LINER LTC6900

LTC6900
Low Power, 1kHz to 20MHz
Resistor Set SOT-23 Oscillator
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DESCRIPTIO
FEATURES
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One External Resistor Sets the Frequency
1kHz to 20MHz Frequency Range
500µA Typical Supply Current, VS = 3V, 3MHz
Frequency Error ≤1.5% Max, 5kHz to 10MHz
(TA = 25°C)
Frequency Error ≤ 2% Max, 5kHz to 10MHz
(TA = 0°C to 70°C)
±40ppm/°C Temperature Stability
0.04%/V Supply Stability
50% ±1% Duty Cycle 1kHz to 2MHz
50% ±5% Duty Cycle 2MHz to 10MHz
Fast Start-Up Time: 50µs to 1.5ms
100Ω CMOS Output Driver
Operates from a Single 2.7V to 5.5V Supply
Low Profile (1mm) ThinSOTTM Package
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APPLICATIO S
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Portable and Battery-Powered Equipment
PDAs
Cell Phones
Low Cost Precision Oscillator
Charge Pump Driver
Switching Power Supply Clock Reference
Clocking Switched Capacitor Filters
Fixed Crystal Oscillator Replacement
Ceramic Oscillator Replacement
The LTC6900 operates with a single 2.7V to 5.5V power
supply and provides a rail-to-rail, 50% duty cycle square
wave output. The CMOS output driver ensures fast rise/fall
times and rail-to-rail switching. The frequency-setting
resistor can vary from 10kΩ to 2MΩ to select a master
oscillator frequency between 100kHz and 20MHz (5V
supply). The three-state DIV input determines whether the
master clock is divided by 1, 10 or 100 before driving the
output, providing three frequency ranges spanning 1kHz
to 20MHz (5V supply). The LTC6900 features a proprietary
feedback loop that linearizes the relationship between
RSET and frequency, eliminating the need for tables to
calculate frequency. The oscillator can be easily programmed using the simple formula outlined below:
fOSC
100, DIV Pin = V +
 20k 

= 10MHz • 
 , N = 10, DIV Pin = Open
 N • RSET 
1, DIV Pin = GND

, LTC and LT are registered trademarks of Linear Technology Corporation.
ThinSOT is a trademark of Linear Technology Corporation.
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The LTC®6900 is a precision, low power oscillator that is
easy to use and occupies very little PC board space. The
oscillator frequency is programmed by a single external
resistor (RSET). The LTC6900 has been designed for high
accuracy operation (≤1.5% frequency error) without the
need for external trim components.
TYPICAL APPLICATIO
RSET vs Desired Output Frequency
10000
Clock Generator
1
0.1µF
2
10k ≤ RSET ≤ 2M
3
(
OUT
V+
LTC6900
1kHz ≤ fOSC ≤ 20MHz
5
5V, N = 100
GND
SET
20k
fOSC = 10MHz •
N • RSET
DIV
)
1000
4
OPEN, N = 10
N=1
RSET (kΩ)
5V
÷100
÷10
÷1
100
10
6900 TA01
1
1k
100k
1M
10M
10k
DESIRED OUTPUT FREQUENCY (Hz)
100M
6900 F02
6900f
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LTC6900
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PACKAGE/ORDER I FOR ATIO
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ABSOLUTE
RATI GS
(Note 1)
ORDER PART NUMBER
Supply Voltage (V +) to GND ........................– 0.3V to 6V
DIV to GND .................................... – 0.3V to (V + + 0.3V)
SET to GND ................................... – 0.3V to (V + + 0.3V)
Operating Temperature Range (Note 8)
LTC6900C .......................................... – 40°C to 85°C
LTC6900I ............................................ – 40°C to 85°C
Storage Temperature Range ................. – 65°C to 150°C
Lead Temperature (Soldering, 10 sec).................. 300°C
TOP VIEW
V+ 1
LTC6900CS5
LTC6900IS5
5 OUT
GND 2
SET 3
4 DIV
S5 PART MARKING
S5 PACKAGE
5-LEAD PLASTIC SOT-23
LTZM
TJMAX = 150°C, θJA = 256°C/W
Consult LTC Marketing for parts specified with wider operating temperature ranges.
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. V+ = 2.7V to 5.5V, RL= 5k, CL = 5pF, Pin 4 = V + unless otherwise noted.
All voltages are with respect to GND.
SYMBOL
∆f
PARAMETER
CONDITIONS
Frequency Accuracy (Notes 2, 3)
V+ = 5V
V+ = 3V
MIN
5kHz ≤ f ≤ 10MHz
5kHz ≤ f ≤ 10MHz, LTC6900C
5kHz ≤ f ≤ 10MHz, LTC6900I
1kHz ≤ f < 5kHz
10MHz < f ≤ 20MHz
5kHz ≤ f ≤ 10MHz
5kHz ≤ f ≤ 10MHz, LTC6900C
5kHz ≤ f ≤ 10MHz, LTC6900I
1kHz ≤ f < 5kHz
TYP
MAX
UNITS
±0.5
±1.5
±2.0
±2.5
%
%
%
%
%
±1.5
±2.0
±2.5
%
%
%
%
400
400
kΩ
kΩ
●
●
±2
±2
±0.5
●
●
±2
RSET
Frequency-Setting Resistor Range
∆f < 1.5%
∆f/∆T
Freq Drift Over Temp (Note 3)
RSET = 63.2k
●
±0.004
∆f/∆V
Freq Drift Over Supply (Note 3)
V+ = 3V to 5V, RSET = 63.2k
●
0.04
Timing Jitter (Note 4)
Pin 4 = V +, 20k ≤ R
V + = 5V
V + = 3V
20
20
SET ≤ 400k
Pin 4 = Open, 20k ≤ RSET ≤ 400k
Pin 4 = 0V, 20k ≤ RSET ≤ 400k
Long-Term Stability of Output Frequency
Duty Cycle (Note 7)
V+
IS
Pin 4 = V +
or Open (DIV Either by 100 or 10)
Pin 4 = 0V (DIV by 1), RSET = 20k to 400k
Operating Supply Range
Power Supply Current
RSET = 400k, Pin 4 =
fOSC = 5kHz
V +, R
L=∞
RSET = 20k, Pin 4 = 0V, RL = ∞
fOSC = 10MHz
V + = 5V
●
●
49
45
●
2.7
0.1
0.2
0.6
%
%
%
300
ppm/√kHr
50
50
51
55
%
%
5.5
V
●
●
0.32
0.29
0.42
0.38
mA
mA
V + = 5V
V + = 3V
●
●
0.92
0.68
1.20
0.86
mA
mA
High Level DIV Input Voltage
● V+ – 0.4
VIL
Low Level DIV Input Voltage
●
DIV Input Current (Note 5)
%/V
V + = 3V
VIH
IDIV
%/°C
0.1
Pin 4 = V +
V + = 5V
Pin 4 = 0V
V + = 5V
●
●
–4
V
2
–2
0.5
V
4
µA
µA
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LTC6900
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. V+ = 2.7V to 5.5V, RL= 5k, CL = 5pF, Pin 4 = V+ unless otherwise noted.
All voltages are with respect to GND.
SYMBOL
PARAMETER
CONDITIONS
VOH
High Level Output Voltage (Note 5)
V + = 5V
IOH = – 1mA
IOH = – 4mA
●
●
4.8
4.5
4.95
4.8
V
V
V + = 3V
IOH = – 1mA
IOH = – 4mA
●
●
2.7
2.2
2.9
2.6
V
V
V + = 5V
IOL = 1mA
IOL = 4mA
●
●
0.05
0.2
0.15
0.4
V
V
V + = 3V
IOL = 1mA
IOL = 4mA
●
●
0.1
0.4
0.3
0.7
V
V
V + = 5V
Pin 4 = V+ or Floating, RL = ∞
Pin 4 = 0V, RL = ∞
14
7
ns
ns
V + = 3V
Pin 4 = V+ or Floating, RL = ∞
Pin 4 = 0V, RL = ∞
19
11
ns
ns
V + = 5V
Pin 4 = V+ or Floating, RL = ∞
Pin 4 = 0V, RL = ∞
13
6
ns
ns
V + = 3V
Pin 4 = V+ or Floating, RL = ∞
Pin 4 = 0V, RL = ∞
19
10
ns
ns
VOL
tr
tf
Low Level Output Voltage (Note 5)
OUT Rise Time
(Note 6)
OUT Fall Time
(Note 6)
Note 1: Absolute Maximum Ratings are those values beyond which the life
of the device may be impaired.
Note 2: Frequencies near 100kHz and 1MHz may be generated using two
different values of RSET (see the Selecting the Divider Setting Resistor
paragraph in the Applications Information section). For these frequencies,
the error is specified under the following assumption: 20k < RSET ≤ 200k.
Note 3: Frequency accuracy is defined as the deviation from the
fOSC equation.
Note 4: Jitter is the ratio of the peak-to-peak distribution of the period to
the mean of the period. This specification is based on characterization and
is not 100% tested. Also, see the Peak-to-Peak Jitter vs Output Frequency
curve in the Typical Performance Characteristics section.
Note 5: To conform with the Logic IC Standard convention, current out of
a pin is arbitrarily given as a negative value.
MIN
TYP
MAX
UNITS
Note 6: Output rise and fall times are measured between the 10% and
90% power supply levels. These specifications are based on
characterization.
Note 7: Guaranteed by 5V test.
Note 8: The LTC6900C is guaranteed to meet specified performance from
0°C to 70°C. The LTC6900C is designed, characterized and expected to
meet specified performance from – 40°C to 85°C but is not tested or QA
sampled at these temperatures. The LTC6900I is guaranteed to meet
specified performance from – 40°C to 85°C.
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LTC6900
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TYPICAL PERFOR A CE CHARACTERISTICS
Frequency Variation Over
Temperature
Frequency Variation vs RSET
4
1.00
TA = 25°C
GUARANTEED LIMITS APPLY OVER
20kΩ ≤ RSET ≤ 400kΩ
2
0.75
VARIATION (%)
0
–1
0.9
0.8
0.50
TYPICAL HIGH
1
1.0
RSET = 63.4k
÷1 OR ÷10 OR ÷100
TYPICAL LOW
–2
0.25
0
TYPICAL
LOW
–0.25
÷1, VA = 5V
0.7
TYPICAL
HIGH
JITTER (%P-P)
3
VARIATION (%)
Peak-to-Peak Jitter vs Output
Frequency
0.6
÷1, VA = 3V
0.5
0.4
0.3
–0.50
÷10
0.2
–3
–0.75
–4
10k
1k
100k
RSET (Ω)
1M
–1.00
–40
–20
0
20
40
60
TEMPERATURE (°C)
80
6900 G01
140
OUTPUT RESISTANCE (Ω)
SUPPLY CURRENT (mA)
÷1, 5V
1.5
÷10, 5V
÷100, 5V
1.0
0.5
0
1k
10k
100k
1M
OUTPUT FREQUENCY (Hz)
10M
6900 G03
Output Resistance
vs Supply Voltage
2.0
÷100, 3V
0
6900 G02
Supply Current vs Output
Frequency
TA = 25°C
CL = 5pF
÷100
0.1
LTC6900 Output Operating at
20MHz, VS = 5V
V + = 5V, RSET = 10k, CL = 10pF
TA = 25°C
120
OUTPUT SOURCING CURRENT
1V/DIV
100
80
0V
60
÷10, 3V ÷1, 3V
12.5ns/DIV
6900 G06
OUTPUT SINKING CURRENT
40
0
1k
10k
100k
1M
OUTPUT FREQUENCY (Hz)
2.5
10M
3.0
3.5 4.0 4.5
5.0
SUPPLY VOLTAGE (V)
6900 G04
5.5
6.0
6900 G05
LTC6900 Output Operating at
10MHz, VS = 3V
V + = 3V, RSET = 20k, CL = 10pF
1V/DIV
0V
25ns/DIV
6900 G07
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LTC6900
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PI FU CTIO S
V+ (Pin 1): Voltage Supply (2.7V ≤ V+ ≤ 5.5V). This supply
must be kept free from noise and ripple. It should be
bypassed directly to a ground plane with a 0.1µF capacitor.
GND (Pin 2): Ground. Should be tied to a ground plane for
best performance.
SET (Pin 3): Frequency-Setting Resistor Input. The value
of the resistor connected between this pin and V+ determines the oscillator frequency. The voltage on this pin is
held by the LTC6900 to approximately 1.1V below the V+
voltage. For best performance, use a precision metal film
resistor with a value between 10kΩ and 2MΩ and limit the
capacitance on this pin to less than 10pF.
DIV (Pin 4): Divider-Setting Input. This three-state input
selects among three divider settings, determining the
value of N in the frequency equation. Pin 4 should be tied
to GND for the ÷1 setting, the highest frequency range.
Floating Pin 4 divides the master oscillator by 10. Pin 4
should be tied to V+ for the ÷100 setting, the lowest
frequency range. To detect a floating DIV pin, the LTC6900
attempts to pull the pin toward midsupply. Therefore,
driving the DIV pin high requires sourcing approximately
2µA. Likewise, driving DIV low requires sinking 2µA.
When Pin 4 is floated, it should preferably be bypassed by
a 1nF capacitor to ground or it should be surrounded by a
ground shield to prevent excessive coupling from other
PCB traces.
OUT (Pin 5): Oscillator Output. This pin can drive 5kΩ
and/or 10pF loads. Heavier loads may cause inaccuracies
due to supply bounce at high frequencies. Voltage transients, coupled into Pin 5, above or below the LTC6900
power supplies will not cause latchup if the current into/
out of the OUT pin is limited to 50mA.
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BLOCK DIAGRA
VRES = (V+ – VSET) = 1.1V TYPICALLY
1
RSET
V+
+
GAIN = 1
IRES
3
SET
PROGRAMMABLE
DIVIDER (N)
(÷1, 10 OR 100)
–
OUT
V
5
+
MASTER OSCILLATOR
ƒMO = 10MHz • 20kΩ •
IRES
(V + – VSET)
DIVIDER
SELECT
+
–
2µA
VBIAS
2 GND
IRES
DIV
THREE-STATE
INPUT DETECT
+
–
4
2µA
GND
6900 BD
PATENT PENDING
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LTC6900
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THEORY OF OPERATIO
As shown in the Block Diagram, the LTC6900’s master
oscillator is controlled by the ratio of the voltage between
the V+ and SET pins and the current (IRES) is entering the
SET pin. The voltage on the SET pin is forced to approximately 1.1V below V+ by the PMOS transistor and its gate
bias voltage. This voltage is accurate to ±8% at a particular
input current and supply voltage (see Figure 1).
A resistor RSET, connected between the V+ and SET pins,
“locks together” the voltage (V + – VSET) and current, IRES,
variation. This provides the LTC6900’s high precision. The
master oscillation frequency reduces to:
 20kΩ 
ƒ MO = 10MHz • 

 RSET 
The LTC6900 is optimized for use with resistors between
10k and 2M, corresponding to master oscillator frequencies between 100kHz and 20MHz.
To extend the output frequency range, the master oscillator signal may be divided by 1, 10 or 100 before driving
OUT (Pin 5). The divide-by value is determined by the state
of the DIV input (Pin 4). Tie DIV to GND or drive it below
0.5V to select ÷1. This is the highest frequency range, with
the master output frequency passed directly to OUT. The
DIV pin may be floated or driven to midsupply to select
÷10, the intermediate frequency range. The lowest frequency range, ÷100, is selected by tying DIV to V+ or
driving it to within 0.4V of V+. Figure 2 shows the relationship between RSET, divider setting and output frequency,
including the overlapping frequency ranges near 100kHz
and 1MHz.
The CMOS output driver has an on resistance that is
typically less than 100Ω. In the ÷1 (high frequency) mode,
the rise and fall times are typically 7ns with a 5V supply and
11ns with a 3V supply. These times maintain a clean
square wave at 10MHz (20MHz at 5V supply). In the ÷10
and ÷100 modes, where the output frequency is much
lower, slew rate control circuitry in the output driver
increases the rise/fall times to typically 14ns for a 5V
supply and 19ns for a 3V supply. The reduced slew rate
lowers EMI (electromagnetic interference) and supply
bounce.
10000
1.4
1.3
1000
RSET (kΩ)
VRES = V + – VSET
V + = 5V
÷100
1.2
V + = 3V
1.1
÷10
÷1
100
1.0
10
0.9
0.8
0.1
1
10
IRES (µA)
100
1000
6900 F01
Figure 1. V + – VSET Variation with IRES
1
1k
10k
100k
1M
10M
DESIRED OUTPUT FREQUENCY (Hz)
100M
6900 F02
Figure 2. RSET vs Desired Output Frequency
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LTC6900
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APPLICATIO S I FOR ATIO
SELECTING THE DIVIDER SETTING AND RESISTOR
The LTC6900’s master oscillator has a frequency range
spanning 0.1MHz to 20MHz. However, accuracy may
suffer if the master oscillator is operated at greater than
10MHz with a supply voltage lower than 4V. A programmable divider extends the frequency range to greater than
three decades. Table 1 describes the recommended frequencies for each divider setting. Note that the ranges
overlap; at some frequencies there are two divider/resistor
combinations that result in the desired frequency.
In general, any given oscillator frequency (fOSC) should be
obtained using the lowest master oscillator frequency.
Lower master oscillator frequencies use less power and
are more accurate. For instance, fOSC = 100kHz can be
obtained by either RSET = 20k, N = 100, master oscillator
= 10MHz or RSET = 200k, N = 10, master oscillator = 1MHz.
The RSET = 200k approach is preferred for lower power and
better accuracy.
Table 1. Frequency Range vs Divider Setting
DIVIDER SETTING
÷1
⇒
DIV (Pin 4) = GND
÷10
⇒
DIV (Pin 4) = Floating
÷100 ⇒
FREQUENCY RANGE
DIV (Pin 4) = V+
ALTERNATIVE METHODS OF SETTING THE OUTPUT
FREQUENCY OF THE LTC6900
The oscillator may be programmed by any method that
sources a current into the SET pin (Pin 3). The circuit in
Figure 3 sets the oscillator frequency using a programmable current source and in the expression for fOSC, the
resistor RSET is replaced by the ratio of 1.1V/ICONTROL. As
already explained in the “Theory of Operation,” the voltage
difference between V + and SET is approximately 1.1V,
therefore, the Figure 3 circuit is less accurate than if a
resistor controls the oscillator frequency.
Figure 4 shows the LTC6900 configured as a VCO. A
voltage source is connected in series with an external 20k
resistor. The output frequency, fOSC, will vary with
VCONTROL, that is the voltage source connected between
V + and the SET pin. Again, this circuit decouples the
relationship between the input current and the voltage
between V + and SET; the frequency accuracy will be
degraded. The oscillator frequency, however, will monotonically increase with decreasing VCONTROL.
> 500kHz*
182kHz TO 18MHz (TYPICALLY ±8%)
50kHz to 1MHz
V+
< 100kHz
*At master oscillator frequencies greater than 10MHz (R
SET
< 20kΩ), the
LTC6900 may experience reduced accuracy with a supply voltage less than
4V.
After choosing the proper divider setting, determine the
correct frequency-setting resistor. Because of the linear
correspondence between oscillation period and resistance, a simple equation relates resistance with frequency.
100
 10MHz 
RSET = 20k • 
 , N = 10
 N • fOSC 
1
(RSETMIN = 10k, RSETMAX = 2M)
Any resistor, RSET, tolerance adds to the inaccuracy of the
oscillator, fOSC.
ICONTROL
1µA TO 100µA
1
0.1µF
2
3
V+
OUT
LTC6900
5
GND
SET
DIV
4
N=1
6900 F03
ƒOSC ≅ 10MHz • 20kΩ • ICONTROL
N
1.1V
ICONTROL EXPRESSED IN (A)
Figure 3. Current Controlled Oscillator
V+
VCONTROL
0V TO 1.1V
+
–
1
0.1µF
RSET
20k
2
3
5
OUT
V+
LTC6900
GND
SET
4
DIV
N=1
(
6900 F04
ƒOSC ≅ 10MHz • 20k • 1 – VCONTROL
N
RSET
1.1V
)
TYPICAL fOSC ACCURACY
±0.5%, VCONTROL = 0V
±8%, VCONTROL = 0.5V
Figure 4. Voltage Controlled Oscillator
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LTC6900
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APPLICATIO S I FOR ATIO
POWER SUPPLY REJECTION
START-UP TIME
Low Frequency Supply Rejection (Voltage Coefficient)
The start-up time and settling time to within 1% of the final
value can be estimated by tSTART ≅ RSET(3.7µs/kΩ) +
10µs. Note the start-up time depends on RSET and it is
independent from the setting of the divider pin. For instance with RSET = 100k, the LTC6900 will settle with 1%
of its 200kHz final value (N = 10) in approximately 380µs.
Figure 6 shows start-up times for various RSET resistors.
Figure 5 shows the output frequency sensitivity to power
supply voltage at several different temperatures. The
LTC6900 has a guaranteed voltage coefficient of 0.1%/V
but, as Figure 5 shows, the typical supply sensitivity is
twice as low.
High Frequency Power Supply Rejection
The accuracy of the LTC6900 may be affected when its
power supply generates significant noise with a frequency
content in the vicinity of the programmed value of fOSC. If
a switching power supply is used to power the LTC6900,
and if the ripple of the power supply is more than 20mV,
make sure the switching frequency and its harmonics are
not related to the output frequency of the LTC6900.
Otherwise, the oscillator may show additional frequency
error.
If the LTC6900 is powered by a switching regulator and the
switching frequency or its harmonics coincide with the
output frequency of the LTC6900, the jitter of the oscillator
output may be affected. This phenomenon will become
noticeable if the switching regulator exhibits ripples beyond 30mV.
The start-up time and settling time of the LTC6900 with
switch S1 open (or closed) is described by tSTART shown
above. Once the LTC6900 starts and settles, and switch S1
closes (or opens), the LTC6900 will settle to its new output
frequency within approximately 70µs.
Jitter
The Peak-to-Peak Jitter vs Output Frequency graph, in the
Typical Performance Characteristics section, shows the
typical clock jitter as a function of oscillator frequency and
power supply voltage. The capacitance from the SET pin,
(Pin 3), to ground must be less than 10pF. If this requirement is not met, the jitter will increase.
70
RSET = 63.2k
PIN 4 = FLOATING (÷10)
0.10
25°C
–40°C
0.05
TA = 25°C
V+ = 5V
60
FREQUENCY ERROR (%)
FREQUENCY DEVIATION (%)
0.15
Figure 7 shows an application where a second set resistor
RSET2 is connected in parallel with set resistor RSET1 via
switch S1. When switch S1 is open, the output frequency
of the LTC6900 depends on the value of the resistor RSET1.
When switch S1 is closed, the output frequency of the
LTC6900 depends on the value of the parallel combination
of RSET1 and RSET2.
85°C
0
50
40
30
20
400k
10
63.2k
0
–0.05
2.5
3.0
3.5
4.0
4.5
SUPPLY VOLTAGE (V)
5.0
5.5
–10
20k
0
200
400
800
600
TIME AFTER POWER APPLIED (µs)
6900 F05
Figure 5. Supply Sensitivity
1000
6900 F06
Figure 6. Start-Up Time
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LTC6900
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APPLICATIO S I FOR ATIO
3V OR 5V
S1
RSET1
1
2
RSET2
V+
OUT
5
fOSC = 10MHz •
OR
LTC6900
V+
GND
3
SET
DIV
4
fOSC = 10MHz •
÷100
(
(
)
20k
N • RSET1
20k
N • RSET1//RSET2
)
÷10
÷1
6900 F07
Figure 7
A Ground Referenced Voltage Controlled Oscillator
The LTC6900 output frequency can also be programmed
by steering current in or out of the SET pin, as conceptually
shown in Figure 8. This technique can degrade accuracy as
the ratio of (V+ – VSET) / IRES is no longer uniquely
dependent of the value of RSET, as shown in the LTC6900
Block Diagram. This loss of accuracy will become noticeable when the magnitude of IPROG is comparable to IRES.
The frequency variation of the LTC6900 is still monotonic.
When VIN = V+, the output frequency of the LTC6900
assumes the highest value and it is set by the parallel
combination of RIN and RSET. Also note, the output frequency, fOSC, is independent of the value of VRES = (V+ –
VSET) so the accuracy of fOSC is within the data sheet limits.
When VIN is less than V+, and expecially when VIN approaches the ground potential, the oscillator frequency,
fOSC, assumes its lowest value and its accuracy is affected
by the change of VRES = (V+ – VSET). At 25°C VRES varies
by ±8%, assuming the variation of V+ is ±5%. The temperature coefficient of VRES is 0.02%/°C.
By manipulating the algebraic relation for fOSC above, a
simple algorithm can be derived to set the values of
external resistors RSET and RIN, as shown in Figure 9.
1. Choose the desired value of the maximum oscillator
frequency, fOSC(MAX), occurring at maximum input voltage VIN(MAX) ≤ V+.
Figure 9 shows how to implement the concept shown in
Figure 8 by connecting a second resistor, RIN, between the
SET pin and a ground referenced voltage source, VIN.
2. Set the desired value of the minimum oscillator frequency, fOSC(MIN), occurring at minimum input voltage
VIN(MIN) ≥ 0.
For a given power supply voltage in Figure 9, the output
frequency of the LTC6900 is a function of VIN, RIN, RSET
and (V+ – VSET) = VRES:
3. Choose VRES = 1.1 and calculate the ratio of RIN/RSET
from the following:
fOSC =
RIN
=
RSET
10MHz
20k
•
•
N
RIN RSET





VIN − V + 
1 
1 +

•
RIN  
VRES


 1+

 RSET  
(
)
1
V+
0.1µF
2
RSET
V+
OUT
IPR
(1)
5
5V
DIV
1
V+
+
GND
SET
IRES
 ( fOSC(MAX) ) 
VRES 
− 1

 fOSC(MIN)
LTC6900
3

(MAX)
+
(VIN(MAX) − V + ) −  ffOSC
 (VIN(MIN) − V )

OSC(MIN)
4
÷100
VRES
÷10
RIN
OPEN
÷1
6900 F08
Figure 8. Concept for Programming via Current Steering
RSET
2
V+
VIN
OUT
5
fOSC
LTC6900
5V
GND
3
SET
+
–
–
0.1µF
− 1 (2)
DIV
4
÷100
÷10
OPEN
÷1
6900 F09
Figure 9. Implementation of Concept Shown in Figure 8
6900f
9
LTC6900
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APPLICATIO S I FOR ATIO
Example 2:
Once RIN/RSET is known, calculate RSET from:
RSET
Vary the oscillator frequency by one octave per volt.
Assume fOSC(MIN) = 1MHz and fOSC(MAX) = 2MHz, when the
input voltage varies by 1V. The minimum input voltage is
half supply, that is VIN(MIN) = 1.5V, VIN(MAX) = 2.5V and
V+ = 3V.
10MHz
20k
=
•
•
N
fOSC(MAX)


RIN  
+

 VIN(MAX) − V + VRES  1 +
 RSET  



 R 
VRES  IN 


 RSET 


(
)
(3)
Example 1:
In this example, the oscillator output frequency has small
excursions. This is useful where the frequency of a system
should be tuned around some nominal value.
V+
= 3V, fOSC(MAX) = 2MHz for VIN(MAX) = 3V and
Let
fOSC(MIN) = 1.5MHz for VIN = 0V. Solve for RIN/RSET by
Equation (2), yielding RIN/RSET = 9.9/1. RSET = 110.1k by
Equation (4). RIN = 9.9RSET = 1.089M. For standard
resistor values, use RSET = 110k (1%) and RIN = 1.1M
(1%). Figure 10 shows the measured fOSC vs VIN. The
1.5MHz to 2MHz frequency excursion is quite limited, so
the curve of fOSC vs VIN is linear.
Equation (2) yields RIN/RSET = 1.273 and Equation (3)
yields RSET = 142.8k. RIN = 1.273RSET = 181.8k. For
standard resistor values, use RSET = 143k (1%) and RIN =
182k (1%). Figure 11 shows the measured fOSC vs VIN. For
VIN higher than 1.5V, the VCO is quite linear; nonlinearities
occur when VIN becomes smaller than 1V, although the
VCO remains monotonic.
Maximum VCO Modulation Bandwidth
The maximum VCO modulation bandwidth is 25kHz; that
is, the LTC6900 will respond to changes in VIN at a rate up
to 25kHz. In lower frequency applications however, the
modulation frequency may need to be limited to a lower
rate to prevent an increase in output jitter. This lower limit
is the master oscillator frequency divided by 20, (fOSC/20).
In general, for minimum output jitter the modulation
frequency should be limited to fOSC/20 or 25kHz, whichever is less. For best performance at all frequencies, the
value for fOSC should be the master oscillator frequency
(N␣ = 1) when VIN is at the lowest level.
2.00
3000
1.95
2500
1.90
RIN = 1.1M
RSET = 110k
V + = 3V
N=1
1.80
2000
fOSC (kHz)
fOSC (MHz)
1.85
1.75
1.70
1500
RIN = 182k
RSET = 143k
V + = 3v
N=1
1000
1.65
1.60
500
1.55
1.50
0
0
0.5
1
1.5
VIN (V)
2
2.5
3
6900 F10
Figure 10. Output Frequency vs Input Voltage
0
0.5
1
1.5
VIN (V)
2
2.5
3
6900 F11
Figure 11. Output Frequency vs Input Voltage
6900f
10
LTC6900
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APPLICATIO S I FOR ATIO
Maximum modulation bandwidth is the lesser of 25kHz or
fOSC(MIN)/20 calculated at N =1 (2MHz/20 = 100kHz)
Example 3:
V+ = 3V, fOSC(MAX) = 5MHz, fOSC(MIN) = 4MHz, N = 1
Maximum VIN modulation frequency = 25kHz
VIN(MAX) = 2.5V, VIN(MIN) = 0.5V
RIN/RSET = 8.5, RSET = 43.2k, RIN = 365k
Table 2. Variation of VRES for Various Values of RIN || RSET
RIN || RSET (VIN = V +)
VRES, V + = 3V
VRES, V + = 5V
20k
0.98V
1.03V
40k
1.03V
1.08V
Maximum VIN modulation frequency = 25kHz
80k
1.07V
1.12V
Example 4:
160k
1.1V
1.15V
V+ = 3V, fOSC(MAX) = 400kHz, fOSC(MIN) = 200kHz, N = 10
320k
1.12V
1.17V
Maximum modulation bandwidth is the lesser of 25kHz or
fOSC(MIN)/20 (4MHz/20 = 200kHz)
VRES = Voltage across RSET
VIN(MAX) = 2.5V, VIN(MIN) = 0.5V
Note: All of the calculations above assume VRES = 1.1V, although VRES ≈ 1.1V. For completeness,
Table 2 shows the variation of VRES against various parallel combinations of RIN and RSET
(VIN = V +). Calulate first with VRES ≈ 1.1V, then use Table 2 to get a better approximation of VRES,
then recalculate the resistor values using the new value for VRES.
RIN/RSET = 3.1, RSET = 59k, RIN = 182k
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PACKAGE DESCRIPTIO
S5 Package
5-Lead Plastic TSOT-23
(Reference LTC DWG # 05-08-1635)
0.62
MAX
0.95
REF
2.90 BSC
(NOTE 4)
1.22 REF
3.85 MAX 2.62 REF
1.4 MIN
2.80 BSC
1.50 – 1.75
(NOTE 4)
PIN ONE
RECOMMENDED SOLDER PAD LAYOUT
PER IPC CALCULATOR
0.30 – 0.45 TYP
5 PLCS (NOTE 3)
0.95 BSC
0.80 – 0.90
0.20 BSC
0.01 – 0.10
1.00 MAX
DATUM ‘A’
0.30 – 0.50 REF
0.09 – 0.20
(NOTE 3)
NOTE:
1. DIMENSIONS ARE IN MILLIMETERS
2. DRAWING NOT TO SCALE
3. DIMENSIONS ARE INCLUSIVE OF PLATING
4. DIMENSIONS ARE EXCLUSIVE OF MOLD FLASH AND METAL BURR
5. MOLD FLASH SHALL NOT EXCEED 0.254mm
6. JEDEC PACKAGE REFERENCE IS MO-193
1.90 BSC
S5 TSOT-23 0302
6900f
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights.
11
LTC6900
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TYPICAL APPLICATIO S
Temperature-to-Frequency Converter
5V
RT
100k
THERMISTOR
1
C1
0.1µF
2
3
OUT
V+
LTC6900
5
fOSC = 10MHz • 20k
10
RT
GND
SET
DIV
4
6900 TA02
RT: YSI 44011 800 765-4974
Output Frequency vs Temperature
1400
MAX
TYP
MIN
FREQUENCY (kHz)
1200
1000
800
600
400
200
0
–20 –10 0 10 20 30 40 50 60 70 80 90
TEMPERATURE (°C)
6900 TA03
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
LTC1799
1kHz to 30MHz ThinSOT Oscillator
Identical Pinout, Higher Frequency Operation
6900f
12
Linear Technology Corporation
LT/TP 0902 2K • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com
 LINEAR TECHNOLOGY CORPORATION 2002