DK152638B - AUTOMATIC ACOUSTIC TESTING SYSTEM - Google Patents

Description

- 1 -

DK 152658 B

The invention relates to an automatic system for testing acoustic appliances according to. the preamble to claim 1.

Such a test system is already known from US Patent No. 39 22 506. The automatic test system shown in the present invention has an oscillator for generating a selected signal frequency, after which an output amplifier is coupled to record the selected signal frequency and supply a drive signal. coupled to the drive amplifier, coupling systems for connecting the drive signal to a test acoustic apparatus, with recording and digitally processing system 10 for recording an output of the test circuit and for digital processing of the output for supplying a sound pressure indicator system, and with a distortion analysis circuit for recording an output signal from the recording and digitally processing plant for further processing of the output signal for supplying an additional indicator system for harmonic distortion values.

However, the known acoustic testing system - especially in assembly line production - has the disadvantage that due to fatigue on the part of the operating staff, malfunctioning can occur and in addition the known testing system does not provide a lasting protocol of the found raw values which is very useful as documentation. for that device. In addition, the known testing system is not sufficiently flexible.

From the journal 'Electronic', 1974, Booklet 10, pages 379 - 385, it is well known that measurement techniques can be automated by automatic calculators. In particular, reference should be made to Table 1, page 381, where the column "16 Bit" also refers to "automatic testing systems," and to page 383, where the introductory section of the second line mentions the use of modular microcomputers, for example also in the field of measurement technology. From this further publication, an average person skilled in the art may have the idea of equipping the measurement method known in U.S. Patent 39,22,506 or its associated measurement system with a digital calculator so as to further improve automation.

However, from this further publication, any reference to details of how the known system can be connected is lacking.

DK 152638 B

a digital calculator to actually achieve the desired characteristics.

The object of the invention lies in the design of the circuit known from US Patent 3,922,506 so that no operating errors can occur, for example. due to fatigue on the part of the service staff, 5 that a durable protocol is provided of the measured values, which the necessary circuits need to be simplified as much as possible depending on the options.

This task is solved according to the invention by the properties specified in the characterizing part of the main claim, i.e. by means of a digital computer connected via an interface to the oscillator means, the amplifier, the recording and digital processing plant and the distortion analyzer circuit for the oscillator. , the amplifier, the recording and digitally operating systems and the distortion analyzer circuit to record digital signals or digitized analog signals and control the operation, and to enable via the indicator systems an indication or reproduction of the analog or digital signals where the digital computer consists of a central CPU (CPU), which communicates with a volatile data storage (RAM) and a non-volatile program memory (ROM) and can control via operation via a controllable switch and that non-volatile program memory (ROM) is occurred so that the frequency of the acoustic drive signal changes step by step and that for reproduction the device enables a corresponding marking.

The test system thus provided solves the task of the invention. Since the frequency of the acoustic drive signal under control 25 from the fixed program is automatically changed stepwise, the amplitude of the drive signal is kept at a desired size and the signal emitted from the study object is simultaneously recorded and digitized and the digitized signal is then digitally reproduced and a signal is produced from this signal. hard copy in a digital or graphical format, avoids operating errors to the greatest extent possible, e.g. as a result of tired operating staff, and in addition, the very useful documentation of the test results for operation and use is also provided. In addition, the use of computer control provides an extremely high degree of flexibility in the direction of feasible investigative procedures.

35

DK 152638B

- 3 - X the dependent requirements, useful further designs of the test system according to the main requirement are stated.

The invention is further explained in the following by means of an exemplary embodiment shown in the drawing, which also comprises a computer control which uses a fixed program memory for the controlled examination of acoustic devices, where the study objects are supplied with a sound produced by generator systems. and the output signals from the survey objects are processed by circuitry, which is controlled by a computer, whereby the output signal from the 10 survey objects can be made in the form of amplitude and in the form of distortion content, both as digital read-out and as graphical representation of the measured values. In the drawing: FIG. 1 is a perspective view from outside of a design of the overall arrangement of the testing system according to the invention; FIG. 2 is a block diagram of automatic acoustic testing system; FIG. 3 is a schematic diagram of the digitally controlled amplifier with constant amplitude; FIG. 4 is a block diagram of a computer-controlled printing press; FIG. 5 shows a printed strip from the automatic acoustic test system with data in digital form; and FIG. 6 is a printed strip similar to that of FIG. 5 but with data in graphical form.

FIG. 1 shows an electronic module 10 which contains the electronic circuit for the automatic acoustic testing system and a sound pressure chamber 12 in which the apparatus to be tested is placed ·

The electronic module 10 has control pushbuttons 14, by means of which operation; the staff can control the measurement and production of readout strips. A visible indication of the acoustic driving and measuring processes is obtained by multiple digital devices 16. In the electronic module is also placed a pressure unit 18, which is controlled by the operating pernola by means of a push button 14 under the control of the computer.

The sound pressure chamber 12 is designed in the manner described in U.S. Patent No. 3,923,359 and is connected to the electronic module by means of

DK 152638 B

- 4 - of electric cables 20.

FIG. 2 shows an oscillator 22 of known design described in U.S. Pat. No. 3,922,506 and whose frequency is determined by a frequency selector switch 24 which is controlled by the computer referred to below in more detail. The frequency selector switch 24 can be manufactured using of known reed switches, relays, FETs, bipolar transistors or C-MOS devices.

The signal for the oscillator 22 has a constant amplitude and is attenuated by a attenuation switch 28, which may be designed in a similar manner to the frequency selector switch 24, and which is also controlled by the computer 26. It attenuates:: *. sigiel from attenuation switch area. 28 is then further attenuated as needed by a correction attenuator 30, which may be configured in the same manner as the frequency selector switch 24. The attenuator 30 is also controlled by the computer 26.

The attenuator switch 28 and the attenuator attenuator 30 together provide the required signal level in such a way that the desired sound pressure level is applied to a test device 32 disposed in the sound pressure chamber 12, the loudspeaker 34 of which is gripped by a prior art output sheet 36 of known type.

The tested apparatus 32, e.g. may be a hearing aid, coupled with the microphone 38 through a coupling device 40 which may be configured in the manner described in U.S. Patent Application 550,196 of February 18, 1975.

The output of the microphone 38 is connected to an amplifier-controlled amplifier 42, which is controlled by the computer 26, and which is of a known kind, composed of three cascade amplifiers, each having an amplification of 0 or 40, 0 or 20 and 0. or 10 dB, or as a binary sequence. Switches which control the gain of the cascade amplifiers may be of the same general design as those used in the frequency selector switch 24, and such switches are controlled via the computer 26.

The signal from the amplifier controlled amplifier 42 is transmitted to a detector 44 of known type which produces a DC voltage level which is compared to voltage references in a comparison circuit 46 which is also of known design. The effect of the DC voltage level of the detector 44 and the comparator stage 46 provides information

DK 152638B

- 5 - to the computer 26, which enables the correct gain setting of the gain-controlled amplifier 42. The binary form of the gain signal provides the necessary information for the digitization process (MSD-most significant digit). The computer 26 generally comprises a central processing unit (CPU) 62, an interface circuit 64, a fixed-line program memory 66 and a volatile memory 68. The central processing unit 62 is the main control element of the computer 26 and is of known design. It receives its instructions through the boundary layer circuit 64 of known design and the firmly occurring program memory 66, which e.g. consists of "read only memories" (ROM's). The central foc processing unit 62 is also connected to the volatile memory 68, e.g. consists of "random access .memories" (RAM's). The computer 26 receives its control signals through the control switches 14 on the front plate of the device shown in FIG. 1 electronic module 10.

The digital information used in the control and measurement of the tested apparatus 32 is stored in the volatile memory 68. This information is used to form the basis for the digital readout of information by the multiple digital device 16 consisting of LEDs and the printing plant. 18, which is described in more detail below.

FIG. 3 shows more detailed constant amplitude amplifier 52, where the signal from the gain regulated amplifier 42 is introduced into the amplifier through a resistor 70. This signal has, as discussed above, the same form as the signal from the tested device and further varies in amplitude over a limited range of 10 - 1. The lowest 25 level of the signal represents a digitized number of 0 or - in binary form - 00000000. When a signal of this level is applied to the constant amplitude of the signal circuit, it is simultaneously measured by the unit digitizer 50, which finds this 0 level. The computer 26 is now driven to operate the switch 72, which is thereby connected either to the output of the operating amplifier 74 or to the north, depending on the binary links representing the unit digitized level of the signal voltage and providing feedback. If desired, an automatic digitization circuit such as that described in US Patent 3,922,506 may be used to control the switches 72. If the most significant bit (MSB) is a binary 1, it will be operated by the operational amplifier 74

DK 152638 B

- 6 - the nearest switch 72 is connected to the output of the amplifier. The switches 72 may be electronic switches of a kind similar to those used in the frequency selector switch 24, and the operating amplifier 74 is of known design. Resistance network 76 consists of a known binary ladder · 5 It will be readily seen that the smallest signal of a binary value of 0 is one tenth of the maximum amplitude of the signal of the gain controlled amplifier 42. When a signal of this amplitude is available, all the switches 72 are connected to ground, and the gain of the amplifier 74 is set by the resistance ratio of the resistor 78 to the resistor 70. X this state, the constant amplitude amplifier 52 has its maximum gain. The maximum signal from the gain-regulated amplifier 42 is assigned a binary number - 11111111 - at which all the switches 72 are connected to the output of the operating amplifier 74. In this state, the constant amplitude amplifier 52 has inaxial gain. The signal from the constant amplitude amplifier 52 is maintained at a constant amplitude by means of the switches 72 which are set after the previous signal information from the unit digitizer 50.

FIG. 4 shows the details of the printing plant 18, wherein a multi-slot 20 printing plant 80, e.g. eighteen slots of known design comprise a plurality of hammer guide solenoids 82 which serve to print the characters of a type drum 84 driven continuously by a motor 86 on a paper strip 88 engaged with the drum under the control of a paper feed mechanism 90. Usually, black characters are printed on strip 25 88, but red characters can also be printed on paper 88 by means of a red-print solenoid 92.

The DC signal from the detector 44 is smoothed in a filter 48 of a known kind and is then fed to a unit digitizer 50 controlled by the computer 26. The effect of the unit digitizer 50 and other 30 elements of the amplitude digitization circuit comprising the gain controlled amplifier 42, the detector 44, comparator net 46 and filter 48 are designed in a similar manner as described in U.S. Pat. No. 3,922,506 and similarly operate with the improvements provided by digital computer 26. These improvements are: digitization process, - 7 -

DK 152638 B

greater flexibility in the use of the digital information derived from the digitization process, and greater processing speed.

The signal from the gain-controlled amplifier 42 bears a level held within certain limits enclosing a 10-1 voltage range (20 dB). This signal is of the same form as that received from the tested device 32. It is now sent to the constant amplitude amplifier 52 / which is controlled by the computer 26 / and which is described in more detail below. The signal amplitude amplifier 52 delivered by constant amplitude 52 has constant amplitude and is filtered into a filter 54 of a known kind. The filter 54 is controlled by the frequency selector switch 56 under the control of the computer 26 and is designed in a similar manner to the frequency selector switch pure 24.

The signal emitted from the filter 54 is detected in a detector 58 of a known kind, and the resulting DC voltage level is applied to a percent digitization circuit 60, similar to the digitizer 50, controlled by the computer 26. The constant amplitude researcher 52, the filter 54, the frequency selector switch 56, the detector 58, and the percentage digitization circuit 60 together with the computer 26 form a distortion analysis circuit.

The computer 26 is informed of the characters available for printing at all times by signals received from clock and reset pick-up coils 94 through a known electronic switch 95. The computer 26 controls the paper feed mechanism 90, the motor 86, and the red print. solenoid 92 through a 4 bit lock 96 and boundary layer amplifiers 98, all of which are of known design.

The signals for the hammer control solenoids are serially input into a known shooting register 100 by means of a fit bit lock 102 of a similar design as the 4 bit lock 96, under the control of the computer 26. The shooting register 100 can be caused to drive all the hammer control solenoids 82 in parallel 30 by means of a parallel trigger pulse at the desired moment, thereby pressing the appropriate characters on the paper 88.

FIG. 5 shows a paper strip 88 printed with digital data information. As will be seen, the information shown constitutes a permanent record of the frequency and amplitude of the test signal and the sound pressure level and the percentage harmonic distortion of the test signal.

DK 152638 B

- 8 - the signal from the tested device 32.

FIG. 6 shows a paper strip 88 on which is printed information in graphical form, which provides an easily readable representation of the frequency sensitivity of the tested apparatus 32.

5

Claims (11)

An automatic acoustic testing system with an oscillator (22) for generating a selected signal frequency / after which an output amplifier (30, 36) is coupled to record the selected signal frequency and supply a drive signal coupled to the drive amplifier ( 12, 34, 40) for connecting the drive signal to a test acoustic apparatus (32), with recording and digitally processing systems (38, 42, 44, 46, 48, 50, 26) for recording an output of the examination of certain systems (32) and for digital processing of the output for supplying an indicator system (16, 18) for 10 sound pressure values, and with a distortion analysis circuit (52 - 60) for receiving an output signal from the recording and digital processing system for further processing of the output signal for supplying an additional indicator system for harmonic distortion values, characterized by a digital computer (26) connected to an oscillator via an interface (64) The llator (24, 22), the amplifier (28, 30, 36), the recording and digital processing system (38, 42 - 50) and the distortion analyzer circuit (52 - 60), for the oscillator (22), the amplifier (30, 36) , recording and digitally operating systems (38, 42 - 50) and the distortion analyzer circuit (52 - 60) to record digital signals or digitized analog signals and control operation and to enable an indication or reproduction via the indicator systems (16, 18) of the analog or digital signals, wherein the digital computer consists of a central computing unit (CPU 62), which communicates with a volatile data store (RAM, 68) and a non-volatile program store 25 (ROM, 66) and via a controllable the switch (14) can be controlled during operation, and the non-volatile program memory (ROM, 66) is arranged so that the frequency of the acoustic drive signal is changed step by step and that the reproducing device allows a corresponding marking. Test system according to claim 1, characterized in that the oscillator (22) and the amplifier (36) are connected to each other via an attenuation link (28, 30), the attenuation of which can be controlled from the digital computer (26) via an interface (64). . Test system according to claim 1 or 2, characterized in that the recording and digitally processing systems (38, 42, 44, 46, 48, 50, 26) comprise a gain controlled amplifier (42), a detector (44), a comparator (46), a filter (48) and a unit digitizer (50). Test system according to claim 1, characterized in that the distortion analysis circuit (52 - 60) comprises a constant amplitude amplifier (52), a filter (54), frequency selector means (56), a detector (58) and a percentage digitization circuit (60). 5. Testing system according to any one of the preceding claims, k e n - 10. e t e g n ?. v. id that the readout means (16, 18) comprises means for producing a visible digital representation. Testing system according to any one of claims 1 to 4, characterized in that the read-out means (16, 18) comprise printing means (18) for delivering an impression with the acoustic characteristic of the device (32) determined in digital format. Testing system according to any one of the preceding claims, characterized by a constant-amplitude amplifier circuit (52) having an operational amplifier (Fig. 3) with an input for receiving an input signal (from 42), and feedback means (78, 72, RF ) between an output of the operational amplifier and its input forming by means of control devices (72, 26) interchangeable root resistor couplings, wherein the resistance couplings (RF, ¼RF) of the control devices are either connected to ground or to the output of the operational amplifier. Test system according to claim 7, characterized in that the switchable resistance couplings (78, 72) have electronic switches (72). Testing system according to claim 7, characterized in that the control devices (26) comprise an automatic digitizing circuit, in particular comprising a computer (26). Testing system according to any one of the preceding claims, characterized by an electronically controlled printing plant (30, Fig. 4) for printing up to 40 slots with printing characters on a paper grinder, with printing and paper supply devices (84, 86, 90) for feeding the paper (88) and engaging the printing devices (82, 84, 86), with guide devices (96, 98) for controlling the paper drive (90) and the printing device. - 11 - DK 152638 B (82, 84/86) and a digital computer (26) cursed with the control devices (96, 98) for supplying control signals to the control devices. 5