SU661421A1 - Arrangement for tolerance checking of electroacoustic transducer amplitude-frequency characteristics - Google Patents

Claims (2)

The invention relates to a technique for measuring amplitude-frequency characteristics (AFC), and can be used to measure the frequency response of electroacoustic transducers, telephony devices, sound recording equipment, and the low-frequency path of broadcasting and television equipment.  A device for monitoring amplitude-frequency characteristics, which reproduces the amplitude-frequency characteristic on the screen of a cathode-ray tube (CRT) 1, is known.  The disadvantage of this device is the low measurement accuracy of the amplitude-frequency characteristic of the scale located in front of the CRT screen.  Also known is the frequency response meter, which contains a logarithmic DC amplifier of vertical deflection, frequency to voltage converter, plug-in units for setting operating frequency ranges, a DC amplifier of horizontal deflection, a cathode tube with a deflection system, the coils of vertical deflection of which are connected to a constant DC amplifier vertical current deviation, and the horizontal deviation coils are connected to the output of the horizontal current amplifier Oneni, two threshold circuits, whose inputs are connected to the horizontal deflection UTP outputs, are connected in series a static trigger, a key, a control voltage generator, and a sweeping frequency generator with an electronic frequency tuning element, the outputs of the threshold circuits are connected to the corresponding inputs of a statistical trigger, and the input frequency-to-voltage converters with the output of the oscillating frequency generator.  The lack of meter - low measurement performance when monitoring the frequency response of products in their mass production.  The aim of the invention is to reduce the time control of the amplitude-frequency characteristics.  The goal is achieved by the fact that the device for tolerance control of amplitude-frequency characteristics of electroacoustic transducers, containing the first linear amplifier, the input of which is connected to the input terminal, avon1GodeTo gb dkl1S) to the INPUT. In a logarithmic amplifier, the second linear amplifier has a control voltage generator, the output of which is connected to the control input of the oscillating frequency generator, and its input is connected via a switch to the static trigger output of which control inputs are connected to the outputs of the threshold elements, and the inputs of the latter are connected between and with the output of the frequency converter into the Zhenyo nagr, entering the Thorbg CG with the output of the frequency band yctaHOBkM, and its control input is connected to the swing of the oscillator frequencies, additionally introduced a measuring microphone, / emitter, four yards with a reference characteristic, a second logarithmic amplifier, an algebraic block, an index of amplitude-frequency characteristics indices at the center frequency range, a block com,. ; roll on the upper tolerance, control unit on the lower tolerance, the block specifying the tolerance in the first section of the amplitude-frequency characteristic, the block specifying the tolerance on the second part. ke frequency response, tolerance setting unit on the third frequency response section, analysis unit of the first frequency response section, analysis unit of the second frequency response section, analysis unit of the third frequency response section, display activation unit1 on the first the section, the turn on display of operation on the second section, the turn on display of operation on the third section and the display panel, with the output of the oscillating oscillator you are connected to the input sounder, akustileski associated with the measurement microphone, the membrane of which is acoustically coupled to the center of the membrane-controlled converter; The microphone output of the measuring tube 63tro is connected to the second linear amplifier, quadrupole with the reference characteristic and the second logarithmic amplifier is connected to one of the algebraic addition unit inputs, the other input of which is connected to the output of the first logarithmic amplifier, the first output of the adder unit is connected to the input of the amplitude-frequency characteristic display unit on the middle frequency, the second output - with the inputs of the control units on the pivotal tolerance and PB lower allowed To the deviation, the control inputs of which are connected to ss) to the corresponding outputs of the predgus task blocks on the first, second, third sections of the amplitude-frequency xapaRteplcfWKH, and the outputs of the blocks control the upper tolerance 661421 and the lower tolerance on the tolerance is connected to the corresponding indicator inputs. "More than normal," less than the norm of the display panel, while the inputs of the analysis units on the first, second, third sections of the amplitude-frequency characteristic are connected to the output of the frequency conversion unit for example voltage, and the output of the first portion of the analysis block frequency response: Soedyyen the first input unit incorporating the display on the first section and pervgm input unit specifying the tolerance on the first portion of the amplitude-frequency characteristics; the output of the second section analysis block is connected to the first input of the work indication on the second section, the second input of the operation indication on the first section, the second input of the tolerance setting on the first frequency response section and the first input of the tolerance on the second section, amplitude-frequency characteristic, and the output of the analysis unit of the third section of the amplitude-frequency characteristic is connected to the input of the work indication enablement unit on the third section, the second input of the unit includes The display is working on the second section, the second input of the task setting tolerance: a on the second section of the amplitude and frequency response, and the output of the analysis unit of the third section of the amplitude-frequency characteristic is connected to the input of the block, turning on the operation indication on the third section, the second input the unit for switching on the indication of operation in the second section, the second input of the block for setting the tolerance on the second section of the amplitude-frequency characteristic and the first input of the block for setting the tolerance on the third section of the amplitude-frequency characteristic, n By this, the outputs of the switching-on indication units on the first, second, and third sections are connected to the corresponding indicators of the indicator panel.  FIG.  Figures 1a and 2 show the structural electrical circuit of the device.  The diagram shows the oscillating frequency oscillator (GCCH) 1, linear amplifier 2, sound emitter 3, measuring microphone 4, quadrupole 5 with a reference amplitude-frequency characteristic, logarithmic amplifier b, test electroacoustic converter 7, linear amplifier 8, logarithmic amplifier 9, generator amplifier voltage 10, frequency converter to voltage 11, plug-in units for setting operating frequency ranges 12, threshold element 13, key 14, trigger 15, threshold element 16, algebraic block 17, frequency response indication display unit at the middle frequency 18, control unit for upper tolerance 19, control unit for lower tolerance 20, task entry unit at the third frequency response section 21, at the second section 22, at the first section 23, analysis unit of the first 24 the second 25 and third 26 frequency response sections, the operation indication unit on the first section 27, the operation indication inclusion unit in the second section 28, the operation indication inclusion unit in the third section 29, the display panel 30.  The meter works as follows.  An electrical signal with a time-varying frequency from the oscillating frequency generator 1 is fed to the sound; radiator 3.  Sound vibrations affect the electroacoustic transducer under test 7 and the measuring microphone 4.  The sound vibrations are converted by the electroacoustic transducer under test 7 into electrical signals, which contain information about the frequency response of the high frequency circuit 1 - sound emitter 3 - the electroacoustic transducer 7 under test.  The signal from the electroacoustic converter 7 through the amplifier 8 is fed to a logarithmic amplifier 9, the amplitude characteristic of which is described by the equation.  and W, where a is the transition coefficient from the natural logarithm to the logarithm with another. the base; and - DC output voltage of a logarithmic amplifier; and ihd, is the AC voltage applied to the input of the logarithmic amplifier.  At the same time, the sound vibrations of the sound emitter 3 are converted by the measuring microphone 4 and, through the linear amplifier 2, are transmitted to a quadrupole with a reference frequency response 5.  Establishing almost perfect linearity of the frequency response of the channel measuring microphone 4 - linear amplifier 2, form a signal, which at the input of the logarithmic amplifier 6 contains information about the frequency response of the GCh I path to the sound source.  3- quadrupole with reference frequency response 5.  A: Logarithmic amplifiers 6 and 9 have identical amplitude characteristics.  The signals from the logarithmic amplifiers 6 and 9 are fed to the inputs of the block algebraic, addition 17.  In bl. Ocean 17 at each time point, the difference between the signals from the logarithmic amplifiers 6 and 9.  The signal at the output of the algebraic addition block 17 is proportional to the deviation of the amplitude-frequency characteristic, the test microphone relative to the reference amplitude-frequency characteristic.  .  At the same time, the signal from the GKCH I is fed to the frequency converter in the voltage Pi and to the replaceable blocks of the installation of the frequency bands 12.  Between the frequency of the input signal and the voltage at the output of the frequency conversion unit to the voltage 11, there is a relationship "jr Igf / where is the voltage of the direct current at the output of the frequency conversion unit to the voltage; & x - 4acTota input signal.  The voltage from unit 11 simultaneously enters the threshold elements 13, 16 and the units for analyzing the tolerances of the first section 24, the second section 25, and the third section 26.  The threshold element 13 is set so that it triggers at the input voltage corresponding to the lowest frequency of the operating range itself, and the threshold element 16 triggers at a voltage corresponding to the highest frequency of the working range.  The threshold elements Hz and 16, controlling the static trigger 15 and the key 14, automatically switch the control voltage generator from reverse to operating voltage, providing an automatic change of the frequency of the oscillating frequency generator 1.  The tolerance analysis units, the first section 24, the second section 25, the third section 26 are configured in such a way that they operate at input voltages that correspond to certain frequencies fi, fz, 1h. When the block 24 is triggered, the signal from its output goes to the first the input of the work indication enable unit in the first section 27 and to one of the inputs of the tolerance setting unit in the first section.  When block 25 is triggered, the signal from its output goes to the first input of the operation indication enable block in the second section 28, to the second input of the indication enable block in the first section 27, to the second input of the tolerance setting block in the first section 23 and to the first input of the tolerance setting block second plot 22.  When the block 25 is triggered, the signal from its output goes to the input of the operation indication device on the third section 29, to the second input of the operation indication inclusion block on the second section 28, to the second input of the tolerance setting block on the second section 22 and the tolerance setting block on the first section 23 .  When a signal arrives at the first input of the block 27, the indicator is turned on, located in the display panel with the inscription "1st section.  When a signal is simultaneously received at the first and second inputs of block 27, the indicator "1st section goes out, and the indicator" 2nd section turns on, since the first input of block 28 received a signal.  When a signal is simultaneously received at the second input of the unit 28 and at the input of the unit 29, the indicators "2nd section and" 3rd section are turned on.  When a signal arrives at the first input of block 23, the latter connects to blocks 19 and 20 elements determining the response level of blocks 19 and 20 in the first frequency response zone.  When a signal is simultaneously received at the first and second inputs of block 23 and at the first input of block 22, block 23 disconnects from block 29 and 20 elements determining the response level of blocks 19 and 20 in the first segment, and block 22 connects to blocks 19, 20 elements determining the level of operation of the blocks 19 and 20 in the second frequency response area.  When a signal is simultaneously received at the first and second inputs of block 22 and at the input of block 21, block 22 disconnects the electrons from blocks 19 and 20, which determine the response level of blocks 19 and 20 in the second frequency response section, and block 21 connects to blocks 19 and 20 elements that determine the response level of the blocks 19 and 20 in the third frequency response section.  A signal from one output of an algebraic block.  17 enters the frequency response display unit at fftjs 18, which makes it possible to count in decibels the values of the frequency response of the test microphone from the reference characteristic at the center frequency of the operating range.  The signal from the second output of the block is algebraic. skogr of addition 17 enters a pair; ice-connected inputs of the control unit for the upper tolerance 19 and the control unit for the lower tolerance 20.  Block 19 analyzes the incoming signal for voltage. .  When the input signal is less than the trigger threshold of block 19, the day emit a signal to turn on the "normal" indicator.  When the input signal exceeds the threshold, unit 19 turns on the indicator "normal."  Block 20 analyzes the incoming signal by voltage.  When the input signal is greater than the response threshold, block 20 issues a signal to turn on the "normal" indicator.  When the input signal exceeds the threshold, unit 20 turns on the "normal" indicator.  The device provides automatic tolerance control. b and amplitude-frequency characteristics of electroacoustic transducers with high performance The invention A device for tolerance control of amplitude-frequency characteristics of electroacoustic transducers, comprising a first linear amplifier, the input of which is connected to an input terminal, and an output connected to the input of a logarithmic amplifier, second linear amplifier, control voltage generator the output of which is connected to the control input of the oscillating frequency generator, and the input through the switch It is connected with the output of a static trigger, the control inputs of which are connected to the outputs of the threshold elements, and the inputs of the latter are connected to each other and to the output. The unit for converting frequency to voltage, the input of which is connected to the output of the plug-in unit for setting frequency ranges, and its control input is connected to the output of the oscillating frequency generator, characterized in that, in order to reduce time. meni control amplitude characteristics, a measuring microphone, a sound emitter, a quadrupole with a reference characteristic, a second logarithmic amplifier, an algebraic addition unit, an amplitude-frequency characteristics indication unit at the center frequency range, a control unit for the upper tolerance, a control unit for the lower tolerance are entered. to the deviation, the tolerance setting unit in the first amplitude-frequency characteristic section, the tolerance setting unit in the second amplitude-frequency characteristic section, the tolerance setting unit for the third. m section of amplitude-frequency characteristics, unit of analysis of the first section of amplitude-frequency characteristics, unit of analysis of the second section of amplitude-frequency characteristics, unit of analysis of the third section of amplitude-frequency characteristics, unit enable operation display in the first section, unit enable operation display in the second section, a third-stage operation indication switch-on unit and a display panel, the output of the sweeping frequency generator connected to the input of the sound emitter, acoustically connected to the mic a measuring microphone whose membrane is acoustically connected to the center of the membrane of the controlled transducer; With this exit. measuring microphone through serially connected second linear amplifier, quadrupole with reference characteristic and second logarithmic amplifier connected to one of the inputs of the algebraic addition unit, the other input of which is connected to the output of the first logarith. Simultaneously amplify the first output of the addition unit connected to the input of the indication unit of the amplitude-frequency characteristics of the average frequency, and the second output to the outputs of the control units for the upper permissible deviation and the lower tolerance. to the deviation, the control inputs of which are connected to the corresponding outputs of the primary access tolerance block. m, second, third chapters of amplitude-frequency characteristics, and the output, s of control units for the upper tolerance and the lower tolerance are connected to the corresponding inputs of the indicators “normal,“ more than normal, ”less than normal of the display panel, while the inputs of the analysis units in the first, second and third sections of the amplitude-frequency characteristics are connected to the output of the conversion unit, frequencies to voltage, and the output of the analysis unit of the first section of the amplitude-frequency characteristic is connected to the first input of the unit Including the work indication at the first section and the first input of the tolerance setting block at the first section of the amplitude-frequency characteristic, the output of the analysis section of the second section is connected to the first input of the work indication enablement section at the second section, the second input of the work indication enablement section at the first section, second input of the resetting unit the tolerance in the first section of the amplitude-frequency characteristic and the first input of the block specifying the tolerance in the second section of the amplitude-frequency characteristic, and the output of the analysis unit of the third The frequency response is connected with. the input of the operation indication enable unit at the third section, the second input of the operation indication enablement unit at the second section, the second input of the tolerance setting section at the second frequency response amplitude section, and the output of the third frequency response analysis section output unit connected to the operation indication input input unit the third section, the second input of the work indication enable unit at the second section, the second input of the tolerance setting block at the second frequency-amplitude characteristic section and the first input ohm tolerance specifying unit in the third section of the amplitude-frequency characteristic, the output indicating incorporation work-blocks on the first, second, third portions connected to the respective LEDs of indicator panel.  Sources of information taken into account during the examination 1. Device for  removing frequency characteristics of the 4712 type.  Description and application.  Brühl and Kjr, Dani, 1970.   2. USSR author's certificate No. 56270, G 01 R 29/00, 26.05.75. ig. g TSNIIPI Zakaz2442 / 44 Circulation 1089 Subscription Branch of the PPP "Patent, Uzhgorod, ul. Project, 4