 and to the third input of the fourth mixer 8, the shaper 13 of the installation code, phase shifts connected to the bit inputs of the first scaler 14, a digital sample node 15 connected to the outputs of the amps of the first scaler 14 through a block of 16 keys and a memory register 17, the control inputs of the driver .13 and the key block 16 are connected to the first output of the second scaler 18, and the first and second outputs of the scalers 14 and 18 are connected respectively to the first and second inputs of the strobe pulses 11 and 12, which drive the generator 19 connected through the second phase-shifting node 20, a frequency multiplier 21 to the inputs of the first 18 and second 14 of the sweepers. In addition, the output of the first mixer 3 through the first amplifier 22 is connected to the first controlled divider 2, connect the output of the second mixer 4 through the second amplifier 23 to the second phase-shifting unit 20, the output of the third mixer 3 through the third amplifier 24 is connected to the first phase-shifting node 6, vGGkod the fourth mixer 8 through the fourth amplifier 25 is connected to the second controlled divider. The phase shift calibrator operates as follows. If the high-frequency signal Ugq is summed with a predetermined low fixed frequency at the time of gating with a certain frequency i st peHepyropa strobe pulses and simultaneously changing the phase and amplitude of the predetermined voltage at a low fixed frequency, then the instant when the instantaneous values of the high-frequency signal samples and the specified the stresses will be equal (Fig. 2a). Moreover, the frequency of the local oscillator must be strictly related to the frequency; of a given voltage Ij and the frequency of the input signal as follows, the frequency of a given voltage, for example 10 kHz / frequency of the input signal, for example 1-100 MHz; the frequency of the strobe pulses of the oscillator range 08-2 MHz; the number of periods of the input RF signal, which fits into the local oscillator frequency; 1, 2, 3 ... If you select a strobe pulse that coincides with the K pulse of the multiplied time TOTS of a given voltage (Fig. 2e, g), and strobe the RF signal (Fig. 2d), then change the RF phase signal relative to a given one, it is possible to achieve coincidence of this strobe pulse with a K pulse of a multiplied frequency of a given voltage and zero crossing of the RF signal (Fig. 2 h) By setting a certain phase at a low frequency, it can be achieved by setting it at a high frequency. From FIG. 2a, it can be seen that if the reference voltage and the RF signal voltage coincide in phase, i.e. When the gating signal has zero transitions and a predetermined voltage coincides. At the time of gating, then to determine the maximum of the high frequency signal, the gate signal needs to be shifted relative to the gate signal passing through zero to 1/4 of the number of strobe pulses. i.e. on It / 2. (Fig. 2c). If you then perform gating in a single point and compare the amplitude value of the RF signal Opt and the amplitude value of the specified voltage U1, then, by changing the amplitude DBH, their full compensation can be achieved. As an amplitude voltage one can take a constant voltage, which can be normalized both at the input and at the output of the phase shifter. FIG. 2a, it is shown that, at point O, the moments of zero crossing of the specified RF signal and the gating pulse coincide. Moreover, the strobe: Nj.fp О, which passes at the moment of crossing the zero of the specified and RF signals (Fig. 2b, d) and also the gate pulse shifted by, are formed once in the period of the specified voltage so that the strobe will occur one point. The phase shift calibrator works as follows. The high-frequency sinusoidal signal taken from generator 1 is supplied through divider 2 to mixers 3 and 4. Setting the required phase shift value is done by writing the corresponding parallel code produced by shaper 13 of the code to the bits of the recalculation device 14 at the moment of filling the best device 18 The digital indication of the settable phase shift is performed by sweeping the readout node 15 with the memory register 17, to which the instantaneous code value is written through the key block 16, Equipped with 1 counting device 14 at the moment of filling the counting device 18. The resolution of the settable phase shifts is determined by the multiplication factor of the frequency of the signal multiplier 21 taken from generator 1. When you select a multiplication factor of 360 and a division factor of the counting devices of 360, the resolution is set to shifts will be 1. Pulse The beginning of the period of a given voltage and shifted relative to this beginning by a quarter of the period from the recalculation device arrive at block 11. Block 11 generates a strobe pulse at the beginning of the period of the specified C-voltage, which gates in the mixer 4 the high-frequency signal C 01 ,. If, when the RF signal passes through zero, the beginning of the period of the specified voltage, as well as the moment of the strobe pulses occur, do not coincide, the uncompensation voltage is applied, which is fed through the amplifier 23 to the node 20, the node 20 changes the phase of the specified voltage 0 to those then, while the strobe pulse, being formed in A by block 11 at the time of the beginning of the period of a given voltage U, does not coincide with the crossing of the RF signal through zero and ds. Then, at the output of the mixer 4, the noncompensation voltage will be min 4 = 1 O {. At the same time, the strobe pulse, shifted by a quarter of the period relative to the zero (strobe pulse), is amplified in the mixer 3, the amplitude value of the high-frequency sinusoidal voltage and the normalized constant voltage removed from the calibrator 9. And if they are not equal, the voltage amplified by the amplifier 22 is fed to a controllable divider. 2, which changes the amplitude of the high frequency voltage to full compensation. Thus, the circuit automatically assigns the phase of the specified voltage to the phase of the RF signal, and also sets the amplitude of the RF signal equal to the normalized DC voltage taken from the calibrator 9, From the recalculation device 14, the pulses of the beginning of the specified voltage period and pulses shifted relative to of this beginning by a quarter of the period, and these pulses are shifted relative to the pulses, measured by the scaler 18, by an angle specified with the code for setting the phase shift, and fed to block 12. The block 12 forms It emits a strobe pulse at the beginning of a predetermined voltage period, which gates the voltage in the mixer 7 coming from node 6. The uncompensation voltage is amplified by the injector 24 and goes to node 6 which changes the phase of the RF signal at the CC until the strobe the impulse that passes at the beginning of the Period of a given voltage does not coincide with the moment of zero crossing of the RF signal. At the same time, the strobe pulse shifted by a quarter of the period relative to the zero strobe pulse generated in block 12, the amplitude value of the high-frequency sinusoidal voltage and the normalized constant voltage removed from the calibrator 9 is amplified in the mixer 8. on the controlled divider 5, changing its transmission coefficient until the amplitude value of the RF signal is equal to the specified constant voltage taken from the calibrator 9. FIG. Figure 3 shows a block diagram of a strobe pulse shaping unit at the beginning of a predetermined voltage period, as well as a strobe pulse shifted relative to this beginning by a quarter period. The unit works in the following way. In the conversion devices 18 and 14 Gfig. 1) pulses of 1 48 begin of a period of a given voltage and a pulse shifted relative to this beginning by a quarter of the period of the same frequency are separated. The pulses arrive at two RiS. -Switches 26 and 27. With the arrival of these pulses at the frequency of a predetermined voltage, the triggers are reset. The pulse from oscillator 10 of the local oscillator frequency passes through the elements 28 and 29 and through the delay lines 30 and 31 sets the triggers to the initial state. Strobe pulses are formed in driver 32 and 33. The block allows generating strobe pulses that coincide with the beginning of the period of a given voltage with the pulses shifted relative to this beginning by a quarter of the period. Thus, the phase relations established at a fixed low frequency are automatically transferred to a high frequency with high accuracy by the compensation circuit of the automatic search for zero crossing of high frequency signals at the moments of gating. Moreover, the required level of differences in high-frequency voltages of the phase shift calibrator is normalized by the constant voltage taken from the constant voltage calibrator in a wide range. The device allows you to automatically transfer these levels to a high frequency. Perfect: Phase installation in the proposed invention can-TfiraT & to tenths of a degree (0.80, 5; whereas, in the well-known set, it can reach 3-4, except for Tofo, this device allows the calibrator to set the specified value of the signal level difference with a high accuracy of 0.8–0, 6% and keep it valid when the load changes.

Ф (/г./

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From the first release of recalculation schemes

From the release of scaling scheme

3

Claims (1)

(56) A PHASE SHIFT CALIBRATOR, comprising a first phase-shifting unit, a first and second mixer, a master oscillator, recounters, a settable phase shift code generator connected to the discharge inputs of the first recounting device, a digital reading unit connected to the discharge outputs of the same recounting device through a key block and a memory register, wherein the control inputs of the code generator of the set phase shifts and the key block are connected to the first output of the second conversion device, which means that, in order to increase the accuracy of the installation of phase shifts, a high-frequency generator, the first and second controlled dividers, the third and fourth mixers, a local oscillator and a constant voltage calibrator, the first 'and second block of the formation of strobe pulses, the second phase shifter are introduced into it node, frequency multiplier and amplifiers, while the output of the high-frequency generator is connected through the first and second controlled dividers to the input of the first phase-shifting node, the output of which is connected to the second output of the calibrator and the first to the inputs of the third and fourth mixers, two outputs of the constant-voltage calibrator are connected to the second inputs of the first and fourth mixers, local oscillator, and keys, respectively, through the first block of formation of strobe pulses to the third input of the First mixer and the second input. the second mixer, and through the second strobe shaping unit to the second input of the third mixer and the third input of the fourth mixer, the output of the first mixer through the first amplifier connected to the first controllable divider, the output of the second mixer through the second amplifier connected to the second phase-shifting unit, the output of the third the mixer through the third amplifier is connected to the first phase-shifting unit, the output of the fourth mixer through the fourth amplifier is connected to the second controlled divider, the output of the master gene Ator through the second phase-shifting unit and a frequency multiplier coupled to the inputs of said first and second scaler mouth? devices whose first and second outputs are connected respectively to the first and second inputs of the strobe pulse generating units, and the first inputs of the first and second mixers are connected to the output of the first controllable divider and the first output of the calibrator.