TAN-005 ...the analog plus company TM High-Quality Function Generator System with the XR-2206 June 1997-3 INTRODUCTION However, they represent the typical performance characteristics measured by EXAR’s application engineers during the laboratory evaluation of the function generator system shown in Figure 1. The typical performance specifications listed below apply only when all of the recommended assembly instructions and adjustment procedures are followed: Waveform or function generators capable of producing AM/FM modulated sine wave outputs find a wide range of applications in electrical measurement and laboratory instrumentation. This application note describes the design, construction and performance of such a complete function generator system suitable for laboratory usage or hobbyist applications. The entire function generator is comprised of a single XR-2206 monolithic IC and a limited number of passive circuit components. It provides the engineer, student, or hobbyist with a highly versatile laboratory instrument for waveform generation, at a very small fraction of the cost of conventional function generators available today. (a) Frequency Ranges: The function generator system is designed to operate over four overlapping frequency ranges: 1Hz 10Hz 100Hz 1KHz GENERAL DESCRIPTION to to to to 100Hz 1KHz 10KHz 100KHz The range selection is made by switching in different timing capacitors. The basic circuit configuration and the external components necessary for the high-quality function generator system is shown in Figure 1. The circuit shown is designed to operate with either a 12V single power supply, or with 16V split supplies. For most applications, split-supply operation is preferred since it results in an output dc level which is nearly at ground potential. (b) Frequency Setting: At any range setting, frequency can be varied over a 100:1 tuning range with a potentiometer (see R13 of Figure 1.) (c) Frequency Accuracy: Frequency accuracy of the XR-2206 is set by the timing resistor R and the timing capacitor C, and is given as: The circuit configuration of Figure 1 provides three basic waveforms: sine, triangle and square wave. There are four overlapping frequency ranges which give an overall frequency range of 1Hz to 100KHz. In each range, the frequency may be varied over a 100:1 tuning range. f = 1/RC The above expression is accurate to within 15% at any range setting. The timing resistor R is the series combination of resistors R4 and R13 of Figure 1. The timing capacitor C is any one of the capacitors C3 through C6, shown in the figure. The sine or triangle output can be varied from 0 to over 6V (peak to peak) from a 600 source at the output terminal. (d) Sine and Triangle Output: The sine and triangle output amplitudes are variable from 0V to 6Vpp. The amplitude is set by an external potentiometer, R12 of Figure 1. At any given amplitude setting, the triangle output amplitude is approximately twice as high as the sinewave output. The internal impedance of the output is 600. A squarewave output is available at the sync output terminal for oscilloscope synchronizing or driving logic circuits. TYPICAL PERFORMANCE CHARACTERISTICS The performance characteristics listed are not guaranteed or warranted by EXAR Corporation. Rev. 1.02 1995 EXAR Corporation, 48720 Kato Road, Fremont, CA 94538 (510) 668-7000 FAX (510) 668-7017 1 TAN-005 (e) Sinewave Distortion: The total harmonic distortion of sinewave is less than 1% from 10Hz to 10KHz and less than 3% over the entire frequency range. The selection of a waveform is made by the triangle/sine selector switch, S2. (f) Sync Output: The sync output provides a 50% duty cycle pulse output with either full swing or upper half swing of the supply voltage depending on the choice of sync output terminals on the printed circuit board (see Figure 1.) V CC V EE R1 30K 4 1 AM INPUT VCC AM INP. 16 SYM ADJ. D S1 Range Select Switch AMPLITUDE 50K C3 1µF E C4 0.1µF F C5 0.01µF G C6 0.001µF 9 5 3 R R12 KEY IN V CC R11 25K 15 SYMMETRY R5 5K TC1 XR-2206 6 H R7 1K U1 RX Q VEE 2 SINE OUT P TC2 OUTPUT L SYNC OUTPUT (HALF SWING) M SYNC OUTPUT (FULL SWING) R6 5K MULT OUT V CC 11 SYNC OUT 13 WA1 R2 100K R9 1M R10 DC OFFSET 12 VEE T R 1 V CC V+ RED A B Y P A S WA2 S GND V EE C2 R8 300 T R 2 7 8 10µF 10V R3 1K 1K 14 C7 10µF 6V R4 9K GND BLACK C1 R15 5.1K VEE 10µF 10V VBLUE V EE I J K R13 SWEEP INPUT 1M FREQUENCY Figure 1. Circuit Connection Diagram for Function Generator (See (i) for Single Supply Operation) Rev. 1.02 2 S2 TRI/SINE SW N 10 R14 5.1K O TAN-005 Triangle/Sine Waveform Switch, S2: Selects the triangle or sine output waveform. g) Frequency Modulation (External Sweep): Frequency can be modulated or swept by applying an external control voltage to sweep terminal (Terminal I of Figure 1.) When not used, this terminal should be left open circuited. The open circuit voltage at this terminal is approximately 3V above the negative supply voltage and its impedance is approximately 1000W. Trimmers and Potentiometers DC Offset Adjustment, R9: The potentiometer used for adjusting the dc offset level of the triangle or sine output waveform. (h) Amplitude Modulation: The output amplitude varies linearly with modulation voltage applied to AM input (terminal Q of Figure 1.) The output amplitude reaches its minimum as the AM control voltage approaches the half of the total power supply voltage. The phase of the output signal reverses as the amplitude goes through its minimum value. The total dynamic range is approximately 55dB, with AM control voltage range of 4V referenced to the half of the total supply voltage. When not used, AM terminal should be left open-circuited. Sinewave Distortion Adjustment, R10: Adjusted to minimize the harmonic content of sinewave output. Sinewave Symmetry Adjustment, R11: Adjusted to optimize the symmetry of the sinewave output. Amplitude Control, R12: Sets the amplitude of the triangle or sinewave output. Frequency Adjust, R13: Sets the oscillator frequency for any range setting of S1. Thus, R13 serves as a frequency dial on a conventional waveform generator and varies the frequency of the oscillator over an approximate 100 to 1 range. (i) Power Source: Split Supplies: +/-6V, or single supply: +12V. Supply Current 15mA (see Figure 2). For single supply operation bias resistors, R14 and R15 should be added, the GND point left floating and V-tied to ground. Terminals A. Negative Supply -6V B. Ground C. Positive Supply +6V EXPLANATION OF CIRCUIT CONTROLS D. Range 1, timing capacitor terminal E. Range 2, timing capacitor terminal Switches F. Range Select Switch, S1: Selects the frequency range of operation for the function generator. The frequency is inversely proportional to the timing capacitor connected across Pins 5 and 6 of the XR-2206 circuit. Nominal capacitance values and frequency ranges corresponding to switch positions of S1 are as follows: Position Nominal Range Timing Capacitance 1 1Hz to 100Hz 1mF 2 10Hz to 1KHz 0.1mF 3 100Hz to 10KHz 0.01mF 4 1Hz to 100kHz 0.001mF Range 3. timing capacitor terminal G. Range 4, timing capacitor terminal H. Timing capacitor common terminal I. Sweep Input J. Frequency adjust potentiometer terminal K. Frequency adjust potentiometer negative supply terminal L. Sync output (1/2 swing) M. Sync output (full swing) N. Triangle/sine waveform switch terminals O. Triangle/sine waveform switch terminals P. Triangle or sinewave output Q. AM input If additional frequency ranges are needed, they can be added by introducing additional switch positions. R. Amplitude control terminal Rev. 1.02 3 TAN-005 PARTS LIST S1 S2 The following is a list of external circuit components necessary to provide the circuit interconnections shown in Figure 1. Power Supply: Dual supplies 16V or single +12V Capacitors: C1, C2, C7 C3 C4 C5 C6 Rotary switch, 1-pole, 4 positions Toggle or slide, SPST Batteries or power supply unit Electrolytic, 10µF, 10V Mylar, 1µF, nonpolar, 10% Mylar, 0.1µF, 10% Mylar, 0.01µF, 10% Mylar, 1000pF, 10% (See Figure 2 (a) and Figure 2 (b).) Miscellaneous: Knobs, solder, wires, terminals, etc. Resistors: R1 R2 R3, R7 R4 R5, R6 R8 RX BOARD LAYOUT 30K, 1/4 W, 10% 100K, 1/4 W, 10% 1K, 1/4 W, 10% 9K, 1/4 W, 10% 5K, 1/4 W. 10% 300K,1/4 W, 10% 62K, 1/4 W, 10% (RX can be eliminated for maximum output) Care should be given to the layout of the board, to prevent noise from the supplies from affecting the XR-2206 performance. Any simple power supply having reasonable regulation may be used. Figure 2 gives some recommended power supply configurations. Precaution: Keep the lead lengths small for the range selector switch. This will reduce stray capacitance. The following two resistors are used in single supply applications: R14, R15 5.1K, 1/4 W 10% ADJUSTMENT PROCEDURE Potentiometers: R9 R10 R11 When assembly is completed and you are ready to put the function generator into operation, make sure that the polarity of power supply and the orientation of the IC unit are correct. Then apply the dc power to the unit. Trim, 1M, 1/4 W Trim, 1K, 1/4 W Trim, 25K, 1/4 W The following additional items are recommended to convert the circuit of Figure 1 to a complete laboratory instrument: To adjust for minimum distortion, connect the scope probe to the triangle/sine output. Close S2 and adjust the amplitude control to give non-clipping maximum swing. Then adjust R10 and R11 alternately for minimum distortion by observing the sinusoidal waveform. If a distortion meter is available, you may use it as a final check on the setting of sine-shaping trimmers. The minimum distortion obtained in this manner is typically less than 1% from 1Hz to 10KHz and less than 3% over the entire frequency range. Potentiometers: R12 Amplitude control, linear, 50K R13 Frequency control, audio taper, 1M Switches: Rev. 1.02 4 TAN-005 T1 115 VAC CT D1 12.6V RMS D2 +6V R1 51 RED D3 C1 500µF D4 D5 6V GND BLACK C2 500µF R2 51 D6 6V -6V BLUE (a) Zener Regulated Supply 6V + +6V RED GND BLACK 6V -6V + BLUE (b) Battery Power Supply T1: Filament Transformer (Primary 115V Secondary 12.6 VCT 0.5A) D1 - D4: 1N4001 or Similar D5, D6: 1N4735 or Similar R1, R2: 51Ω, 1/2W, 10% Figure 2. Recommended Power Supply Configurations Rev. 1.02 5 TAN-005 Notes Rev. 1.02 6 TAN-005 Notes Rev. 1.02 7 TAN-005 NOTICE EXAR Corporation reserves the right to make changes to the products contained in this publication in order to improve design, performance or reliability. EXAR Corporation assumes no responsibility for the use of any circuits described herein, conveys no license under any patent or other right, and makes no representation that the circuits are free of patent infringement. Charts and schedules contained here in are only for illustration purposes and may vary depending upon a user’s specific application. While the information in this publication has been carefully checked; no responsibility, however, is assumed for inaccuracies. EXAR Corporation does not recommend the use of any of its products in life support applications where the failure or malfunction of the product can reasonably be expected to cause failure of the life support system or to significantly affect its safety or effectiveness. Products are not authorized for use in such applications unless EXAR Corporation receives, in writing, assurances to its satisfaction that: (a) the risk of injury or damage has been minimized; (b) the user assumes all such risks; (c) potential liability of EXAR Corporation is adequately protected under the circumstances. Copyright 1996 EXAR Corporation Application Note June 1997 Reproduction, in part or whole, without the prior written consent of EXAR Corporation is prohibited. Rev. 1.02 8