MAXIM MAX038

19-0266; Rev 2a; 9/96
KIT
ATION
EVALU
LE
B
A
IL
A
AV
High-Frequency Waveform Generator
The MAX038 is a high-frequency, precision function
generator producing accurate, high-frequency triangle,
sawtooth, sine, square, and pulse waveforms with a
minimum of external components. The output frequency
can be controlled over a frequency range of 0.1Hz to
20MHz by an internal 2.5V bandgap voltage
reference and an external resistor and capacitor. The
duty cycle can be varied over a wide range by applying
a ±2.3V control signal, facilitating pulse-width modulation and the generation of sawtooth waveforms.
Frequency modulation and frequency sweeping are
achieved in the same way. The duty cycle and
frequency controls are independent.
Sine, square, or triangle waveforms can be selected at
the output by setting the appropriate code at two
TTL-compatible select pins. The output signal for all
waveforms is a 2VP-P signal that is symmetrical around
ground. The low-impedance output can drive up
to ±20mA.
The TTL-compatible SYNC output from the internal
oscillator maintains a 50% duty cycle—regardless of
the duty cycle of the other waveforms—to synchronize
other devices in the system. The internal oscillator can
be synchronized to an external TTL clock connected
to PDI.
________________________Applications
____________________________Features
♦ 0.1Hz to 20MHz Operating Frequency Range
♦ Triangle, Sawtooth, Sine, Square, and Pulse
Waveforms
♦ Independent Frequency and Duty-Cycle
Adjustments
♦ 350 to 1 Frequency Sweep Range
♦ 15% to 85% Variable Duty Cycle
♦ Low-Impedance Output Buffer: 0.1Ω
♦ Low-Distortion Sine Wave: 0.75%
♦ Low 200ppm/°C Temperature Drift
______________Ordering Information
PART
TEMP. RANGE
PIN-PACKAGE
MAX038CPP
0°C to +70°C
20 Plastic DIP
MAX038CWP
MAX038C/D
MAX038EPP
MAX038EWP
0°C to +70°C
0°C to +70°C
-40°C to +85°C
-40°C to +85°C
20 SO
Dice*
20 Plastic DIP
20 SO
*Contact factory for dice specifications.
__________________Pin Configuration
Precision Function Generators
Voltage-Controlled Oscillators
Frequency Modulators
TOP VIEW
Pulse-Width Modulators
REF 1
20 V-
Phase-Locked Loops
GND 2
19 OUT
Frequency Synthesizer
A0 3
FSK Generator—Sine and Square Waves
A1 4
18 GND
MAX038
COSC 5
17 V+
16 DV+
GND 6
15 DGND
DADJ 7
14 SYNC
FADJ 8
13 PDI
GND 9
12 PDO
IIN 10
11 GND
DIP/SO
________________________________________________________________ Maxim Integrated Products
1
For free samples & the latest literature: http://www.maxim-ic.com, or phone 1-800-998-8800.
For small orders, phone 408-737-7600 ext. 3468.
MAX038
_______________General Description
MAX038
High-Frequency Waveform Generator
ABSOLUTE MAXIMUM RATINGS
V+ to GND ................................................................-0.3V to +6V
DV+ to DGND...........................................................-0.3V to +6V
V- to GND .................................................................+0.3V to -6V
Pin Voltages
IIN, FADJ, DADJ, PDO .....................(V- - 0.3V) to (V+ + 0.3V)
COSC .....................................................................+0.3V to VA0, A1, PDI, SYNC, REF.........................................-0.3V to V+
GND to DGND ................................................................±0.3V
Maximum Current into Any Pin .........................................±50mA
OUT, REF Short-Circuit Duration to GND, V+, V- ...............30sec
Continuous Power Dissipation (TA = +70°C)
Plastic DIP (derate 11.11mW/°C above +70°C) ..........889mW
SO (derate 10.00mW/°C above +70°C) .......................800mW
CERDIP (derate 11.11mW/°C above +70°C) ...............889mW
Operating Temperature Ranges
MAX038C_ _ .......................................................0°C to +70°C
MAX038E_ _ ....................................................-40°C to +85°C
Maximum Junction Temperature .....................................+150°C
Storage Temperature Range .............................-65°C to +150°C
Lead Temperature (soldering, 10sec) .............................+300°C
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
ELECTRICAL CHARACTERISTICS
(Circuit of Figure 1, GND = DGND = 0V, V+ = DV+ = 5V, V- = -5V, V DADJ = V FADJ = V PDI = V PDO = 0V, C F = 100pF,
RIN = 25kΩ, RL = 1kΩ, CL = 20pF, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
SYMBOL
FREQUENCY CHARACTERISTICS
Maximum Operating Frequency
Fo
Frequency Programming
Current
IIN
IIN Offset Voltage
VIN
Frequency Temperature
Coefficient
∆Fo/°C
CONDITIONS
MIN
TYP
15pCF ≤ 15pF, IIN = 500µA
20.0
40.0
VFADJ = 0V
2.50
750
VFADJ = -3V
1.25
375
±1.0
VFADJ = 0V
MAX
MHz
±2.0
600
Fo/°C
VFADJ = -3V
(∆Fo/Fo)
V- = -5V, V+ = 4.75V to 5.25V
∆V+
Frequency Power-Supply
Rejection
(∆Fo/Fo)
V+ = 5V, V- = -4.75V to -5.25V
∆VOUTPUT AMPLIFIER (applies to all waveforms)
UNITS
µA
mV
ppm/°C
200
±0.4
±2.00
±0.2
±1.00
%/V
Output Peak-to-Peak Symmetry
VOUT
±4
Output Resistance
ROUT
0.1
Output Short-Circuit Current
IOUT
Short circuit to GND
mV
0.2
40
Ω
mA
SQUARE-WAVE OUTPUT (RL = 100Ω)
Amplitude
VOUT
Rise Time
tR
10% to 90%
1.9
Fall Time
tF
90% to 10%
Duty Cycle
dc
VDADJ = 0V, dc = tON/t x 100%
2.0
2.1
12
VP-P
ns
12
ns
47
50
53
%
1.9
2.0
2.1
VP-P
TRIANGLE-WAVE OUTPUT (RL = 100Ω)
Amplitude
VOUT
Nonlinearity
Duty Cycle
Fo = 100kHz, 5% to 95%
dc
VDADJ = 0V (Note 1)
0.5
47
%
50
53
%
2.0
2.1
VP-P
SINE-WAVE OUTPUT (RL = 100Ω)
Amplitude
Total Harmonic Distortion
2
VOUT
THD
1.9
Duty cycle adjusted to 50%
0.75
Duty cycle unadjusted
1.50
_______________________________________________________________________________________
%
High-Frequency Waveform Generator
(Circuit of Figure 1, GND = DGND = 0V, V+ = DV+ = 5V, V- = -5V, V DADJ = V FADJ = V PDI = V PDO = 0V, C F = 100pF,
RIN = 25kΩ, RL = 1kΩ, CL = 20pF, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
SYMBOL
SYNC OUTPUT
Output Low Voltage
VOL
Output High Voltage
VOH
Rise Time
tR
Fall Time
tF
Duty Cycle
dcSYNC
DUTY-CYCLE ADJUSTMENT (DADJ)
DADJ Input Current
IDADJ
DADJ Voltage Range
VDADJ
Duty-Cycle Adjustment Range
dc
DADJ Nonlinearity
dc/VFADJ
Change in Output Frequency
Fo/VDADJ
with DADJ
Maximum DADJ Modulating
FDC
Frequency
FREQUENCY ADJUSTMENT (FADJ)
FADJ Input Current
IFADJ
FADJ Voltage Range
VFADJ
Frequency Sweep Range
Fo
FM Nonlinearity with FADJ
Fo/VFADJ
Change in Duty Cycle with FADJ dc/VFADJ
Maximum FADJ Modulating
FF
Frequency
VOLTAGE REFERENCE
Output Voltage
VREF
Temperature Coefficient
CONDITIONS
ISINK = 3.2mA
ISOURCE = 400µA
10% to 90%, RL = 3kΩ, CL = 15pF
90% to 10%, RL = 3kΩ, CL = 15pF
MIN
2.8
190
-2.3V ≤ VDADJ ≤ 2.3V
-2V ≤ VDADJ ≤ 2V
VREF/IREF
Line Regulation
VREF/V+
MAX
UNITS
0.3
3.5
10
10
50
0.4
V
V
ns
ns
%
250
±2.3
320
2
85
4
µA
V
%
%
±2.5
±8
%
15
-2V ≤ VDADJ ≤ 2V
2
190
-2.4V ≤ VFADJ ≤ 2.4V
-2V ≤ VFADJ ≤ 2V
-2V ≤ VFADJ ≤ 2V
250
±2.4
±70
±0.2
±2
MHz
320
2
IREF = 0
2.48
VREF/°C
Load Regulation
TYP
2.50
20
1
1
1
0mA ≤ IREF ≤ 4mA (source)
-100µA ≤ IREF ≤ 0µA (sink)
4.75V ≤ V+ ≤ 5.25V (Note 2)
µA
V
%
%
%
MHz
2.52
V
ppm/°C
2
4
2
mV/mA
mV/V
LOGIC INPUTS (A0, A1, PDI)
Input Low Voltage
VIL
Input High Voltage
VIH
0.8
V
2.4
V
Input Current (A0, A1)
IIL, IIH
VA0, VA1 = VIL, VIH
±5
µA
Input Current (PDI)
IIL, IIH
VPDI = VIL, VIH
±25
µA
POWER SUPPLY
Positive Supply Voltage
SYNC Supply Voltage
Negative Supply Voltage
Positive Supply Current
SYNC Supply Current
Negative Supply Current
V+
4.75
5.25
V
DV+
4.75
5.25
V
V-
-4.75
-5.25
V
I+
35
45
mA
IDV+
1
2
mA
I-
45
55
mA
Note 1: Guaranteed by duty-cycle test on square wave.
Note 2: VREF is independent of V-.
_______________________________________________________________________________________
3
MAX038
ELECTRICAL CHARACTERISTICS (continued)
__________________________________________Typical Operating Characteristics
(Circuit of Figure 1, V+ = DV+ = 5V, V- = -5V, VDADJ = VFADJ = VPDI = VPDO = 0V, RL = 1kΩ, CL = 20pF, TA = +25°C, unless
otherwise noted.)
NORMALIZED OUTPUT FREQUENCY
vs. FADJ VOLTAGE
OUTPUT FREQUENCY
vs. IIN CURRENT
10M
1.8
33pF
100pF
330pF
OUTPUT FREQUENCY (Hz)
1M
3.3nF
100k
10k
MAX038-09
2.0
IIN = 100µA, COSC = 1000pF
1.6
FOUT NORMALIZED
MAX038-08
100M
1.4
1.2
1.0
0.8
0.6
33nF
0.4
100nF
0.2
0
-3
1k
-2
0
-1
1µF
2
1
3
VFADJ (V)
3.3µF
DUTY CYCLE vs. DADJ VOLTAGE
10µF
100
90
47µF
100µF
1
0.1
1
10
100
1000
80
DUTY CYCLE (%)
10
MAX038-16B
100
IIN CURRENT (µA)
70
60
50
40
30
20
10
IIN = 200µA
0
-3
-2
-1
1
0
2
3
DADJ (V)
NORMALIZED OUTPUT FREQUENCY
vs. DADJ VOLTAGE
IIN = 25µA
IIN = 50µA
1.00
0.95
IIN = 100µA
IIN = 250µA
0.90
IIN = 500µA
IIN = 500µA
1.5
1.0
0.5
IIN = 250µA
0
IIN = 100µA
-0.5
-1.0
-1.5
IIN = 50µA
IIN = 25µA
IIN = 10µA
-2.0
-2.5
0.85
-2.0
DADJ (V)
4
MAX038-18
2.0
DUTY-CYCLE LINEARITY ERROR (%)
IIN = 10µA
1.05
DUTY-CYCLE LINEARITY
vs. DADJ VOLTAGE
MAX038-17
1.10
NORMALIZED OUTPUT FREQUENCY
MAX038
High-Frequency Waveform Generator
-1.0
0
1.0
1.5
2.5
DADJ (V)
_______________________________________________________________________________________
High-Frequency Waveform Generator
SINE-WAVE OUTPUT (50Hz)
SINE-WAVE OUTPUT (20MHz)
TOP: OUTPUT 50Hz = Fo
BOTTOM: SYNC
IIN = 50µA
CF = 1µF
IIN = 400µA
CF = 20pF
TRIANGLE-WAVE OUTPUT (50Hz)
TOP: OUTPUT 50Hz = Fo
BOTTOM: SYNC
IIN = 50µA
CF = 1µF
TRIANGLE-WAVE OUTPUT (20MHz)
IIN = 400µA
CF = 20pF
SQUARE-WAVE OUTPUT (50Hz)
TOP: OUTPUT 50Hz = Fo
BOTTOM: SYNC
IIN = 50µA
CF = 1µF
_______________________________________________________________________________________
5
MAX038
____________________________Typical Operating Characteristics (continued)
(Circuit of Figure 1, V+ = DV+ = 5V, V- = -5V, VDADJ = VFADJ = VPDI = VPDO = 0V, RL = 1kΩ, CL = 20pF, TA = +25°C, unless
otherwise noted.)
MAX038
High-Frequency Waveform Generator
____________________________Typical Operating Characteristics (continued)
(Circuit of Figure 1, V+ = DV+ = 5V, V- = -5V, VDADJ = VFADJ = VPDI = VPDO = 0V, RL = 1kΩ, CL = 20pF, TA = +25°C, unless
otherwise noted.)
SQUARE-WAVE OUTPUT (20MHz)
FREQUENCY MODULATION USING FADJ
0.5V
0
-0.5V
IIN = 400µA
CF = 20pF
TOP: OUTPUT
BOTTOM: FADJ
FREQUENCY MODULATION USING IIN
FREQUENCY MODULATION USING IIN
TOP: OUTPUT
BOTTOM: IIN
TOP: OUTPUT
BOTTOM: IIN
PULSE-WIDTH MODULATION USING DADJ
+1V
0V
-1V
+2V
0V
-2V
TOP: SQUARE-WAVE OUT, 2VP-P
BOTTOM: VDADJ, -2V to +2.3V
6
_______________________________________________________________________________________
High-Frequency Waveform Generator
OUTPUT SPECTRUM, SINE WAVE
(Fo = 11.5MHz)
0
-20
-20
ATTENUATION (dB)
ATTENUATION (dB)
RIN = 51kΩ (VIN = 2.5V), CF = 0.01µF,
VDADJ = 50mV, VFADJ = 0V
-10
MAX038 12B
RIN = 15kΩ (VIN = 2.5V), CF = 20pF,
VDADJ = 40mV, VFADJ = -3V
MAX038-12A
0
-10
OUTPUT SPECTRUM, SINE WAVE
(Fo = 5.9kHz)
-30
-40
-50
-60
-70
-30
-40
-50
-60
-70
-80
-80
-90
-90
-100
-100
0
10 20 30 40 50 60 70 80 90 100
0
5
10 15 20 25 30 35 40 45 50
FREQUENCY (MHz)
FREQUENCY (kHz)
______________________________________________________________Pin Description
PIN
NAME
1
REF
2.50V bandgap voltage reference output
FUNCTION
2, 6, 9,
11, 18
GND
Ground*
3
A0
Waveform selection input; TTL/CMOS compatible
4
A1
Waveform selection input; TTL/CMOS compatible
5
COSC
External capacitor connection
7
DADJ
Duty-cycle adjust input
Frequency adjust input
8
FADJ
10
IIN
12
PDO
Phase detector output. Connect to GND if phase detector is not used.
13
PDI
Phase detector reference clock input. Connect to GND if phase detector is not used.
14
SYNC
TTL/CMOS-compatible output, referenced between DGND and DV+. Permits the internal oscillator to be
synchronized with an external signal. Leave open if unused.
15
DGND
Digital ground
16
DV+
17
V+
19
OUT
20
V-
Current input for frequency control
Digital +5V supply input. Can be left open if SYNC is not used.
+5V supply input
Sine, square, or triangle output
-5V supply input
*The five GND pins are not internally connected. Connect all five GND pins to a quiet ground close to the device. A ground plane is
recommended (see Layout Considerations).
_______________________________________________________________________________________
7
MAX038
____________________________Typical Operating Characteristics (continued)
(Circuit of Figure 1, V+ = DV+ = 5V, V- = -5V, VDADJ = VFADJ = VPDI = VPDO = 0V, RL = 1kΩ, CL = 20pF, TA = +25°C, unless
otherwise noted.)
MAX038
High-Frequency Waveform Generator
5
TRIANGLE
COSC
OSCILLATOR
CF
6
GND
OSC A
OSC B
3
4
A0
A1
SINE
SINE
SHAPER
OUT
TRIANGLE
19
MUX
SQUARE
8
7
10
FADJ
DADJ
OSCILLATOR
CURRENT
GENERATOR
RL
CL
COMPARATOR
IIN
MAX038
RF
RD
RIN
-250µA
COMPARATOR
*
+5V
-5V
1
REF
17
20
V+
V-
2, 9, 11, 18
14
PDO
12
PDI
13
2.5V
VOLTAGE
REFERENCE
PHASE
DETECTOR
GND
DGND
DV+
16
15
*
= SIGNAL DIRECTION, NOT POLARITY
*
SYNC
+5V
= BYPASS CAPACITORS ARE 1µF CERAMIC OR 1µF ELECTROLYTIC IN PARALLEL WITH 1nF CERAMIC.
Figure 1. Block Diagram and Basic Operating Circuit
_______________Detailed Description
The MAX038 is a high-frequency function generator
that produces low-distortion sine, triangle, sawtooth, or
square (pulse) waveforms at frequencies from less than
1Hz to 20MHz or more, using a minimum of external
components. Frequency and duty cycle can be independently controlled by programming the current, voltage, or resistance. The desired output waveform is
selected under logic control by setting the appropriate
code at the A0 and A1 inputs. A SYNC output and
phase detector are included to simplify designs requiring tracking to an external signal source.
The MAX038 operates with ±5V ±5% power supplies.
The basic oscillator is a relaxation type that operates by
alternately charging and discharging a capacitor, CF,
8
with constant currents, simultaneously producing a triangle wave and a square wave (Figure 1). The charging and discharging currents are controlled by the current flowing into IIN, and are modulated by the voltages
applied to FADJ and DADJ. The current into IIN can be
varied from 2µA to 750µA, producing more than two
decades of frequency for any value of CF. Applying
±2.4V to FADJ changes the nominal frequency (with
VFADJ = 0V) by ±70%; this procedure can be used for
fine control.
Duty cycle (the percentage of time that the output waveform is positive) can be controlled from 10% to 90% by
applying ±2.3V to DADJ. This voltage changes the CF
charging and discharging current ratio while maintaining
nearly constant frequency.
_______________________________________________________________________________________
High-Frequency Waveform Generator
The output frequency is inversely proportional to
capacitor CF. CF values can be selected to produce
frequencies above 20MHz.
A sine-shaping circuit converts the oscillator triangle
wave into a low-distortion sine wave with constant
amplitude. The triangle, square, and sine waves are
input to a multiplexer. Two address lines, A0 and A1,
control which of the three waveforms is selected. The
output amplifier produces a constant 2VP-P amplitude
(±1V), regardless of wave shape or frequency.
The triangle wave is also sent to a comparator that produces a high-speed square-wave SYNC waveform that
can be used to synchronize other oscillators. The SYNC
circuit has separate power-supply leads and can be
disabled.
Two other phase-quadrature square waves are generated in the basic oscillator and sent to one side of an
“exclusive-OR” phase detector. The other side of the
phase-detector input (PDI) can be connected to an
external oscillator. The phase-detector output (PDO) is
a current source that can be connected directly to
FADJ to synchronize the MAX038 with the external
oscillator.
Waveform Selection
The MAX038 can produce either sine, square, or triangle waveforms. The TTL/CMOS-logic address pins (A0
and A1) set the waveform, as shown below:
A0
X
0
1
A1
1
0
0
WAVEFORM
Sine wave
Square wave
Triangle wave
X = Don’t care
Waveform switching can be done at any time, without
regard to the phase of the output. Switching occurs
within 0.3µs, but there may be a small transient in the
output waveform that lasts 0.5µs.
Waveform Timing
Output Frequency
The output frequency is determined by the current
injected into the IIN pin, the COSC capacitance (to
ground), and the voltage on the FADJ pin. When
VFADJ = 0V, the fundamental output frequency (Fo) is
given by the formula:
Fo (MHz) = IIN (µA) ÷ CF (pF)
[1]
The period (to) is:
to (µs) = CF (pF) ÷ IIN (µA)
[2]
where:
IIN = current injected into IIN (between 2µA and
750µA)
CF = capacitance connected to COSC and GND
(20pF to >100µF).
For example:
0.5MHz = 100µA ÷ 200pF
and
2µs = 200pF ÷ 100µA
Optimum performance is achieved with IIN between
10µA and 400µA, although linearity is good with I IN
between 2µA and 750µA. Current levels outside of this
range are not recommended. For fixed-frequency operation, set IIN to approximately 100µA and select a suitable capacitor value. This current produces the lowest
temperature coefficient, and produces the lowest frequency shift when varying the duty cycle.
The capacitance can range from 20pF to more than
100µF, but stray circuit capacitance must be minimized
by using short traces. Surround the COSC pin and the
trace leading to it with a ground plane to minimize coupling of extraneous signals to this node. Oscillation
above 20MHz is possible, but waveform distortion
increases under these conditions. The low frequency
limit is set by the leakage of the COSC capacitor and
by the required accuracy of the output frequency.
Lowest frequency operation with good accuracy is usually achieved with 10µF or greater non-polarized
capacitors.
An internal closed-loop amplifier forces IIN to virtual
ground, with an input offset voltage less than ±2mV. IIN
may be driven with either a current source (IIN), or a
voltage (VIN) in series with a resistor (RIN). (A resistor
between REF and IIN provides a convenient method of
generating IIN: IIN = VREF/RIN.) When using a voltage
in series with a resistor, the formula for the oscillator frequency is:
Fo (MHz) = VIN ÷ [RIN x CF (pF)] [3]
and:
to (µs) = CF (pF) x RIN ÷ VIN
[4]
_______________________________________________________________________________________
9
MAX038
A stable 2.5V reference voltage, REF, allows simple
determination of IIN, FADJ, or DADJ with fixed resistors,
and permits adjustable operation when potentiometers
are connected from each of these inputs to REF. FADJ
and/or DADJ can be grounded, producing the nominal
frequency with a 50% duty cycle.
MAX038
High-Frequency Waveform Generator
When the MAX038’s frequency is controlled by a voltage source (VIN) in series with a fixed resistor (RIN), the
output frequency is a direct function of VIN as shown in
the above equations. Varying VIN modulates the oscillator frequency. For example, using a 10kΩ resistor for
RIN and sweeping VIN from 20mV to 7.5V produces
large frequency deviations (up to 375:1). Select RIN so
that IIN stays within the 2µA to 750µA range. The bandwidth of the IIN control amplifier, which limits the modulating signal’s highest frequency, is typically 2MHz.
IIN can be used as a summing point to add or subtract
currents from several sources. This allows the output
frequency to be a function of the sum of several variables. As VIN approaches 0V, the IIN error increases
due to the offset voltage of IIN.
Output frequency will be offset 1% from its final value
for 10 seconds after power-up.
FADJ Input
The output frequency can be modulated by FADJ,
which is intended principally for fine frequency control,
usually inside phase-locked loops. Once the fundamental, or center frequency (Fo) is set by IIN, it may be
changed further by setting FADJ to a voltage other than
0V. This voltage can vary from -2.4V to +2.4V, causing
the output frequency to vary from 1.7 to 0.30 times the
value when FADJ is 0V (Fo ±70%). Voltages beyond
±2.4V can cause instability or cause the frequency
change to reverse slope.
The voltage on FADJ required to cause the output to
deviate from Fo by Dx (expressed in %) is given by the
formula:
VFADJ = -0.0343 x Dx
[5]
where V FADJ , the voltage on FADJ, is between
-2.4V and +2.4V.
Note: While IIN is directly proportional to the fundamental, or center frequency (Fo), VFADJ is linearly related to
% deviation from Fo. VFADJ goes to either side of 0V,
corresponding to plus and minus deviation.
The voltage on FADJ for any frequency is given by the
formula:
VFADJ = (Fo - Fx) ÷ (0.2915 x Fo) [6]
where:
Fx = output frequency
Fo = frequency when VFADJ = 0V.
Likewise, for period calculations:
VFADJ = 3.43 x (tx - to) ÷ tx
[7]
where:
tx = output period
10
to = period when VFADJ = 0V.
Conversely, if VFADJ is known, the frequency is given
by:
Fx = Fo x (1 - [0.2915 x VFADJ])
[8]
and the period (tx) is:
tx = to ÷ (1 - [0.2915 x VFADJ])
[9]
Programming FADJ
FADJ has a 250µA constant current sink to V- that must
be furnished by the voltage source. The source is usually an op-amp output, and the temperature coefficient
of the current sink becomes unimportant. For manual
adjustment of the deviation, a variable resistor can be
used to set VFADJ, but then the 250µA current sink’s
temperature coefficient becomes significant. Since
external resistors cannot match the internal temperature-coefficient curve, using external resistors to program V FADJ is intended only for manual operation,
when the operator can correct for any errors. This
restriction does not apply when VFADJ is a true voltage
source.
A variable resistor, RF, connected between REF (+2.5V)
and FADJ provides a convenient means of manually
setting the frequency deviation. The resistance value
(RF) is:
RF = (VREF - VFADJ) ÷ 250µA
[10]
VREF and VFADJ are signed numbers, so use correct
algebraic convention. For example, if V FADJ is -2.0V
(+58.3% deviation), the formula becomes:
RF = (+2.5V - (-2.0V)) ÷ 250µA
= (4.5V) ÷ 250µA
= 18kΩ
Disabling FADJ
The FADJ circuit adds a small temperature coefficient
to the output frequency. For critical open-loop applications, it can be turned off by connecting FADJ to GND
(not REF) through a 12kΩ resistor (R1 in Figure 2). The
-250µA current sink at FADJ causes -3V to be developed across this resistor, producing two results. First,
the FADJ circuit remains in its linear region, but disconnects itself from the main oscillator, improving temperature stability. Second, the oscillator frequency doubles.
If FADJ is turned off in this manner, be sure to correct
equations 1-4 and 6-9 above, and 12 and 14 below by
doubling Fo or halving to. Although this method doubles
the normal output frequency, it does not double the
upper frequency limit. Do not operate FADJ open circuit or with voltages more negative than -3.5V. Doing
so may cause transistor saturation inside the IC, leading to unwanted changes in frequency and duty cycle.
______________________________________________________________________________________
High-Frequency Waveform Generator
20
FREQUENCY
1
C1
1µF
C3
1nF
V-
10
8
DADJ
IIN
MAX038
OUT
DV+
DGND
SYNC
CF
3
19
C2
1µF
PDI
COSC
PDO
16
13
12
R3
100k
+2.5V
MAX038
R2
50Ω
SINE-WAVE
OUTPUT
R7
100k
R5
100k
N.C.
15
14
R4
100k
REF
FADJ
R1
12k
5
–2.5V
4
V+ A1
AO
7
RIN
20k
REF
17
MAX038
PRECISION DUTY-CYCLE ADJUSTMENT CIRCUIT
–5V +5V
R6
5k
N.C.
Fo =
2 x 2.5V
RIN x CF
DADJ
GND GND GND GND GND
6
2 9 11 18
ADJUST R6 FOR MINIMUM SINE-WAVE DISTORTION
Figure 2. Operating Circuit with Sine-Wave Output and 50% Duty Cycle; SYNC and FADJ Disabled
With FADJ disabled, the output frequency can still be
changed by modulating IIN.
Swept Frequency Operation
The output frequency can be swept by applying a varying signal to IIN or FADJ. IIN has a wider range, slightly
slower response, lower temperature coefficient, and
requires a single polarity current source. FADJ may be
used when the swept range is less than ±70% of the
center frequency, and it is suitable for phase-locked
loops and other low-deviation, high-accuracy closedloop controls. It uses a sweeping voltage symmetrical
about ground.
Connecting a resistive network between REF, the voltage source, and FADJ or IIN is a convenient means of
offsetting the sweep voltage.
Duty Cycle
The voltage on DADJ controls the waveform duty cycle
(defined as the percentage of time that the output
waveform is positive). Normally, VDADJ = 0V, and the
duty cycle is 50% (Figure 2). Varying this voltage from
+2.3V to -2.3V causes the output duty cycle to vary
from 15% to 85%, about -15% per volt. Voltages
beyond ±2.3V can shift the output frequency and/or
cause instability.
DADJ can be used to reduce the sine-wave distortion.
The unadjusted duty cycle (VDADJ = 0V) is 50% ±2%;
any deviation from exactly 50% causes even order harmonics to be generated. By applying a small
adjustable voltage (typically less than ±100mV) to
VDADJ, exact symmetry can be attained and the distortion can be minimized (see Figure 2).
The voltage on DADJ needed to produce a specific
duty cycle is given by the formula:
VDADJ = (50% - dc) x 0.0575
[11]
or:
VDADJ = (0.5 - [tON ÷ to]) x 5.75 [12]
where:
VDADJ = DADJ voltage (observe the polarity)
dc = duty cycle (in %)
tON = ON (positive) time
to = waveform period.
Conversely, if VDADJ is known, the duty cycle and ON
time are given by:
dc = 50% - (VDADJ x 17.4)
[13]
tON = to x (0.5 - [VDADJ x 0.174]) [14]
______________________________________________________________________________________
11
MAX038
High-Frequency Waveform Generator
Programming DADJ
DADJ is similar to FADJ; it has a 250µA constant current sink to V- that must be furnished by the voltage
source. The source is usually an op-amp output, and
the temperature coefficient of the current sink becomes
unimportant. For manual adjustment of the duty cycle, a
variable resistor can be used to set VDADJ, but then the
250µA current sink’s temperature coefficient becomes
significant. Since external resistors cannot match the
internal temperature-coefficient curve, using external
resistors to program VDADJ is intended only for manual
operation, when the operator can correct for any errors.
This restriction does not apply when VDADJ is a true
voltage source.
A variable resistor, R D , connected between REF
(+2.5V) and DADJ provides a convenient means of
manually setting the duty cycle. The resistance value
(RD) is:
RD = (VREF - VDADJ) ÷ 250µA
[15]
Note that both VREF and VDADJ are signed values, so
observe correct algebraic convention. For example, if
VDADJ is -1.5V (23% duty cycle), the formula becomes:
RD = (+2.5V - (-1.5V)) ÷ 250µA
= (4.0V) ÷ 250µA = 16kΩ
Varying the duty cycle in the range 15% to 85% has
minimal effect on the output frequency—typically less
than 2% when 25µA < IIN < 250µA. The DADJ circuit is
wideband, and can be modulated at up to 2MHz (see
photos, Typical Operating Characteristics).
Output
The output amplitude is fixed at 2V P-P, symmetrical
around ground, for all output waveforms. OUT has an
output resistance of under 0.1Ω, and can drive ±20mA
with up to a 50pF load. Isolate higher output capacitance from OUT with a resistor (typically 50Ω) or buffer
amplifier.
Reference Voltage
REF is a stable 2.50V bandgap voltage reference capable of sourcing 4mA or sinking 100µA. It is principally
used to furnish a stable current to IIN or to bias DADJ
and FADJ. It can also be used for other applications
external to the MAX038. Bypass REF with 100nF to minimize noise.
Selecting Resistors and Capacitors
The MAX038 produces a stable output frequency over
time and temperature, but the capacitor and resistors
that determine frequency can degrade performance if
they are not carefully chosen. Resistors should be
metal film, 1% or better. Capacitors should be chosen
12
for low temperature coefficient over the whole temperature range. NPO ceramics are usually satisfactory.
The voltage on COSC is a triangle wave that varies
between 0V and -1V. Polarized capacitors are generally
not recommended (because of their outrageous temperature dependence and leakage currents), but if they
are used, the negative terminal should be connected to
COSC and the positive terminal to GND. Large-value
capacitors, necessary for very low frequencies, should
be chosen with care, since potentially large leakage
currents and high dielectric absorption can interfere
with the orderly charge and discharge of CF. If possible, for a given frequency, use lower IIN currents to
reduce the size of the capacitor.
SYNC Output
SYNC is a TTL/CMOS-compatible output that can be
used to synchronize external circuits. The SYNC output
is a square wave whose rising edge coincides with the
output rising sine or triangle wave as it crosses through
0V. When the square wave is selected, the rising edge
of SYNC occurs in the middle of the positive half of the
output square wave, effectively 90° ahead of the output.
The SYNC duty cycle is fixed at 50% and is independent of the DADJ control.
Because SYNC is a very-high-speed TTL output, the
high-speed transient currents in DGND and DV+ can
radiate energy into the output circuit, causing a narrow
spike in the output waveform. (This spike is difficult to
see with oscilloscopes having less than 100MHz bandwidth). The inductance and capacitance of IC sockets
tend to amplify this effect, so sockets are not recommended when SYNC is on. SYNC is powered from separate ground and supply pins (DGND and DV+), and it
can be turned off by making DV+ open circuit. If synchronization of external circuits is not used, turning off
SYNC by DV+ opening eliminates the spike.
Phase Detectors
Internal Phase Detector
The MAX038 contains a TTL/CMOS phase detector that
can be used in a phase-locked loop (PLL) to synchronize its output to an external signal (Figure 3). The
external source is connected to the phase-detector
input (PDI) and the phase-detector output is taken from
PDO. PDO is the output of an exclusive-OR gate, and
produces a rectangular current waveform at the
MAX038 output frequency, even with PDI grounded.
PDO is normally connected to FADJ and a resistor,
RPD, and a capacitor CPD, to GND. RPD sets the gain
of the phase detector, while the capacitor attenuates
high-frequency components and forms a pole in the
phase-locked loop filter.
______________________________________________________________________________________
High-Frequency Waveform Generator
charge CPD, so the rate at which VFADJ changes (the
loop bandwidth) is inversely proportional to CPD.
The phase error (deviation from phase quadrature)
depends on the open-loop gain of the PLL and the initial frequency deviation of the oscillator from the external signal source. The oscillator conversion gain (Ko) is:
[17]
KO = ∆ωo ÷ ∆VFADJ
which, from equation [6] is:
KO = 3.43 x ωo (radians/sec)
[18]
C1
1µF
C2
1µF
CENTER
FREQUENCY
RD
14
1
7
10
8
16 17
SYNC DV+ V+
REF
20
4
V- A1
A0
3
DADJ
IIN
FADJ
MAX038
OUT
19
ROUT
50Ω
RF
OUTPUT
RPD
5
CPD
CF
PDI
COSC
PDO
13
12
GND GND GND GND GND DGND
2 6
9 11 18 15
EXTERNAL OSC INPUT
Figure 3. Phase-Locked Loop Using Internal Phase Detector
PDO is a rectangular current-pulse train, alternating
between 0µA and 500µA. It has a 50% duty cycle when
the MAX038 output and PDI are in phase-quadrature
(90° out of phase). The duty cycle approaches 100%
as the phase difference approaches 180° and conversely, approaches 0% as the phase difference
approaches 0°. The gain of the phase detector (KD)
can be expressed as:
[16]
KD = 0.318 x RPD (volts/radian)
where RPD = phase-detector gain-setting resistor.
When the loop is in lock, the input signals to the phase
detector are in approximate phase quadrature, the duty
cycle is 50%, and the average current at PDO is 250µA
(the current sink of FADJ). This current is divided
between FADJ and RPD; 250µA always goes into FADJ
and any difference current is developed across RPD,
creating VFADJ (both polarities). For example, as the
phase difference increases, PDO duty cycle increases,
the average current increases, and the voltage on RPD
(and V FADJ ) becomes more positive. This in turn
decreases the oscillator frequency, reducing the phase
difference, thus maintaining phase lock. The higher
RPD is, the greater VFADJ is for a given phase difference; in other words, the greater the loop gain, the less
the capture range. The current from PDO must also
The loop gain of the PLL system (KV) is:
KV = KD x KO
[19]
where:
KD = detector gain
KO = oscillator gain.
With a loop filter having a response F(s), the open-loop
transfer function, T(s), is:
T(s) = KD x KO x F(s) ÷ s
[20]
Using linear feedback analysis techniques, the closedloop transfer characteristic, H(s), can be related to the
open-loop transfer function as follows:
H(s) = T(s) ÷ [1+ T(s)]
[21]
The transient performance and the frequency response
of the PLL depends on the choice of the filter characteristic, F(s).
When the MAX038 internal phase detector is not used,
PDI and PDO should be connected to GND.
External Phase Detectors
External phase detectors may be used instead of the
internal phase detector. The external phase detector
shown in Figure 4 duplicates the action of the MAX038’s
internal phase detector, but the optional ÷N circuit can
be placed between the SYNC output and the phase
detector in applications requiring synchronizing to an
exact multiple of the external oscillator. The resistor network consisting of R4, R5, and R6 sets the sync range,
while capacitor C4 sets the capture range. Note that
this type of phase detector (with or without the ÷N circuit) locks onto harmonics of the external oscillator as
well as the fundamental. With no external oscillator
input, this circuit can be unpredictable, depending on
the state of the external input DC level.
Figure 4 shows a frequency phase detector that locks
onto only the fundamental of the external oscillator.
With no external oscillator input, the output of the frequency phase detector is a positive DC voltage, and
the oscillations are at the lowest frequency as set by
R4, R5, and R6.
______________________________________________________________________________________
13
MAX038
+5V -5V
MAX038
High-Frequency Waveform Generator
+5V
-5V
C1
1µF
C2
1µF
÷N
16
14
CENTER
FREQUENCY
17
20
SYNC DV+ V+
1
REF
4
V-
A1
A0
3
R2
CW
7
R3
PHASE DETECTOR
10
R4
8
R5
OFFSET
EXTERNAL
OSC INPUT
DADJ
MAX038
IIN
OUT
-5V
RF
OUTPUT
FADJ
R6
GAIN
5
R1
50Ω
19
PDI
COSC
PDO
13
12
GND GND GND GND GND DGND
2 6
9 11 18 15
C4
C3
CAPTURE FREQUENCY
Figure 4. Phase-Locked Loop Using External Phase Detector
+5V
-5V
C1
1µF
C2
1µF
÷N
14
CENTER
FREQUENCY
16
17
20
SYNC DV+ V+
1
REF
4
V-
A1
A0
3
R2
CW
7
R3
FREQUENCY PHASE DETECTOR
10
R4
EXTERNAL
OSC INPUT
8
R5
OFFSET
DADJ
IIN
-5V
C4
C3
CAPTURE FREQUENCY
OUT
19
PDI
COSC
PDO
13
12
GND GND GND GND GND DGND
2 6
9 11 18 15
Figure 5. Phase-Locked Loop Using External Frequency Phase Detector
14
R1
50Ω
RF
OUTPUT
FADJ
R6
GAIN
5
MAX038
______________________________________________________________________________________
28
8.192MHz
LD
N11
OSCOUT
OSCIN
N10
FIN
PD1OUT
VDD
VSS
RA0
1
0.1µF
3.3M
7
4
MAX427
0.1µF
33k
3
2
VDD
PDR
BIT7
PDV
BIT8
BIT6
3.3M
BIT9
BIT5
N8 MC145151 FV
N9
PDV
T/R
PDR
N12
RA2
RA1
N13
BIT10
BIT4
N0
BIT11
BIT3
N1
BIT2
33k
BIT12
N
N6
MX7541
N7
14
BIT1
N3
N2
GND
N4
N5
6
0.1µF
VREF
10
9
RFB
OUT2
35pF
20pF
512kHz
1.024MHz
2.048MHz
4.096MHz
8.192MHz
15
1kHz
2kHz
4kHz
8kHz
16kHz
32kHz
64kHz
128kHz
256kHz
OUT1
______________________________________________________________________________________
18
1
0.1µF
7.5k
10k
0.1µF
MAX412
+2.5V
3.33k
1
2N3904
±2.5V
0.1µF
2
0V TO 2.5V
3
8
35
pF
4
7
10
1
1N914
GND1
PDO
IIN
GND1
SYNC
DADJ
PDI
DGND
GND1
FADJ
DV+
COSC
V+
GND
A0
MAX038
OUT
GND1
A1
V-
VREF
2µA to
750µA
2N3906
WAVEFORM
SELECT
MAX412
2.7M
5
6
1k
11
20
0.1
µF
100
50.0
56pF
110pF
-5V
SYNC
OUTPUT
SIGNAL
OUTPUT
56pF
50Ω
FREQUENCY SYNTHESIZER 1kHz RESOLUTION; 8kHz TO 16.383MHz
0.1µF
0.1µF
50Ω, 50MHz
LOWPASS FILTER
220nH
220nH
+5V
MAX038
1k
High-Frequency Waveform Generator
Figure 6. Crystal-Controlled, Digitally Programmed Frequency Synthesizer—8kHz to 16MHz with 1kHz Resolution
15
MAX038
High-Frequency Waveform Generator
Layout Considerations
Realizing the full performance of the MAX038 requires
careful attention to power-supply bypassing and board
layout. Use a low-impedance ground plane, and connect all five GND pins directly to it. Bypass V+ and Vdirectly to the ground plane with 1µF ceramic capacitors or 1µF tantalum capacitors in parallel with 1nF
ceramics. Keep capacitor leads short (especially with
the 1nF ceramics) to minimize series inductance.
If SYNC is used, DV+ must be connected to V+, DGND
must be connected to the ground plane, and a second
1nF ceramic should be connected as close as possible
between DV+ and DGND (pins 16 and 15). It is not
necessary to use a separate supply or run separate
traces to DV+. If SYNC is disabled, leave DV+ open.
Do not open DGND.
Minimize the trace area around COSC (and the ground
plane area under COSC) to reduce parasitic capacitance, and surround this trace with ground to prevent
coupling with other signals. Take similar precautions
with DADJ, FADJ, and IIN. Place CF so its connection
to the ground plane is close to pin 6 (GND).
__________Applications Information
Frequency Synthesizer
Figure 6 shows a frequency synthesizer that produces
accurate and stable sine, square, or triangle waves with
a frequency range of 8kHz to 16.383MHz in 1kHz increments. A Motorola MC145151 provides the crystal-controlled oscillator, the ÷N circuit, and a high-speed phase
detector. The manual switches set the output frequency;
opening any switch increases the output frequency.
Each switch controls both the ÷N output and an
MX7541 12-bit DAC, whose output is converted to a current by using both halves of the MAX412 op amp. This
current goes to the MAX038 IIN pin, setting its coarse
frequency over a very wide range.
Fine frequency control (and phase lock) is achieved
from the MC145151 phase detector through the differential amplifier and lowpass filter, U5. The phase detec-
16
tor compares the ÷N output with the MAX038 SYNC
output and sends differential phase information to U5.
U5’s single-ended output is summed with an offset into
the FADJ input. (Using the DAC and the IIN pin for
coarse frequency control allows the FADJ pin to have
very fine control with reasonably fast response to switch
changes.)
A 50MHz, 50Ω lowpass filter in the output allows passage of 16MHz square waves and triangle waves with
reasonable fidelity, while stopping high-frequency noise
generated by the ÷N circuit.
___________________Chip Topography
GND
REF
V-
OUT
AO
GND
V+
A1
DV+
DGND
COSC
0.118"
(2.997mm)
SYNC
GND
DADJ
PDI
FADJ GND IIN
GND
0.106"
(2.692mm)
PDO
TRANSISTOR COUNT: 855
SUBSTRATE CONNECTED TO GND
______________________________________________________________________________________