LTC1264
High Speed, Quad Universal
Filter Building Block
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FEATURES
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DESCRIPTIO
High Speed, Up to 250kHz Center Frequency
Four Identical Filters in a 0.3" Wide Package
Clock-to-Center Frequency Ratio of 20:1
Double-Sampling, Improved Aliasing
Operates from ±2.37V to ±8V Power Supplies
Customized Version with Internal Resistors Available
Low Noise
Low Harmonic Distortion
Available in 24-Pin DIP and SO Wide Packages
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APPLICATIO S
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The LTC ®1264 consists of four identical, high speed 2nd
order switched-capacitor filter building blocks designed
for center frequencies up to 250kHz. Each building block,
together with three to five resistors, can provide 2nd order
functions like lowpass, highpass, bandpass and notch.
The center frequency of each 2nd order section is tuned via
an external clock. The clock-to-center frequency ratio is
internally set to 20:1, but it can be modified via external
resistors.
The aliasing performance of the LTC1264 is improved by
double-sampling each 2nd order section. Input signal
frequencies can reach up to twice the clock frequency
before any alias products will be detectable.
Digital Communications
Spread Spectrum Communications
Spectral Analysis
Loran Receivers
Instrumentation
For Q ≤ 5 and for TA < 85°C, the maximum center
frequency is 160kHz. For Q ≤ 2, the maximum center
frequency is 250kHz. Up to 8th order filters can be realized
by cascading all four 2nd order sections.
, LTC and LT are registered trademarks of Linear Technology Corporation.
All other trademarks are the property of their respective owners.
A customized monolithic version of the LTC1264 including internal thin film resistors can be obtained.
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TYPICAL APPLICATIO
Clock-Tunable 8th Order Bandpass Filter, fCENTER = fCLK /20
50k
Gain vs Frequency
100kHz Bandpass, f –3dB Bandwidth = fCENTER/10
50k
IN
INV B
INV C
10k
10k
HPB/NB
HPC/NC
10
50k
50k
BPC
0
LPB
LPC
–10
SC
–20
SB
LTC1264
V–
AGND
V+
0.1µF
GAIN (dB)
MAXIMUM POWER
fCENTER SUPPLY
160kHz
±7.5V
120kHz
±5V
60kHz
Single 5V
BPB
CLK
SA
SD
LPA
LPD
0.1µF
fCLK
BPA
BPD
HPA/NA
HPD/ND
INV A
–40
–50
OUT
50k
10k
–30
–60
–70
50k
–80
10k
10k
INV D
100k
FREQUENCY (Hz)
1M
1264 TA02
50k
50k
1264 TA01
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LTC1264
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RATI GS
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AXI U
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(Note 1)
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ABSOLUTE
PACKAGE/ORDER I FOR ATIO
TOP VIEW
Total Supply Voltage (V + to
V –) .............................. 16V
Input Voltage (Note 2) ........... (V + + 0.3V) to (V – – 0.3V)
Output Short-Circuit Duration .......................... Indefinite
Power Dissipation ............................................. 400mW
Burn-In Voltage ...................................................... 16V
Operating Temperature Range ............... – 40°C to 85°C
Storage Temperature Range ................ – 65°C to 150°C
Lead Temperature (Soldering, 10 sec).................. 300°C
INV B
1
24 INV C
HPB/NB
2
23 HPC/NC
BPB
3
22 BPC
LPB
4
21 LPC
SB
5
20 SC
AGND
6
19
V–
V+
7
18 CLK
SA
8
17 SD
LPA
9
16 LPD
BPA 10
15 BPD
HPA/NA 11
ORDER PART
NUMBER
LTC1264CN
LTC1264CSW
14 HPD/ND
INV A 12
13 INV D
N PACKAGE
SW PACKAGE
24-LEAD PLASTIC DIP 24-LEAD PLASTIC SO (WIDE)
TJMAX = 110°C, θJA = 65°C/W (N)
TJMAX = 110°C, θJA = 85°C/W (S)
Order Options Tape and Reel: Add #TR
Lead Free: Add #PBF Lead Free Tape and Reel: Add #TRPBF
Lead Free Part Marking: http://www.linear.com/leadfree/
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.(Internal Op Amps) TA = 25°C, unless otherwise noted.
PARAMETER
Operating Supply Range
Voltage Swings
CONDITIONS
MIN
±2.375
VS = ±2.375V, RL = 5k
VS = ±5V, RL = 5k
●
±3.2
±3.1
VS = ±7.5, RL = 5k
TYP
MAX
±8
UNITS
V
V
V
V
V
mA
dB
MHz
V/µs
MAX
UNITS
kHz
kHz
kHz
± 0.7
±0.8
±0.8
±1.0
%
%
%
%
%
%
%
%
%
ppm/°C
ppm/°C
±1.5
±3.7
±6
3
80
7
10
Output Short-Circuit Current (Source/Sink)
DC Open-Loop Gain
GBW Product
Slew Rate
(Complete Filter) VS = ±5V, fCLK = 1MHz, all sides mode 1, fO = 50kHz, Q = 5, TA = 25°C, unless otherwise noted.
PARAMETER
Center Frequency Range, fO (Note 2)
Clock-to-Center Frequency Ratio, fCLK /fO
Center Frequency Error (Note 4)
CONDITIONS
VS = ±7.5V, TA < 85°C, Q < 2
VS = ±5V, TA < 85°C, Q < 2
VS = ±2.5V, TA < 85°C, Q < 2
MIN
VS = ±7.5V
TYP
0.1 - 250
0.1 - 200
0.1 - 100
20:1
±0.1
●
VS = ±5V
±0.2
●
Clock-to-Center Frequency Ratio,
Side-to-Side Matching
Q Accuracy
VS = ±2.375V
VS ≥ ±5V
– 1.6
0.4
●
VS = ±5V
– 2.7
●
fO Temperature Coefficient
Q Temperature Coefficient
fCLK < 2MHz
fCLK < 2MHz
0.8
1.0
7.0
±1
5
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LTC1264
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. (Complete Filter) VS = ±5V, fCLK = 1MHz, all sides mode 1, fO = 50kHz,
Q = 5, unless otherwise noted.
PARAMETER
DC Offset Voltage (Note 3)
CONDITIONS
VOS1 (DC Offset of Input Inverter)
VOS2 (DC Offset of First Integrator)
VOS3 (DC Offset of Second Integrator)
VS = ±7.5V (fCLK is a Square Wave)
VS = ±5V (fCLK is a Square Wave)
VS = ±2.375V (fCLK is a Square Wave)
VS = ±7.5V, TA = 25°C
VS = ±5V
Clock Feedthrough
Maximum Clock Frequency
Power Supply Current
MIN
TYP
9
160
120
90
6
14
●
●
●
MAX
±20
±45
±45
●
Note 1: Absolute Maximum Ratings are those values beyond which the life
of a device may be impaired.
Note 2: Please refer to Typical Maximum Q vs Clock Frequency graphs.
Note 3: Calculations of output DC offsets of one 2nd order section. Also
see Block Diagram.
VOSN
PINS 2, 11, 14, 23
MODE
23
26
UNITS
mV
mV
mV
µVRMS
µVRMS
µVRMS
MHz
mA
mA
Note 4: The center frequency fO, error is calculated as:
fO(measured) – fO(ideal)
• 100
fO (ideal)
VOSBP
PINS 3, 10, 15, 22
VOSLP
PINS 4, 9, 16, 21
1
VOS1[(1Q) + 1 ||HOLP ||] – VOS3 /Q
VOS3
VOSN – VOS2
1b
VOS1[(1/Q) + 1 + R2/R1] – VOS3 /Q
VOS3
≈(VOSN – VOS2)(1 + R5/R6)
2
[VOS1(1 + R2/R1 + R2/R3 + R2/R4) – VOS3(R2/R3)]
• [R4/(R2 + R4)] + VOS2[R2/(R2 + R4)]
VOS3
VOSN – VOS2
3
VOS2
VOS3
VOS1[1 + R4/R1 + R4/R2 + R4/R3] – VOS2(R4/R2)
– VOS3(R4/R3)
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TYPICAL PERFOR A CE CHARACTERISTICS
A
VS = ±7.5V
TA ≤ 85°C
A. MODES 1, 1b
B. MODES 3, 3a
B
1.5
2.0
2.5 3.0 3.5
4.0 4.5
CLOCK FREQUENCY (MHz)
5.0
1264 G01
26
24
22
20
18
16
14
12
10
8
6
4
2
0
A
Typical Maximum Q
vs Clock Frequency
20
VS = ±5V
TA ≤ 85°C
A
18
VS = SINGLE 5V
TA ≤ 85°C
16
A. MODES 1, 1b
B. MODES 3, 3a
TYPICAL MAXIMUM Q
26
24
22
20
18
16
14
12
10
8
6
4
2
0
Typical Maximum Q
vs Clock Frequency
TYPICAL MAXIMUM Q
TYPICAL MAXIMUM Q
Typical Maximum Q
vs Clock Frequency
B
A. MODES 1, 1b
B. MODES 3, 3a
14
12
10
B
8
6
4
2
1.0
1.5
3.0
2.5
2.0
3.5
CLOCK FREQUENCY (MHz)
4.0
0
1.0
1.2
1.6
1.8
1.4
CLOCK FREQUENCY (MHz)
2.0
1264 G02
1264 G03
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LTC1264
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TYPICAL PERFOR A CE CHARACTERISTICS
Typical Bandpass Gain Error
vs Clock Frequency
VS = ±5V
2
VS = ±7.5V
1
2.4
3.2
3.6
2.8
CLOCK FREQUENCY (MHz)
4
MODE 1
Q=4
TA = 25°C
VS = ±5V
3
2
VS = ±7.5V
1
0
2.0
4.0
TYPICAL BNADPASS GAIN ERROR (dB)
3
0
2.0
5
5
MODE 1
Q=2
TA = 25°C
TYPICAL BANDPASS GAIN ERROR (dB)
TYPICAL BANDPASS GAIN ERROR (dB)
5
4
Typical Bandpass Gain Error
vs Clock Frequency
Typical Bandpass Gain Error
vs Clock Frequency
2.4
3.2
3.6
2.8
CLOCK FREQUENCY (MHz)
1264 G04
3
Q=4
2
Q=2
1
0
1.3
4.0
1.4
1.7 1.8 1.9
1,5 1.6
CLOCK FREQUENCY (MHz)
Ratio (fCLK /fO) vs
Clock Frequency
5
20.5
VS = ±5V
MODE 3
Q=4
TA = 25°C
4
BANDPASS OUT
MODE 1
VS = ±7.5V
20.4
20.3
20.2
VS = SINGLE 5V
fCLK /fO
3
VS = ±7.5V
2
Q = 10
20.1
Q=4
20.0
19.9
19.8
1
Q=2
19.7
19.6
0
2
1
3
4
19.5
1
CLOCK FREQUENCY (MHz)
2
3
4
CLOCK FREQUENCY (MHz)
1264 G15
1264 G11
Power Supply Current
vs Supply Voltage
Noise vs R2/R4 Ratio
600
48
MODE 3
VS = ±7.5V
Q=2
f
R2
fO = CLK
20 R4
400
44
POWER SUPPLY CURRENT (mA)
500
NOISE (µVRMS)
2.0
1264 G06
1264 G05
Typical Bandpass Gain Error
vs Clock Frequency
TYPICAL BANDPASS GAIN ERROR (dB)
4
MODE 1
VS = SINGLE 5V
TA = 25°C
300
200
100
40
36
32
28
24
–55°C
25°C
125°C
20
16
12
8
4
0
0
0.2
0.4
0.6
0.8
RESISTOR RATIO (R2/R4)
1.0
1264 G12
0
0 2
4 6 8 10 12 14 16 18 20 22 24
POWER SUPPLY VOLTAGE (V+ – V –)
1264 G14
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LTC1264
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PI FU CTIO S
V +, V – (Pins 7, 19): Power Supply Pins. The V + (Pin 7) and
the V – (Pin 19) should each be bypassed with a 0.1µF
capacitor to an adequate analog ground. The filter’s power
supplies should be isolated from other digital or high
voltage analog supplies. A low noise linear supply is
recommended. Using a switching power supply will lower
the signal-to-noise ratio of the filter. The supply during
power-up should have a slew rate less than 1V/µs. When
V + is applied before V – and V – is allowed to go above
ground, a diode should clamp V – to prevent latch-up.
Figures 1 and 2 show typical connections for dual and
single supply operation.
ANALOG
GROUND
PLANE
1
24
2
23
3
22
AGND (Pin 6): Analog Ground Pin. The filter performance
depends on the quality of the analog signal ground. For
either dual or single supply operation, an analog ground
plane surrounding the package is recommended. The
analog ground plane should be connected to any digital
ground at a single point. For dual supply operation, Pin 6
should be connected to the analog ground plane. For
single supply operation, Pin 6 should be biased at 1/2
supply and should be bypassed to the analog ground plane
with at least a 1µF capacitor (Figure 2). For single 5V
operation and fCLK greater than 1MHz, pin 6 should be
biased at 2V. This minimizes passband gain and phase
variations.
ANALOG
GROUND
PLANE
1
24
2
23
3
22
4
21
*5
20*
–7.5V
4
7.5V
0.1µF
21
5
20
6
19
7
LTC1264
*
V
0.1µF
5k
+
V +/2 6
+
18
1µF
5k
V+
7
19
LTC1264
18
17
*8
17*
9
16
9
16
10
15
10
15
11
14
11
14
12
13
12
13
8
STAR
SYSTEM
GROUND
DIGITAL
GROUND
PLANE
STAR
SYSTEM
GROUND
200Ω
200Ω
CLOCK
SOURCE
CLOCK
SOURCE
* OPTIONAL, 1N4148, 1N5819
DIGITAL
GROUND
PLANE
1264 F01
* FOR MODE 3, THE S NODE PINS 5, 8,
1264 F02
17, 20 SHOULD BE TIED TO PIN 6
Figure 1. Dual Supply Ground Plane Connections
Figure 2. Single Supply Ground Plane Connections
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LTC1264
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PI FU CTIO S
CLK (Pin 18): Clock Input Pin. Any TTL or CMOS clock
source with a square wave output and 50% duty cycle
(±10%) is an adequate clock source for the device. The
power supply for the clock source should not be the filter’s
power supply. The analog ground for the filter should be
connected to clock’s ground at a single point only. Table
1 shows the clock’s low and high level threshold values for
a dual or single supply operation.
Table 1. Clock Source High and Low Threshold Levels
POWER SUPPLY
Dual Supply = ±7.5V
Dual Supply = ±5V
Dual Supply = ±2.5V
Single Supply = 12V
Single Supply = 5V
HIGH LEVEL
≥ 2.18V
≥ 1.45V
≥ 0.73V
≥ 7.80V
≥ 1.45V
LOW LEVEL
≤ 0.5V
≤ 0.5V
≤ – 2.0V
≤ 6.5V
≤ 0.5V
HPB/NB, BPB, LPB, LPA, BPA, HPA, HPD, BPD, LPD,
LPC, BPC, HPC/NC (Pins 2, 3, 4, 9, 10, 11, 14, 15, 16,
21, 22, 23): Output Pins. Each 2nd order section of the
LTC1264 has three outputs which typically source 3mA
and sink 1mA. Driving coaxial cables or resistive loads less
than 20k will degrade the total harmonic distortion performance of any filter design. When evaluating the distortion
or noise performance of a particular filter design implemented with an LTC1264, the final output of the filter
should be buffered with a wideband noninverting high
slew rate amplifier (Figure 3).
–
5k
A pulse generator can be used as a clock source provided
the high level on-time is greater than 0.2µs. Sine waves are
not recommended for clock input frequencies less than
100kHz, since excessively slow clock rise or fall times
generate internal clock jitter (maximum clock rise or fall
time ≤ 1µs). The clock signal should be routed from the
right side of the IC package and perpendicular to it to avoid
coupling to any input or output analog signal path. A 200Ω
resistor between clock source and Pin 11 will slow down
the rise and fall times of the clock to further reduce charge
coupling (Figures 1 and 2).
LT1224
+
1264 F03
Figure 3. Wideband Buffer
INV B, INV A, INV D, INV C (Pins 1, 12, 13, 24): Inverting
Input Pins. These pins are the high impedance inverting
inputs of internal op amps and they are susceptible to stray
capacitive connections to low impedance signal outputs
and power supply lines.
SB, SA, SD, SC (Pins 5, 8, 17, 20): Summing Input Pins.
The summing pins connections determine the circuit
topology (mode) of each 2nd order section. Please refer to
Modes of Operation.
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ODES OF OPERATIO
For the definition of filter functions please refer to the
LTC1060 data sheet.
Mode 1
In Mode 1, the ratio of the external clock frequency to the
center frequency of each 2nd order section is internally
fixed at 20:1. Figure 4 illustrates Mode 1 providing 2nd
order notch, lowpass, and bandpass outputs. Mode 1 can
be used to make high order Butterworth lowpass filters; it
can also be used to make low Q notches and for cascading
2nd order bandpass functions tuned at the same center
frequency. Mode 1 is faster than Mode 3.
Please refer to the Maximum Frequency of Operation
paragraph under Applications Information for a guide to
the use of capacitor CC.
Mode 1b
Mode 1b is derived from Mode 1. In Mode 1b (Figure 5) two
additional resistors R5 and R6 are added to alternate the
amount of voltage fed back from the lowpass output into
the input of the SA (SB, SC or SD) switched-capacitor
summer. This allows the filter’s clock-to-center frequency
ratio to be adjusted beyond 20:1. Mode 1b maintains the
speed advantages of Mode 1 and should be considered an
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LTC1264
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ODES OF OPERATIO
optimum mode for high Q designs with fCLK to fCUTOFF (or
fCENTER) ratios greater than 20:1.
Please refer to the Maximum Frequency of Operation
paragraph under Applications Information for a guide to
the use of capacitor CC.
CC
R3
R2
N
VIN
R1
–
S
+
Σ
LP
BP
–
∫
+
∫
Please refer to the Maximum Frequency of Operation
paragraph under Applications Information for a guide to
the use of capacitor CC.
Mode 2 is a combination of Mode 1 and Mode 3, shown in
Figure 7. With Mode 2, the clock-to-center frequency ratio,
fCLK /fO, is always less than 20:1. The advantage of Mode
2 is that it provides less sensitivity to resistor tolerances
than does Mode 3. As in Mode 1, Mode 2 has a notch
output which depends on the clock frequency, and the
notch frequency is therefore less than the center frequency, fO.
f
fi = CLK ; fO = fi; fn = fO
20
R2
R3
R3
Q=
;H =–
;H
=–
R1 OBP
R1
R2 ON
HOLP = HON
Figure 4. Mode 1, 2nd Order Filter Providing Notch,
Bandpass and Lowpass Outputs
Please refer to the Maximum Frequency of Operation
paragraph under Applications Information for a guide to
the use of capacitor CC.
CC
R6
In Mode 3, the ratio of the external clock frequency to the
center frequency of each 2nd order section can be
adjusted above or below 20:1. Figure 6 illustrates Mode 3,
the classical state variable configuration, providing highpass, bandpass, and lowpass 2nd order filter functions.
Mode 3 is slower than Mode 1. Mode 3 can be used to
make high order all-pole bandpass, lowpass, and highpass filters.
Mode 2
1264 F04
1/4 LTC1264
AGND
Mode 3
R5
CC
R3
R4
R2
N
VIN
R1
S
LP
BP
R3
–
+
+
Σ
–
∫
R2
∫
HP
1264 F05
1/4 LTC1264
VIN
NOTE: R5 ≤ 5k
AGND
√
f
R6
fi = CLK ; fO = fi
;f =f
20
(R6 + R5) n O
R3
R6 ; H = – R2 ; H
Q = R3
=–
R1 OBP
R1
R2 (R6 + R5) ON
R2 R6 + R5
HOLP = –
R6
R1
√
R1
(
)
Figure 5. Mode 1b, 2nd Order Filter Providing Notch,
Bandpass and Lowpass Outputs
–
+
AGND
f
fi = CLK ; fO = fi
20
+
S
Σ
–
LP
BP
∫
∫
1264 F06
1/4 LTC1264
1
R3 R2
R2
R3
√ R4 ; Q = 1.005( R2) √ R4 ( 1 – 6.42•R4
)
R3
HOHP = – R2 ; HOBP = –
R1
R1
(
1–
1
R3
6.42•R4
)
; HOLP = –
R4
R1
Figure 6. Mode 3, 2nd Order Section Providing
Highpass, Bandpass and Lowpass Outputs
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LTC1264
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ODES OF OPERATIO
CC
R4
R3
R2
N
VIN
R1
–
S
+
+
Σ
LP
BP
–
∫
∫
Please refer to the Maximum Frequency of Operation
paragraph under Applications Information for a guide to
the use of capacitor CC.
1264 F07
1/4 LTC1264
AGND
fi =
fCLK
;f =f
20 O i
√ 1 + R4 ; f = f
R2
n
O
Mode 2n
( ) √ 1 + R2R4 1 – 1R3
( 6.42•R4 )
R3
Q = 1.005
R2
HOHP = –
R2
(AC GAIN, f > fn); HOHPn = – R2
R1
R1
HOBP = –
R3
R1
(
1–
1
R3
6.42•R4
)
tors RH and RL to create a notch. This is shown in Figure
8. Mode 3a is more versatile than Mode 2 because the
notch frequency can be higher or lower than the center
frequency of the 2nd order section. The external op amp
of Figure 8 is not always required. When cascading the
sections of the LTC1264, the highpass and lowpass
outputs can be summed directly into the inverting input of
the next section.
(
1
1 + R2
R4
)
(DC GAIN, f < fn)
; HOLP = HOHPn
Figure 7. Mode 2, 2nd Order Filter Providing Highpass
Notch, Bandpass and Lowpass Outputs
Mode 3a
This is an extension of Mode 3 where the highpass and
lowpass output are summed through two external resis-
This mode extends the circuit topology of Mode 3a to
Mode 2 (Figure 9) where the highpass notch and lowpass
outputs are summed through two external resistors RH
and RL to create a lowpass output with a notch higher in
frequency than the notch in Mode 2. This mode, shown in
Figure 8, is most useful in lowpass elliptic designs. When
cascading the sections of the LTC1264, the highpass
notch and lowpass outputs can be summed directly into
the inverting input of the next section.
Please refer to the Maximum Frequency of Operation
paragraph under Applications Information for a guide to
the use of capacitor CC.
CC
R3
R2
HP
VIN
R1
–
+
S
Σ
–
+
LP
BP
OHPn
∫
RG
∫
RL
1/4 LTC1264
AGND
R
√ R f = f √ R4
1
R2
Q = 1.005 ( R3)
R2 √ R4
R3
1
–
( 6.42•R4
)
R
R
H
(f = ∞) = ( )( R2 ) ; H
(f = 0) = ( )( R4 )
R R1
R R1
f
fi = CLK ; fn = fi
20
R4
–
RH
+
H
R2
; O
i
L
G
H
OLPn
G
L
HIGHPASS
OR LOWPASS
NOTCH OUTPUT
EXTERNAL OP AMP OR
INPUT OP AMP OF THE
LTC1264, SIDES A, B, C, D
1264 G08
Figure 8. Mode 3a, 2nd Order Filter Providing a Highpass Notch or Lowpass Notch Output
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LTC1264
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ODES OF OPERATIO
CC
√
R3
R2
HP
VIN
R1
√
f
fi = CLK ; fn = fi 1 + RH
20
RL
R2
fO = fi
1+
R4
R
R
HOLPn (f = 0)= G + G R2
RH RL R1
R4
–
+
+
S
Σ
–
LP
BP
∫
RG
∫
RL
( R3R2) √ 1 + R2R4
Q = 1.005
–
+
1/4 LTC1264
)( ) (
(
1–
1
1 + R2
R4
)
1
R3
6.42•R4
)
LOWPASS
NOTCH
OUTPUT
RH
AGND
(
EXTERNAL OP AMP OR
INPUT OP AMP OF THE
LTC1264, SIDES A, B, C, D
1264 G09
Figure 9. Mode 2n, 2nd Order Filter Providing a Lowpass Notch Output
W
BLOCK DIAGRA
INV A 12
AGND 6
HPA/NA
BPA
LPA
11
10
9
–
+
+
+∫
8
SA
–
+
+
Σ
5
SB
+
+
–
+
19
V–
Σ
LPC
+∫
21
+∫
–
20
SC
HPD/ND
14
INV D 13
CLK
+∫
BPC
22
23
–
18
LPB
4
BPB
3
+∫
V+
–
HPC/NC
INV C 24
+∫
–
HPB/NB
2
INV B 1
Σ
7
+
Σ
LPD
BPD
15
+∫
16
+∫
–
17
SD
1264 BD
1264fb
9
LTC1264
U
W
U
UO
APPLICATI
S I FOR ATIO
Operating Limits
The Typical Maximum Q vs Clock Frequency and Bandpass Gain Error graphs, under Typical Performance Characteristics, define an upper limit of operating Q for each
LTC1264 2nd order section. These graphs indicate the
power supply, fCLK and Q value conditions under which a
filter implemented with an LTC1264 will remain stable
when operated at temperatures of 85°C or less. For a 2nd
order section, a bandpass gain error of 3dB or less is
arbitrarily defined as a condition for stability.
When the passband gain error begins to exceed 1dB, the
use of capacitor CC will reduce the gain error (capacitor CC
is connected from the lowpass node to the inverting node
of a 2nd order section). Please refer to Figures 4 through
9. The value of CC can be best determined experimentally,
and as a guide it should be about 5pF for each 1dB of gain
error and not to exceed 15pF. When operating LTC1264
very near the limits defined by the Typical Performance
Characteristics graphs, passband gain variations of 2dB
or more should be expected.
Speed Limitations
To avoid op amp slew rate limiting, the signal amplitude
should be kept below a specified level as shown in Table 2.
Table 2. Maximum VIN vs VS and Clock
VS
±7.5V
±5V
Single 5V
MAXIMUM CLOCK
4MHz to 5MHz
3MHz to 4MHz
1MHz to 2MHz
MAXIMUM VIN
0.5VRMS fIN ≥ 400kHz
0.5VRMS fIN ≥ 250kHz
0.35VRMS fIN ≥ 160kHz
feedthrough specifications. Switching transients have frequency contents much higher than the applied clock; their
amplitude strongly depends on scope probing techniques
as well as grounding and power supply bypassing. The
clock feedthrough, if bothersome, can be greatly reduced
by adding a simple RC lowpass network at the final filter
output. This RC will completely eliminate any switching
transients.
Wideband Noise
The wideband noise of the filter is the total RMS value of
the device’s noise spectral density and it is used to
determine the operating signal-to-noise ratio. Most of its
frequency contents lie within the filter passband and it
cannot be reduced with post filtering.
The total wideband noise (µVRMS) is nearly independent of
the value of the clock. The clock feedthrough specifications are not part of the wideband noise.
For a specific filter design, the total noise depends on the
Q of each section and the cascade sequence. Table 3
shows typical 2nd order section noise (gain = 1) for Q
values and supplies operating at 25°C. Noise increases by
20% at the highest operating temperatures.
Table 3. 2nd Order Section Noise (µVRMS) for Modes 1, 1b,
2 or 3 (R2 = R4)
Q
1
2
3
4
5
VS = ±2.5V
40µVRMS
50µVRMS
60µVRMS
75µVRMS
90µVRMS
VS = ±5V
50
60
75
90
110
VS = ±7.5V
60
75
95
115
135
Clock Feedthrough
Clock feedthrough is defined as the RMS value of the clock
frequency and its harmonics that are present at the filter’s
output pins. The clock feedthrough is tested with the
filter’s input grounded and it depends on PC board layout
and on the value of the power supplies. With proper layout
techniques, the typical values of clock feedthrough are
listed under Electrical Characteristics.
Any parasitic switching transients during the rise and fall
edges of the incoming clock are not part of the clock
Aliasing
Aliasing is an inherent phenomenon of switched-capacitor
filters and it occurs when the frequency of input signals
approaches the sampling frequency. The input signals
that produce the strongest aliased components have a
frequency, fIN, such as (fSAMPLING – fIN) falls into the
filter’s passband. For the LTC1264 the sampling frequency is twice fCLK. If the input signal spectrum is not
band-limited, aliasing may occur.
1264fb
10
LTC1264
U
W
U
UO
APPLICATI
S I FOR ATIO
For example, for an LTC1264 bandpass filter with fCENTER
= 100kHz and fCLK = 2MHz, a 3.9MHz, 10mV input will
produce a 100kHz, 10mV output. A 1st or 2nd order
prefilter will reduce aliasing to acceptable levels in most
cases.
Table 4. Bandpass Design Specifications (fCENTER is center
frequency of passband.)
A GUIDE TO BANDPASS DESIGN
Note: Reducing passband ripple or attenuation will decrease Q values. The
filter order may also increase.
Filter design tools like FCAD require design specification
inputs such as passband ripple, attenuation, passband
width and stopband width in order to calculate filter
parameters fO, Q, fn or poles and zeroes. The results of
these filter approximations most often require Q values
which make excessive demands on the gain-bandwidth
products of active filter realizations. The active filter designer should define a gain response so that the filter’s
mathematical approximation has practical requirements.
Table 4 is a guide to practical design specifications for
realizing bandpass filters with LTC1264 (please also refer
to the Typical Maximum Q vs Clock Frequency and Bandpass Gain Error graphs under Typical Performance Characteristics).
PASSBAND
RIPPLE
(dB)
≤ 3dB for Butterworth
≤ 0.1 for Chebyshev
PASSBAND
WIDTH
(Hz)
≥ fCENTER /20
≥ fCENTER /20
STOPBAND
ATTENUWIDTH
ATION
(Hz)
(dB)
≥ 5 × Passband –40 to –60
≥ 5 × Passband –40 to –60
Table 5. Calculated Filter Parameters
STAGE
fO
1
2
3
4
38.1201kHz
41.9726kHz
35.6418kHz
44.8911kHz
Q
4.3346
4.3346
10.5221
10.5221
Table 6. Calculated Mode 1b Resistors to Nearest 1% Value
Using Table 5 Filter Parameters and Figure 10 Equations
STAGE
1
2
3
4
R1
52.3k
47.5k
56.2k
44.2k
R2
10k
10k
10k
10k
R3
56.2k
51.1k
147k
118k
R5
5k
5k
5k
5k
R6
6.98k
11.8k
5.11k
20.5k
A Bandpass Design Example
Filter Type:
Filter Response:
Passband Ripple:
Attenuation:
Center Frequency:
Passband Width:
Stopband Width:
Bandpass
Butterworth
3dB
60dB
40kHz (fCENTER)
10kHz
60kHz
R2 = 10k
R5 = 5k
f
fi = CLK
20
R1 = R3 (FOR BANDPASS)
HOBP
2
R6 =
HOBP =
Implementing the Bandpass Design
R3 =
With the LTC1264 in Mode 1b, Butterworth and Chebyshev
bandpass designs with fCLK to fCENTER ratios greater than
20:1 are possible.
R5•fO
( fi
2
√
2
– fO
Q
2
(
)
fO
fCENTER
) (
–
fCENTER
fO
)
2
+1
R2•Q
√(
R6
R6 + 5
)
1264 F10
Figure 10. Equations for Resistors in Mode 1b Operation
First choose the clock frequency which in Mode 1b must
be greater than 20 times the bandpass center frequency of
40kHz. For this example, let’s choose fCLK to be 1MHz.
Table 6 lists the resistors for for the bandpass design
example and Figure 11 shows the complete circuit.
1264fb
11
LTC1264
W
U
U
UO
APPLICATI
S I FOR ATIO
R1
R1
INV B
INV C
R2
R2
HPB/NB
HPC/NC
R3
R3
STAGE 1
R5
R6
R6
R5
STAGE 3
R3
BPB
BPC
LPB
LPC
R5
SB
LTC1264
SC
V–
AGND
V+
CLK
SA
SD
LPA
LPD
BPA
BPD
HPA/NA
fCLK
R6
R6
1.0
0.5
0
R5
–0.5
STAGE 4
R3
HPD/ND
R2
R2
INV A
R1
STAGE 2
INV D
R1
GAIN (dB)
IN
first stage and decreasing the R1 resistor of the last stage
by the same amount (multiplying the R1 resistor of the
first stage and dividing the R1 resistor of the last stage by
2 for narrowband filter, and by 5 for wideband filter is a
good rule of thumb). This adjustment may, however,
increase the filter’s passband noise.
OUT
MODE 1b
VS = ±7.5V
fCLK = 1MHz
fCLK /fCENTER = 25:1
–1.0
–1.5
–2.0
–2.5
–3.0
1264 F11
–3.5
–4.0
Figure 11. Mode 1b Bandpass Filter
30 32 34 36 38 40 42 44 46 48 50
FREQUENCY (kHz)
1264 F12
The sequence of 2nd order stages and the bandpass gain
HOBP of each stage will determine the gain peaks at the
filter’s intermediate outputs. A given internal output can
have several dB more gain than the final filter output. Gain
peaks occur around the corners of the passband. The gain
peaks can be reduced by increasing the R1 resistor of the
Figure 12. Passband Gain vs Frequency
40kHz Butterworth Bandpass
10
0
–10
–20
GAIN (dB)
Figures 12 and 13 show the gain response graphs of the
40kHz Butterworth bandpass design described above. The
passband gain response graph (Figure 12) shows a 40kHz
gain of – 0.4dB and a tilted passband from 37kHz to 43kHz.
These errors are due to the 1% resistors used and the sideto-side matching of the LTC1264 fCLK-to-fCENTER ratio
which typically is 0.4%. To adjust for 0dB gain at 40kHz,
reduce the value of R1 in the first stage by 5%. To adjust
for a flat passband, adjust by ±1% the value of R6 in stages
3 and 4. Adjusting R6 compensates for the side-to-side
matching errors. Please refer to Figure 5 equations defining fO and Q as a function of R6.
MODE 1b
VS = ±7.5V
fCLK = 1MHz
fCLK /fCENTER = 25:1
–30
–40
–50
–60
–70
–80
–90
10 18 26 34 42 50 58 66 74 82 90
FREQUENCY (kHz)
1264 F13
Figure 13. Gain vs Frequency
40kHz Butterworth Bandpass
1264fb
12
LTC1264
UO
TYPICAL APPLICATI
S
Gain vs Frequency
Linear Phase Clock-Tunable to 400kHz, Dual 4th Order Lowpass Filter
R1
0
R1
OUT 1
IN 1
INV B
–10
INV C
R2
R2
HPB/NB
HPC/NC
R3
–20
R3
BPB
BPC
LPB
LPC
R4
GAIN (dB)
R4
C
C
SB
0.1µF
SC
LTC1264
V–
AGND
V+
8V
C
SD
LPA
LPD
C
–70
–80
10k
R4
R3
100k
FREQUENCY (Hz)
BPD
R3
R2
HPA/NA
R2
INV A
IN 2
INV D
OUT 2
R1
C
B
2
2
17.8k 20k
27.4k 27.4k
19.6k 21k
51.1k 75k
5pF
5pF
A
2
17.8k
27.4k
19.6k
51.1k
5pF
D
2
20k
27.4k
21k
75k
5pF
f –3dB (VS = ±8V)
125kHz
200kHz
275kHz
400kHz
fCLK
2MHz
3MHz
4MHz
5MHz
TA ≤ 50°C
1264 TA04a
Clock-Tunable, fCENTER = fCLK /20, 100kHz, 4th Order Bandpass and Notch Filters
Gain vs Frequency
R1
10
R1
BANDPASS IN
INV B
0
INV C
R2
R2
HPB/NB
R3
BPB
BPC
LPB
LPC
SB
BANDPASS OUT
SC
LTC1264
V–
AGND
7.5V
–20
V+
CLK
SA
SD
LPA
LPD
– 7.5V
0.1µF
fCLK
2MHz
NOTCH OUT
BPD
R2
R2
C
–40
–50
–60
R3
HPA/NA
–30
–70
R3
BPA
GAIN (dB)
0.1µF
R1
–10
HPC/NC
R3
NOTCH IN
1M
1264 TA04b
HPD/ND
R1
LTC1264 SIDE
MODE
R1
R2
R3
R4
C
–50
–60
0.1µF
fCLK
R4
BPA
–40
–8V
CLK
SA
–30
VS = ±7.5V
fCLK = 2MHz
–80
10k
100k
FREQUENCY (Hz)
1M
1264 TA05b
HPD/ND
INV A
C
INV D
R1
LTC1264 SIDE
MODE
R1
R2
R3
C
B
1
20k
10k
20k
C
1
20k
10k
20k
A
1
10k
10k
20k
10pF
D
1
10k
10k
20k
10pF
1264 TA05a
1264fb
13
LTC1264
UO
TYPICAL APPLICATI
S
100kHz, 8th Order Notch Filter, fCLK /fCENTER = 20:1
Gain vs Frequency
R1
10
0
C
R1
INV B
INV C
R2
R2
HPB/NB
HPC/NC
R3
0.1µF
–20
R3
BPB
BPC
LPB
LPC
SB
SC
LTC1264
V+
CLK
SA
SD
LPA
LPD
–30
–40
–50
V–
AGND
7.5V
–10
GAIN (dB)
IN
–7.5V
R3
–60
0.1µF
fCLK
2MHz
VS = ±7.5V
fCLK = 2MHz
–70
–80
10k
OUT
R3
BPA
100k
FREQUENCY (Hz)
1M
1264 TA06b
BPD
R2
R2
HPA/NA
LTC1264 SIDE
MODE
R1
R2
R3
C
HPD/ND
INV A
INV D
C
R1
R1
C
B
1
1
36.5k 3.92k
10k
10k
50k 27.4k
30pF
D
1
9.09k
10k
50k
30pF
A
1
7.5k
10k
50k
1264 TA06a
Clock-Tunable, 8th Order Elliptic Lowpass Filter, fCLK /fCUTOFF = 20:1
Gain vs Frequency
RL
0
RH
INV B
INV C
R2
–20
R2
HPB/NB
HPC/NC
R3
R3
BPB
BPC
LPB
LPC
GAIN (dB)
IN
R4
R4
C
0.1µF
SB
LTC1264
7.5V
C
V+
–30
–40
–50
SC
V–
AGND
VS = ±7.5V
fCLK = 2MHz
–10
R1
–70
CLK
SA
SD
LPA
LPD
BPA
BPD
–60
–7.5V
0.1µF
RL
RH
–80
10k
fCLK
2MHz
R4
R4
R3
100k
FREQUENCY (Hz)
1M
1264 TA03b
R3
R2
HPA/NA
HPD/ND
R2
INV A
INV D
OUT
RH
RL
1264 TA03a
POWER SUPPLY
±7.5V
±5V
SINGLE 5V
MAXIMUM fCLK
3.6MHz (C = 10pF)
2.0MHz (C = 10pF)
1.6MHz (C = 10pF)
LTC1264 SIDE
MODE
R1
R2
R3
R4
RH
RL
C
C
B
2n
3a
27.4k
23.7k 20k
20k 37.4k
28k 100k
137k 100k
27.4k 31.6k
3pF
A
2n
D
3
20k
37.4k
100k
130k
24.3k
3pF
29.4k
19.1k
48.7k
1264fb
14
LTC1264
U
PACKAGE DESCRIPTIO
N Package
24-Lead PDIP (Narrow .300 Inch)
(Reference LTC DWG # 05-08-1510)
1.280*
(32.512)
MAX
24
23
22
21
20
19
18
17
16
15
14
13
1
2
3
4
5
6
7
8
9
10
11
12
.255 ± .015*
(6.477 ± 0.381)
.300 – .325
(7.620 – 8.255)
.130 ± .005
(3.302 ± 0.127)
.045 – .065
(1.143 – 1.651)
.020
(0.508)
MIN
.008 – .015
(0.203 – 0.381)
(
+.035
.325 –.015
8.255
+0.889
–0.381
.065
(1.651)
TYP
N24 0405
.120
(3.048)
MIN
)
.018 ± .003
(0.457 ± 0.076)
.100
(2.54)
BSC
NOTE:
1. DIMENSIONS ARE
INCHES
MILLIMETERS
*THESE DIMENSIONS DO NOT INCLUDE MOLD FLASH OR PROTRUSIONS.
MOLD FLASH OR PROTRUSIONS SHALL NOT EXCEED .010 INCH (0.254mm)
SW Package
24-Lead Plastic Small Outline (Wide .300 Inch)
(Reference LTC DWG # 05-08-1620)
.050 BSC .045 ±.005
.030 ±.005
TYP
N
24
23
22
21
.598 – .614
(15.190 – 15.600)
NOTE 4
20 19 18 17 16
15
14
13
N
.325 ±.005
.420
MIN
.394 – .419
(10.007 – 10.643)
NOTE 3
1
2
3
N/2
N/2
RECOMMENDED SOLDER PAD LAYOUT
.005
(0.127)
RAD MIN
.009 – .013
(0.229 – 0.330)
.291 – .299
(7.391 – 7.595)
NOTE 4
.010 – .029 × 45°
(0.254 – 0.737)
2
3
4
5
6
7
8
9
10
11
.093 – .104
(2.362 – 2.642)
12
.037 – .045
(0.940 – 1.143)
0° – 8° TYP
NOTE 3
.016 – .050
(0.406 – 1.270)
NOTE:
1. DIMENSIONS IN
1
.050
(1.270)
BSC
.004 – .012
(0.102 – 0.305)
.014 – .019
(0.356 – 0.482)
TYP
INCHES
(MILLIMETERS)
2. DRAWING NOT TO SCALE
3. PIN 1 IDENT, NOTCH ON TOP AND CAVITIES ON THE BOTTOM OF PACKAGES ARE THE MANUFACTURING OPTIONS.
THE PART MAY BE SUPPLIED WITH OR WITHOUT ANY OF THE OPTIONS
4. THESE DIMENSIONS DO NOT INCLUDE MOLD FLASH OR PROTRUSIONS.
MOLD FLASH OR PROTRUSIONS SHALL NOT EXCEED .006" (0.15mm)
S24 (WIDE) 0502
1264fb
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.
15
LTC1264
UO
TYPICAL APPLICATI
8th Order Bandpass Filter, Linear Phase
RH
RL
R1
VIN
INV B
LTC1264 SIDE
MODE
R1
R2
R3
R4
RH
RL
INV C
R2
R2
HPB/NB
HPC/NC
R3
R3
BPB
BPC
R4
R4
LPB
LPC
C
0.1µF
SB
SC
LTC1264
V–
AGND
7.5V
V+
CLK
SA
SD
LPA
LPD
BPA
BPD
1MHz
–7.5V
0.1µF
fCLK
1MHz
1.5MHz
2.0MHz
R4
R4
C
B
3
3a
97.6k
10.7k 12.4k
39.2k 39.2k
13.3k 10.7k
53.6
15.0k
D
3
10.0k
29.4k
10.0k
27.4k
100.0k
C
0pF
5pF
10pF
R3
R3
A
3a
32.4k
10.7k
12.4k
11.5k
1264 TA07a
R2
R2
HPA/NA
HPD/ND
INV A
INV D
VOUT
RH
R1
RL
50kHz Bandpass Filter, Linear Phase
Gain vs Frequency
Passband Gain and Group Delay
10
3
VS = ±7.5V
fCLK = 1MHz
0
124
114
GAIN
–10
–3
104
–20
–6
94
GAIN (dB)
–30
–40
–9
84
DELAY
–12
74
–15
64
–60
–18
54
–70
–21
44
–80
–24
34
–90
10k
–27
–50
100k
FREQUENCY (Hz)
1M
1264 TA07b
40 42 44 46 48 50 52 54 56 58 60
FREQUENCY (kHz)
GROUP DELAY (µs)
GAIN (dB)
0
24
1264 TA07c
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1264fb
16
Linear Technology Corporation
LT/LT 0805 REV B • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com
© LINEAR TECHNOLOGY CORPORATION 1993