簡要描述:XO10A低頻信號(hào)發(fā)生器可產(chǎn)生10赫至1兆赫的訊號(hào),訊號(hào)輸出失真極小。輸出電壓從0分貝到60分貝以每10分貝逐級(jí)衰減,作為信號(hào)源深受生產(chǎn)線,業(yè)余愛好者,維修等多方面的歡迎,其同時(shí)配有隨外信號(hào)同步的端子,使得極小的控制信號(hào)可準(zhǔn)確地控制強(qiáng)訊號(hào)的輸出。
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品牌 | 廈門地坤 |
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XO10A低頻信號(hào)發(fā)生器
1.FEATURES
Reliable circuitry insure high stability and accuracy
Easy operation on vertical type panel assembling
Frequency range from 10Hz to 1MHz selectable in 5 ranges are calibrated with single-scale graduations.
More than 5Vrms at no load and more than 2.8Vrms on 600Ω loading (sine wave). Output level can be adjusted by a 10dB-step, 6 range attenuator and a level adjuster.
Sine wave and square waves is available.
Synchronizing input terminal
2.Specifications
Frequency range:
X1 range: 10Hz-100Hz
X10 range: 100Hz-1KHz
X100range: 1KHz-10KHz
X1K range: 10KHZ-100KHz
X10K range: 100KHz-1MHz
Sine wave characteristics
Output volXO10A: 5V rms or more
Output distortion: 400Hz-20KHz, 0.1% or less
(X100 range for 1KHz)
50Hz-500KHz 0.5% or less
Output Flatness: ±1.5 dB (refer to 1KHz)
Square wave characteristics:
Output volXO10A: 10Vp.p or more
Rise time: 0.25 us or less
Duty ratio: 50%±5% (refer to 1KHz)
External synchronization characteristics
Range±3% of oscillator frequency
Input impedance: 10K approximate
Maxi mun input: 10V rms
Output characteristics:
Impedance: 600Ω±10%
Attenuator: 0dB, -10dB, -20dB, -30dB, -40dB, and -50dB in 6 steps (accuracy +1 dB at 600Ω load)
Power requirement:
Input: AC 110V or 220V, 50/60Hz
Consumption: 5 Watt
Dimension:
142(w)*233(D)*197(H) mm
Weight:3.5Kg
Accessories:
Power cord 1pc
Test clip 1pc
Instruction manual 1pc
1.CIRCUIT DESCRIPTION
1) Summary
When reading the following descriptions, refer to the block diagram(Fig.1) and the schematic diagram.
The sine-wave signal generated by the oscillator is fed through the WAVE FROM selector switch set at the “ ” position to the OUTPUT control, to adjust on any desired volXO10A.
If the WAVE FORM switch is in the “” position, square wave is fed to the OUTPUT control to adjust on any desired volXO10A.
The adjusted signal volXO10A is applied to the output circuit with its impedance converted, and then delivered through an output attenuator to the output terminal.
The attenuator provides selectable attenuations of 0dB through
-50dB in 10dB steps at 600Ω of output impedance.
1) Wien Bridge Oscillator Circuit
The Wien bridge oscillator circuit with resistance elements may be switched over for 5 ranges by the FREQ. RANGE switch, and the variable capacitor controlled by the FREQUENCY dial.
These elements provide means to vary the oscillating frequency continuously over 10 times its frequency on one range, so any desired frequency within the entire frequency range from 10Hz to 1MHz can be set.
The buffer circuit for the oscillator circuit is composed of a 2 sXO10A differential amplifier and an output sXO10A, employing an DC amplifier circuit.
The output volXO10A is fed back with positive polarity through the oscillator elements to form an oscillating circuit; while it is also fed back with negative polarity through the non-linear thermistor to stabilize the amplitude.
XO10A低頻信號(hào)發(fā)生器
2) Square wave shaping circuit
The square wave shaping circuit is a Schmit-trigger circuit in which the sine wave signal from the oscillator circuit is shaped into a square wave. Schmit-trigger circuit and a buffer amplifier providing sufficient rising and falling characteristics
3) Output circuit
The output circuit converts the impedance of oscillating signal from the OUTPUT control and feeds the signal to the output attenuator at a low impedance. SEPP-OCL circuit is employed to provide sufficient low output impedance characteristics over the range from DC to 1MHz
4) Output Attenuator
The 6-positions output attenuator selects attenuations of 0dB to -50dB in 10dB steps. At the 0dB position with the OUTPUT control
turned fully clockwise, the output volXO10A (sine wave at no-load time) is more than 5Vrms.
The output impedance is rated at around 600Ω and the attenuation accuracy is as high as ± 1.0dB at 600Ω load.
1) Power supply
The power supply circuit is powered by AC 110V/220V and delivers DC ± 24V sufficiently stabilized by large capacity smoothing capacitors and a volXO10A stabilizer.
4. PANEL CONTROLS AND THEIR FUNCTIONS
The table below describes the functions of panel controls. Refer to panel diagram on page 4
FRONT PANEL
1. DIAL POINTER
This pointer indicates frequencies on the dial scale
2.DIAL SCALE
This dial is calibrated with graduations of 10-100 to indicate oscillating frequencies
3. FREQUENCY DIAL
This dial adjusts oscillating frequencies. Frequencies can be read by multiplying the reading on the dial scale by magnification of FREQ. RANGE.
4. ATTENUATOR
6-position output attenuator selects attenuations of 0dB to -50dB in 10dB steps.
5. SYNC
External synchronizing signal input terminals for GND for connection of synchronizing signal to the instruments.
6. OUTPUT
Output terminal used for both sine wave and square wave
7. FREQ. RANGE
Oscillating frequency range selector switch which selects the ranges in 5 steps as follows:
X1 10Hz-100Hz
X10 100Hz-1KHz
X100 1KHz-10KHz
X1K 10KHz-100KHz
X10K 100KHz-1MHz
8. WAVE FORM
Output waveform selector switch. When pressed to “’ output signal is sine wave. When pressed to “” the signal is square wave.
9. AMPLITUDE
Amplitude adjuster to continuously vary the amplitude of output volXO10A
10. POWER Switch turns on the power when pressed
11.VOLXO10A SELECTOR 110V/220V selection
12. AC INPUT TERMINAL
13. FUSE SOCKET
14. This lamp ( light emitting diode) lights when POWER switch (10) is ON.
5. OPERATING INSTRUCIONS
1) Start-up
First check that the fuse (13), then connect the supplied AC power cord to your AC outlet. Press the power switch (10) and the pilot lamp (14) will light indicating that the unit is ready for operation. Allow 3 minutes for the unit to warm up so that it is stabilized.
2)Waveform selection
Press the WAVE FORM switch (8) to “~” position to obtain sine waves. Press the switch to the “” position for square waves.
3)Frequency selection
First set the FREQ. RANGE switch (7) to the desired range, then set the frequency dial(3) so that the dial pointer(1) indicates your frequency.
Example: suppose you want to select a frequency of 1.5KHz, thenproceed as follows:
1. Set FREQ. RANGE switch(7) to X 100.
2. by using the frequency dial, set the dial pointer(1) to “15” on the dial scale.
The frequency thus selected is:
15×00=1500(Hz)=1.5( KHz)
4) Adjustment of output volXO10A
The output volXO10A from OUTPUT terminal (6) either sine wave or square wave, can be continuously varied by AMPLITUDE(9) and stepped down by ATTENUATOR (4)
Example: To adjust output volXO10A to 10mV rms, proceed as follows:
1. Connect a voltmeter (e.g. TVT-321) capable of measuring AC 1V rms to OUTPUT terminal (6)
2. Set ATTENUATOR (4) to 0dB and then adjust AMPLITUDE (9) until the voltmeter indicates 1Vrms (6)
3. Set ATTENUATOR (4) to -40dB. The voltmeter indicates about OV, while a volXO10A of 10mVrms appears at OUTPUT terminal (6)
5) USE of Synchronizing input terminal (instrument is between 990Hz and 1010Hz)
By applying an external sine wave signal to SYNC terminal (5), the oscillating frequency can be synchronized to the external signal. Synchronizing range is increased in proportion as the input volXO10A is increased as shown in Fig.3, indicating that the synchronizing range is about 1% per input volXO10A of 1V.
Example: Suppose that the input signal volXO10A is 1Vrms and the
oscillating frequency of GENERATOR is between 990Hz and 1010Hz(1KHz±1KHz×1%/v×1V=1KHz±1KHz×0.01), the frequency can be synchronized with 1KHz of the input signal.
Note that too high synchronizing signal volXO10A will affect the amplitude and distortion factor, and care must therefore be taken when the signal volXO10A is higher than 3Vrms. Also, note that if the synchronizing signal is largely deviated the distortion factor. It is therefore advisable that the oscillating frequency be first synchronized with a low input signal volXO10A (less than 1Vrms) and then the volXO10A be increased.
6. APPLICATIONS
1) Using as sine wave oscillator
As a sine wave oscillator, features can be noted as below.
1.1 Low distortion factor can be obtained for measurement of distortion characteristic of amplifier.
1.2 As the unit working on wide bandwidth, it can be used for measurement of frequency characteristic of amplifier.
1.3 The built-in high accuracy attenuator permits measurement of amplifier gain.
1.4 Can be used as a signal source of impedance bridge.
2)Measurement of amplifier gain
An example of measurement of amplifier gain is described below
First connect the instrument, amplifier to be tested and AC
volt-meter as shown in Fig.4
2.1Adjust ATTENUATOR (4) and AMPLITUDE(9) so that AC voltmeter indicates the rated output (supposed to be 1 Vin this example) of the amplifier. To facilitate the measurement, it is advisable to set ATTENUATOR(4) as low as possible. Assume that ATTENUATOR (4) is set -50dB for the rated output.
2.2 Disconnect the amplifier and connect the AC voltmeter to instrument to measure the output volXO10A. Note that the use of ATTENUATOR (4) eliminates the need for connecting a high sensitivity voltmeter. If ATTENUATOR(4) is set to 0dB and the voltmeter indicates 2V, it means that the input volXO10A of the amplifier is 50dB below 2V. Therefore, the gain obtained is as follows:
3) Measurements of phase characteristic
Connect the instrument and an oscilloscope to the amplifier to be tested as shown in Fig5. If there is no phase shift about the output signal of the amplifier, the oscilloscope will display a straight line as shown in Fig. 5A. If the straight line on the oscilloscope is curved at its top and bottom sections as shown in Fig.5B, it indicates that the output signal of amplifier is suffering from an amplitude distortion. In this case, reduce the output level of instrument a little to vary the
frequency. This causes the straight line on the oscilloscope to expand gradually to turn into an ellipse. By utilizing the configuration of this ellipse. The phase shift can be calculated as follows:
First, measure the maximum horizontal deflection and suppose that this deflection is”X” and that the section at which the ellipse crosses the horizontal axis is “X, as show in Fig.6. And, the phase shift angle θ is given by the following
Find from the table of trigonometric functions and the value obtained gives the angle of phase shift.
4) Using as square wave oscillator
The instrument features excellent rising and falling characteristics (120ns as standard characteristic.) it has no coupling capacitors in the output sXO10A, so the sag (deflection of top section) is as low as 5% at 50Hz. By applying such a good square wave to an amplifier input, various characteristics of amplifier can be observed on an oscilloscope. To test an amplifier proceed as follows:
4.1 connect the instrument, an amplifier to be tested and an oscilloscope as shown in Fig7.
4.2 Press WAVE FORM (8) to the “” position to obtain square waves of appropriate frequency and amplitude.
4.3 During the test, change the frequency as necessary. The relationship between waveforms and amplifier characteristics is shown in Fig.8
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