LINER LTC1068IN

LTC1068 Series
Clock-Tunable, Quad
Second Order, Filter Building Blocks
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DESCRIPTIO
FEATURES
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The LTC®1068 product family consists of four monolithic
clock-tunable filter building blocks. Each product contains
four matched, low noise, high accuracy 2nd order switchedcapacitor filter sections. An external clock tunes the center
frequency of each 2nd order filter section. The LTC1068
products differ only in their clock-to-center frequency
ratio. The clock-to-center frequency ratio is set to 200:1
(LTC1068-200), 100:1 (LTC1068), 50:1 (LTC1068-50) or
25:1 (LTC1068-25). External resistors can modify the
clock-to-center frequency ratio. High performance, quad
2nd order, dual 4th order or 8th order filters can be
designed with an LTC1068 family product. Designing
filters with an LTC1068 product is fully supported by
FilterCADTM filter design software for Windows®.
Four Identical 2nd Order Filter Sections in an
SSOP Package
2nd Order Section Center Frequency Error:
±0.3% Typical and ±0.8% Maximum
Low Noise per 2nd Order Section, Q ≤ 5:
LTC1068-200 50µVRMS, LTC1068 50µVRMS
LTC1068-50 75µVRMS, LTC1068-25 90µVRMS
Low Power Supply Current: 4.5mA, Single 5V,
LTC1068-50
Operation with ±5V Power Supply, Single 5V
Supply or Single 3.3V Supply
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APPLICATI
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Lowpass or Highpass Filters:
LTC1068-200, 0.5Hz to 25kHz; LTC1068, 1Hz to
50kHz; LTC1068-50, 2Hz to 50kHz; LTC1068-25,
4Hz to 200kHz
Bandpass or Bandreject (Notch) Filters:
LTC1068-200, 0.5Hz to 15kHz; LTC1068, 1Hz to
30kHz; LTC1068-50, 2Hz to 30kHz; LTC1068-25,
4Hz to 140kHz
The LTC1068 products are available in a 28-pin SSOP
surface mount package. A customized version of an
LTC1068 family product can be obtained in a 16-lead SO
package with internal thin-film resistors. Please contact
LTC Marketing for details.
, LTC and LT are registered trademarks of Linear Technology Corporation.
FilterCAD is a trademark of Linear Technology Corporation.
Windows is a registered trademark of Microsoft Corporation.
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S
TYPICAL APPLICATI
Dual, Matched, 4th Order Butterworth Lowpass Filters, Clock-Tunable
Up to 200kHz f – 3dB = fCLK/25, 4th Order Filter Noise = 60µVRMS
R12 14k
1
R21 14k
2
R31 20k
3
4
5
6
7
8
5V
0.1µF
9
10
11
R33 20k
R23 14k
R13 20k
VIN2
12
13
14
INV B
HPB/NB
INV C
HPC/NC
BPB
BPC
LPB
LPC
SB
SC
LTC1068-25
NC
AGND
V
+
V–
NC
CLK
NC
NC
SA
SD
LPA
LPD
BPA
BPD
HPA/NA
INVA
HPD/ND
INVD
28
27
R22 20k
26
R32 10k
Gain vs Frequency
10
25
VOUT1
0
24
–10
23
– 20
– 5V
1µF
22
21
fCLK = (25)(f – 3dB)
20
GAIN (dB)
R11 20k
VIN1
– 30
– 40
– 50
19
– 60
18
VOUT2
17
R34 10k
16
R24 20k
– 70
– 80
0.1
15
1
RELATIVE FREQUENCY [fIN /(f – 3dB)]
10
1068 TA20b
R14 14k
1068 TA20a
1
LTC1068 Series
W W
W
AXI U
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ABSOLUTE
RATI GS
(Note 1)
Total Supply Voltage (V + to V –) .............................. 12V
Power Dissipation............................................. 500mW
Input Voltage at Any Pin .... V – – 0.3V ≤ VIN ≤ V + + 0.3V
Storage Temperature Range ................. – 65°C to 150°C
Operating Temperature Range
LTC1068C................................................ 0°C to 70°C
LTC1068I ........................................... – 40°C to 85°C
Lead Temperature (Soldering, 10 sec).................. 300°C
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W
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PACKAGE/ORDER I FOR ATIO
TOP VIEW
INV B
1
28 INV C
HPB/NB
2
27 HPC/NC
BPB
3
26 BPC
LPB
4
25 LPC
SB
5
24 SC
NC
6
23 V –
AGND
7
22 NC
V+
8
21 CLK
9
NC
SA 10
20 NC
19 SD
LPA 11
18 LPD
BPA 12
17 BPD
HPA/NA 13
INV A 14
ORDER PART
NUMBER
ORDER PART
NUMBER
TOP VIEW
LTC1068CG
LTC1068CG-200
LTC1068CG-50
LTC1068CG-25
LTC1068IG
LTC1068IG-200
LTC1068IG-50
LTC1068IG-25
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
14 HPD/ND
INV A 12
16 HPD/ND
LTC1068CN
LTC1068IN
13 INV D
N PACKAGE
24-LEAD PDIP
TJMAX = 110°C, θJA = 65°C/W
15 INV D
G PACKAGE
28-LEAD PLASTIC SSOP
TJMAX = 110°C, θJA = 95°C/W
Consult factory for Military grade parts.
ELECTRICAL CHARACTERISTICS
PARAMETER
LTC1068 (Internal Op Amps) VS = ±5V, TA = 25°V, unless otherwise noted.
CONDITIONS
MIN
Operating Supply Voltage Range
TYP
3.14
Voltage Swings
VS = 3.14V, RL = 5k (Note 2)
VS = 4.75V, RL = 5k (Note 3)
VS = ±5V, RL = 5k
Output Short-Circuit Current (Source/Sink)
VS = ±4.75V
VS = ±5V
DC Open-Loop Gain
RL = 5k
●
●
●
1.2
2.6
±3.4
MAX
UNITS
±5.5
V
1.6
3.2
±4.1
VP-P
VP-P
V
17/6
20/15
mA
mA
85
dB
GBW Product
VS = ±5V
6
MHz
Slew Rate
VS = ±5V
10
V/µs
Analog Ground Voltage (Note 4)
VS = 5V, Voltage at AGND
2
2.5V ±2%
V
LTC1068 Series
ELECTRICAL CHARACTERISTICS
LTC1068 (Complete Filter) VS = ±5V, TA = 25°V, unless otherwise noted.
PARAMETER
CONDITIONS
MIN
TYP
MAX
Clock-to-Center Frequency Ratio (Note 5)
VS = 4.75V, fCLK = 1MHz, Mode 1 (Note 3),
fO = 10kHz, Q = 5, VIN = 0.5VRMS,
R1 = R3 = 49.9k, R2 = 10k
●
VS = ±5V, fCLK = 1MHz, Mode 1,
fO = 10kHz, Q = 5, VIN = 1VRMS,
R1 = R3 = 49.9k, R2 = 10K
●
Clock-to-Center Frequency Ratio,
Side-to-Side Matching (Note 5)
VS = 4.75V, fCLK = 1MHz, Q = 5 (Note 3)
VS = ±5V, fCLK = 1MHz, Q = 5
Q Accuracy (Note 5)
VS = 4.75V, fCLK = 1MHz, Q = 5 (Note 3)
VS = ±5V, fCLK = 1MHz, Q = 5
UNITS
100 ±0.3
100 ±0.8
100 ±0.9
%
%
100 ±0.3
100 ±0.8
100 ±0.9
%
%
●
●
±0.25
±0.25
±0.9
±0.9
%
%
●
●
±1
±1
±3
±3
%
%
fO Temperature Coefficient
±1
ppm/°C
Q Temperature Coefficient
±5
ppm/°C
DC Offset Voltage (Note 5)
(See Table 1)
VS = ±5V, fCLK = 1MHz, VOS1
(DC Offset of Input Inverter)
●
0
±15
mV
VS = ±5V, fCLK = 1MHz, VOS2
(DC Offset of First Integrator)
●
±2
±25
mV
VS = ±5V, fCLK = 1MHz, VOS3
(DC Offset of Second Integrator)
●
±5
±40
mV
Clock Feedthrough
VS = ±5V, fCLK = 1MHz
Max Clock Frequency (Note 6)
VS = ±5V, Q ≤ 2.0, Mode 1
Power Supply Current
VS = 3.14V, fCLK = 1MHz (Note 2)
VS = 4.75V, fCLK = 1MHz (Note 3)
VS = ±5V, fCLK = 1MHz
0.1
mVRMS
5.6
●
●
●
MHz
3.5
6.5
9.5
8
11
15
TYP
MAX
mA
mA
mA
LTC1068-200 (Internal Op Amps) VS = ±5V, TA = 25°V, unless otherwise noted.
PARAMETER
CONDITIONS
MIN
Operating Supply Voltage Range
±5.5
3.14
V
Voltage Swings
VS = 3.14V, RL = 5k (Note 2)
VS = 4.75V, RL = 5k (Note 3)
VS = ±5V, RL = 5k
Output Short-Circuit Current (Source/Sink)
VS = ±4.75V
VS = ±5V
DC Open-Loop Gain
RL = 5k
85
dB
GBW Product
VS = ±5V
6
MHz
Slew Rate
VS = ±5V
10
V/µs
Analog Ground Voltage (Note 4)
VS = 5V, Voltage at AGND
●
●
●
1.2
2.6
±3.4
UNITS
1.6
3.2
±4.1
VP-P
VP-P
V
17/6
20/15
mA
mA
2.5V ±2%
V
LTC1068-200 (Complete Filter) VS = ±5V, TA = 25°V, unless otherwise noted.
PARAMETER
CONDITIONS
MIN
Clock-to-Center Frequency Ratio (Note 5)
VS = 4.75V, fCLK = 1MHz, Mode 1 (Note 3),
fO = 5kHz, Q = 5, VIN = 0.5VRMS,
R1 = R3 = 49.9k, R2 = 10k
●
VS = ±5V, fCLK = 1MHz, Mode 1,
fO = 5Hz, Q = 5, VIN = 1VRMS,
R1 = R3 = 49.9k, R2 = 10K
●
TYP
MAX
UNITS
200 ±0.3
200 ±0.8
200 ±0.9
%
%
200 ±0.3
200 ±0.8
200 ±0.9
%
%
3
LTC1068 Series
ELECTRICAL CHARACTERISTICS
LTC1068-200 (Complete Filter) VS = ±5V, TA = 25°V, unless otherwise noted.
PARAMETER
CONDITIONS
Clock-to-Center Frequency Ratio,
Side-to-Side Matching (Note 5)
VS = 4.75V, fCLK = 1MHz, Q = 5 (Note 3)
VS = ±5V, fCLK = 1MHz, Q = 5
Q Accuracy (Note 5)
VS = 4.75V, fCLK = 1MHz, Q = 5 (Note 3)
VS = ±5V, fCLK = 1MHz, Q = 5
MIN
TYP
MAX
UNITS
●
●
±0.25
±0.25
±0.9
±0.9
%
%
●
●
±1
±1
±3
±3
%
%
fO Temperature Coefficient
±1
ppm/°C
Q Temperature Coefficient
±5
ppm/°C
DC Offset Voltage (Note 5)
(See Table 1)
VS = ±5V, fCLK = 1MHz, VOS1
(DC Offset of Input Inverter)
●
0
±15
mV
VS = ±5V, fCLK = 1MHz, VOS2
(DC Offset of First Integrator)
●
±2
±25
mV
VS = ±5V, fCLK = 1MHz, VOS3
(DC Offset of Second Integrator)
●
±5
±40
mV
Clock Feedthrough
VS = ±5V, fCLK = 1MHz
Max Clock Frequency (Note 6)
VS = ±5V, Q ≤ 2.0, Mode 1
Power Supply Current
VS = 3.14V, fCLK = 1MHz (Note 2)
VS = 4.75V, fCLK = 1MHz (Note 3)
VS = ±5V, fCLK = 1MHz
0.1
mVRMS
5.6
●
●
●
MHz
3.5
6.5
9.5
8
11
15
mA
mA
mA
TYP
MAX
UNITS
±5.5
V
LTC1068-50 (Internal Op Amps) VS = ±5V, TA = 25°V, unless otherwise noted.
PARAMETER
CONDITIONS
MIN
Operating Supply Voltage Range
3.14
Voltage Swings
VS = 3.14V, RL = 5k (Note 2)
VS = 4.75V, RL = 5k (Note 3)
VS = ±5V, RL = 5k
Output Short-Circuit Current (Source/Sink)
VS = ±3.14V
VS = ±5V
DC Open-Loop Gain
RL = 5k
85
dB
GBW Product
VS = ±5V
4
MHz
Slew Rate
VS = ±5V
7
V/µs
Analog Ground Voltage (Note 4)
VS = 5V, Voltage at AGND
●
●
●
1.2
2.6
±3.4
1.8
3.6
±4.1
VP-P
VP-P
V
17/6
20/15
mA
mA
2.175V ±2%
V
LTC1068-50 (Complete Filter) VS = ±5V, TA = 25°V, unless otherwise noted.
PARAMETER
CONDITIONS
Clock-to-Center Frequency Ratio (Note 5)
VS = 3.14V, fCLK = 250kHz, Mode 1 (Note 2),
fO = 5kHz, Q = 5, VIN = 0.34VRMS,
R1 = R3 = 49.9k, R2 = 10k
●
VS = ±5V, fCLK = 500kHz, Mode 1,
fO = 10kHz, Q = 5, VIN = 1VRMS,
R1 = R3 = 49.9k, R2 = 10K
●
Clock-to-Center Frequency Ratio,
Side-to-Side Matching (Note 5)
VS = 3.14V, fCLK = 250kHz, Q = 5 (Note 2)
VS = ±5V, fCLK = 500kHz, Q = 5
Q Accuracy (Note 5)
VS = 3.14V, fCLK = 250kHz, Q = 5 (Note 2)
VS = ±5V, fCLK = 500kHz, Q = 5
4
MIN
TYP
MAX
50 ±0.3
50 ±0.8
50 ±0.9
UNITS
%
%
50 ±0.3
50 ±0.8
50 ±0.9
%
%
●
●
±0.25
±0.25
±0.9
±0.9
%
%
●
●
±1
±1
±3
±3
%
%
LTC1068 Series
ELECTRICAL CHARACTERISTICS
LTC1068-50 (Complete Filter) VS = ±5V, TA = 25°V, unless otherwise noted.
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
fO Temperature Coefficient
±1
ppm/°C
Q Temperature Coefficient
±5
ppm/°C
DC Offset Voltage (Note 5)
(See Table 1)
VS = ±5V, fCLK = 500kHz, VOS1
(DC Offset of Input Inverter)
●
0
±15
mV
VS = ±5V, fCLK = 500kHz, VOS2
(DC Offset of First Integrator)
●
–2
±25
mV
VS = ±5V, fCLK = 500kHz, VOS3
(DC Offset of Second Integrator)
●
–5
±40
mV
Clock Feedthrough
VS = ±5V, fCLK = 500kHz
Max Clock Frequency (Note 6)
VS = ±5V, Q ≤ 1.6, Mode 1
Power Supply Current
VS = 3.14V, fCLK = 250kHz (Note 2)
VS = 4.75V, fCLK = 250kHz (Note 3)
VS = ±5V, fCLK = 500kHz
0.16
mVRMS
3.4
●
●
●
MHz
3.0
4.3
6.0
5
8
11
TYP
MAX
mA
mA
mA
LTC1068-25 (Internal Op Amps) VS = ±5V, TA = 25°V, unless otherwise noted.
PARAMETER
CONDITIONS
MIN
Operating Supply Voltage Range
±5.5
3.14
V
Voltage Swings
VS = 3.14V, RL = 5k (Note 2)
VS = 4.75V, RL = 5k (Note 3)
VS = ±5V, RL = 5k
Output Short-Circuit Current (Source/Sink)
VS = ±4.75V
VS = ±5V
DC Open-Loop Gain
RL = 5k
GBW Product
VS = ±5V
6
MHz
Slew Rate
VS = ±5V
10
V/µs
Analog Ground Voltage (Note 4)
VS = 5V, Voltage at AGND
●
●
●
1.2
2.6
±3.4
UNITS
1.6
3.4
±4.1
VP-P
VP-P
V
17/6
20/15
mA
mA
85
dB
2.5V ±2%
V
LTC1068-25 (Complete Filter) VS = ±5V, TA = 25°V, unless otherwise noted.
PARAMETER
CONDITIONS
Clock-to-Center Frequency Ratio (Note 5)
VS = 4.75V, fCLK = 500kHz, Mode 1 (Note 3),
fO = 20kHz, Q = 5, VIN = 0.5VRMS,
R1 = R3 = 49.9k, R2 = 10k
MIN
TYP
MAX
25 ±0.3
25 ±0.8
25 ±0.9
●
VS = ±5V, fCLK = 1MHz, Mode 1,
fO = 40kHz, Q = 5, VIN = 1VRMS,
R1 = R3 = 49.9k, R2 = 10K
●
Clock-to-Center Frequency Ratio,
Side-to-Side Matching (Note 5)
VS = 4.75V, fCLK = 500kHz, Q = 5 (Note 3)
VS = ±5V, fCLK = 1MHz, Q = 5
Q Accuracy (Note 5)
VS = 4.75V, fCLK = 500kHz, Q = 5 (Note 3)
VS = ±5V, fCLK = 1MHz, Q = 5
UNITS
%
%
25 ±0.3
25 ±0.8
25 ±0.9
%
%
●
●
±0.25
±0.25
±0.9
±0.9
%
%
●
●
±1
±1
±3
±3
%
%
fO Temperature Coefficient
±1
ppm/°C
Q Temperature Coefficient
±5
ppm/°C
5
LTC1068 Series
ELECTRICAL CHARACTERISTICS
LTC1068-25 (Complete Filter) VS = ±5V, TA = 25°V, unless otherwise noted.
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
DC Offset Voltage (Note 5)
(See Table 1)
VS = ±5V, fCLK = 1MHz, VOS1
(DC Offset of Input Inverter)
●
0
±15
mV
VS = ±5V, fCLK = 1MHz, VOS2
(DC Offset of First Integrator)
●
–2
±25
mV
VS = ±5V, fCLK = 1MHz, VOS3
(DC Offset of Second Integrator)
●
–5
±40
mV
Clock Feedthrough
VS = ±5V, fCLK = 1MHz
Max Clock Frequency (Note 6)
VS = ±5V, Q ≤ 1.6, Mode 1
Power Supply Current
VS = 3.14V, fCLK = 1MHz (Note 2)
VS = 4.75V, fCLK = 1MHz (Note 3)
VS = ±5V, fCLK = 1MHz
The ● denotes specifications which apply over the full operating
temperature range.
Note 1: Absolute Maximum Ratings are those values beyond which the life
of a device may be impaired.
Note 2: Production testing for single 3.14V supply is achieved by
using the equivalent dual supplies of ±1.57V.
Note 3: Production testing for single 4.75V supply is achieved by
using the equivalent dual supplies of ±2.375V.
0.25
mVRMS
5.6
MHz
3.5
6.5
9.5
●
●
●
8
11
15
mA
mA
mA
Note 4: Pin 7 (AGND) is the internal analog ground of the device. For
single supply applications this pin should be bypassed with a 1µF
capacitor. The biasing voltage of AGND is set with an internal resistive
divider from Pin 8 to Pin 23 (see Block Diagram).
Note 5: Side D is guaranteed by design.
Note 6: See Typical Performance Characteristics.
Table 1. Output DC Offsets One 2nd Order Section
MODE
VOSN
VOSBP
VOSLP
1
VOS1[(1/Q) + 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)X
[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 PERFORMANCE CHARACTERISTICS
LTC1068
Maximum Q vs Center Frequency
(Modes 1, 1b, 2)
50
55
50
40
A. VS = 3.3V, fCLK(MAX) = 1MHz
B. VS = 5V, fCLK(MAX) = 3MHz
C. VS = ± 5V, fCLK(MAX) = 5MHz
(FOR MODE 2 R4 < 10R2)
45
40
35
MAXIMUM Q
35
30
25
20
45
A: VS = 3.3V, fCLK(MAX) = 1.2MHz
B: VS = 5V, fCLK(MAX) = 3.2MHz
C: VS = ± 5V, fCLK(MAX) = 6.1MHz
40
(FOR MODE 2, R4 ≥ 10R2)
50
TYPICAL MAXIMUM Q
A. VS = 3.3V, fCLK(MAX) = 1.5MHz
B. VS = 5V, fCLK(MAX) = 3.4MHz
C. VS = ± 5V, fCLK(MAX) = 5.6MHz
(FOR MODE 2 R4 ≥ 10R2)
45
MAXIMUM Q
LTC1068-200
Maximum Q vs Center Frequency
(Modes 1, 1b, 2)
LTC1068
Maximum Q vs Center Frequency
(Modes 2, 3)
30
25
20
35
30
25
20
15
15
10
10
10
5
5
5
A
B
C
A
0
0
10
40
30
20
50
60
CENTER FREQUENCY, fO (kHz)
70
1068 G01
6
B
C
40
30
20
50
10
CENTER FREQUENCY, fO (kHz)
A
B
C
0
0
0
15
60
1068 G02
0
4
12 16 20 24 28
8
CENTER FREQUENCY, fO (kHz)
32
1068 G03
LTC1068 Series
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TYPICAL PERFORMANCE CHARACTERISTICS
LTC1068-200
Maximum Q vs Center Frequency
(Modes 2, 3)
LTC1068-50
Maximum Q vs Center Frequency
(Modes 1, 1b, 2)
55
40
(FOR MODE 2, R4 < 10R2)
30
25
20
15
45
40
(FOR MODE 2, R4 ≥ 10R2)
35
30
25
20
B
15
B
A
5
C
C
A
10
10
32
12 16 20 24 28
8
CENTER FREQUENCY, fO (kHz)
4
25
20
15
45
10
40
35
30
25
20
15
10
A
5
B
C
A
5
0
B
C
0
0
32
64
96 128 160 192
CENTER FREQUENCY, fO (kHz)
224
0
32
64
96 128 160
FREQUENCY, fO (kHz)
1068 G07
0.10
0.05
MODE 3
0
– 0.05
MODE 1
– 0.10
– 0.20
VS = ± 5V
Q = 5, REFERENCE
CENTER FREQUENCY
WITH fCLK = 0.75MHz
– 0.25
0.75 1.25 1.75 2.25 2.75 3.25 3.75 4.25
CLOCK FREQUENCY (MHz)
1068 G10
192
224
1.2
1.0
0.8
VS = ± 5V
Q = 5, REFERENCE
CENTER FREQUENCY
WITH fCLK = 0.75MHz
0.4
MODE 1
0.2
0
– 0.2
– 0.4
– 0.6
0.75 1.25 1.75 2.25 2.75 3.25 3.75 4.25
CLOCK FREQUENCY (MHz)
1068 G09
LTC1068-25 Center Frequency
Variation vs Clock Frequency
1.8
MODE 1
0.3
MODE 3
0.2
0.1
0
– 0.2
MODE 3
0.6
0.4
– 0.1
32
12 16 20 24 28
8
CENTER FREQUENCY, fO (kHz)
1068 G06
LTC1068-50 Center Frequency
Variation vs Clock Frequency
CENTER FREQUENCY VARIATION (% ERROR)
CENTER FREQUENCY VARIATION (% ERROR)
0.15
4
1068 G08
LTC1068-200 Center Frequency
Variation vs Clock Frequency
0.20
A
0
CENTER FREQUENCY VARIATION (% ERROR)
30
B
LTC1068 Center Frequency
Variation vs Clock Frequency
A: VS = 3.3V, fCLK(MAX) = 1MHz
B: VS = 5V, fCLK(MAX) = 3MHz
C: VS = ± 5V, fCLK(MAX) = 5MHz
(FOR MODE 2, R4 < 10R2)
50
TYPICAL MAXIMUM Q
TYPICAL MAXIMUM Q
35
C
15
32
12 16 20 24 28
8
CENTER FREQUENCY, fO (kHz)
4
55
40
20
LTC1068-25
Maximum Q vs Center Frequency
(Modes 2, 3)
55
45
25
1068 G05
LTC1068-25
Maximum Q vs Center Frequency
(Modes 1, 1b, 2)
A: VS = 3.3V, fCLK(MAX) = 1.2MHz
B: VS = 5V, fCLK(MAX) = 3.4MHz
C: VS = ± 5V, fCLK(MAX) = 6.1MHz
(FOR MODE 2, R4 ≥ 10R2)
30
0
0
1068 G04
50
(FOR MODE 2, R4 < 10R2)
35
5
0
0
40
10
5
0
45
A: VS = 3.3V, fCLK(MAX) = 1.1MHz
B: VS = 5V, fCLK(MAX) = 2.1MHz
C: VS = ± 5V, fCLK(MAX) = 3.6MHz
50
BATTERY VOLTAGE (V)
TYPICAL MAXIMUM Q
35
55
A: VS = 3.3V, fCLK(MAX) = 1.1MHz
B: VS = 5V, fCLK(MAX) = 2.1MHz
C: VS = ± 5V, fCLK(MAX) = 3.6MHz
50
TYPICAL MAXIMUM Q
45
A: VS = 3.3V, fCLK(MAX) = 1.2MHz
B: VS = 5V, fCLK(MAX) = 3.2MHz
C: VS = ± 5V, fCLK(MAX) = 6.1MHz
50
TYPICAL MAXIMUM Q
55
– 0.15
LTC1068-50
Maximum Q vs Center Frequency
(Modes 2, 3)
VS = ± 5V
Q = 5, REFERENCE
CENTER FREQUENCY
WITH fCLK = 0.5MHz
1.3
VS = ± 5V
Q = 5, REFERENCE
CENTER FREQUENCY
WITH fCLK = 0.5MHz
0.8
MODE 1
0.3
MODE 3
0
0.5
0.75
1.0
1.25
1.5
1.75
CLOCK FREQUENCY (MHz)
2.0
1068 G11
0.5
1.0
3.0
1.5
2.0
2.5
CLOCK FREQUENCY (MHz)
3.5
1068 G12
7
LTC1068 Series
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TYPICAL PERFORMANCE CHARACTERISTICS
LTC1068-50 Noise vs Q
300
250
250
200
150
5V
± 5V
100
LTC1068-25 Noise vs Q
300
250
200
5V
150
3.3V
100
3.3V
50
50
0
5
10
15
25
20
Q
30
35
5
0
40
10
15
20
Q
30
25
35
3.3V
150
100
0
40
0
5
15
10
Noise Increase vs R2/R4 Ratio
(Mode 3)
RELATIVE NOISE INCREASE
(REFERENCE NOISE WHEN R5/R6 = 0.02)
2.0
1.9
1.8
1.7
1.6
1.5
1.4
1.3
1.2
1.1
0
1.9
1.8
1.7
1.6
1.5
1.4
1.3
1.2
1.1
0
0.2 0.3
0.4
0.5 0.6 0.7
R2/R4 RATIO
0.8
0.9
0
1.0
0.5
1.0
1.5 2.0
2.5
R5/R6 RATIO
3.0
1068 G16
LTC1068-50 Power Supply
Current vs Power Supply
8
POWER SUPPLY CURRENT (mA)
10.5
POWER SUPPLY CURRENT (mA)
3.5
1068 G17
LTC1068/LTC1068-200/
LTC1068-25 Power Supply
Current vs Power Supply
9.5
25°C
70°C
8.5
– 20°C
7.5
6.5
5.5
4.5
7
25°C
70°C
6
– 20°C
5
4
3
2
3
4
7
9
6
8
5
TOTAL POWER SUPPLY (V)
10
LT1027 • TPCXX
3
4
25
30
35
40
1068 G15
Noise Increase vs R5/R6 Ratio
(Mode 1b)
2.0
8
20
Q
1068 G14
1068 G13
RELATIVE NOISE INCREASE
(REFERENCE NOISE WHEN R2/R4 = 1)
200
50
0
0
5V ± 5V
± 5V
NOISE (µVRMS)
300
NOISE (µVRMS)
NOISE (µVRMS)
LTC1068/LTC1068-200
Noise vs Q
7
9
6
8
5
TOTAL POWER SUPPLY (V)
10
1068 G19
LTC1068 Series
U
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PIN FUNCTIONS
Power Supply Pins
Clock Input Pin
The V + and V – pins should each be bypassed with a 0.1µF
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 2 shows the clock’s low and high
level threshold values for dual or single supply operation.
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. Figures 1 and 2 show
typical connections for dual and single supply operation.
Table 2. Clock Source High and Low Threshold Levels
Analog Ground Pin
POWER SUPPLY
The filter’s 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 single
supply operation, AGND should be bypassed to the analog
ground plane with at least a 0.47µF capacitor (Figure 2).
Two internal resistors bias the analog ground pin. For the
LTC1068, LTC1068-200 and LTC1068-25, the voltage at
the analog ground pin (AGND) for single supply is 0.5 × V+
and for the LTC1068-50 it is 0.435 × V+.
ANALOG
GROUND
PLANE
V+
0.1µF
STAR
SYSTEM
GROUND
1
28
2
27
3
26
4
25
5
24
6
23
7
22
8
LTC1068
V–
0.1µF
9
20
19
11
18
12
17
13
14
LOW LEVEL
≥ 1.53V
≤ 0.53V
Single Supply = 5V
≥ 1.53V
≤ 0.53V
Single Supply = 3.3V
≥ 1.20V
≤ 0.53V
A pulsed generator can be used as a clock source provided
the high level ON time is at least 25% of the pulse period.
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
ANALOG
GROUND
PLANE
1
28
2
27
DEVICE
RA RB
LTC1068
LTC1068-200 10k 10k
LTC1068-25
LTC1068-50 11.3k 8.6k
3
26
4
25
VAGND
21
10
HIGH LEVEL
Dual Supply = ±5V
5
LTC1068
6
23
7
8
V+
0.1µF
24
22
RA
RB
21
9
20
10
19
11
18
12
17
16
13
16
15
14
15
CLOCK
SOURCE
0.47µF
(1µF FOR
STOPBAND
FREQUENCIES
≤ 1kHz)
STAR
SYSTEM
GROUND
200Ω
DIGITAL GROUND
1068 F01
Figure 1. Dual Supply Ground Plane Connections
FOR MODE 3, THE S NODE
SHOULD BE TIED TO PIN 7 (AGND)
CLOCK
SOURCE
200Ω
DIGITAL GROUND
1068 F02
Figure 2. Single Supply Ground Plane Connections
9
LTC1068 Series
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PIN FUNCTIONS
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).
–
1k
Output Pins
LT®1354
+
1068 F03
Each 2nd order section of an LTC1068 device has three
outputs that typically source 17mA and sink 6mA. 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 a
LTC1068 device, the final output of the filter should be
buffered with a wideband, noninverting high slew rate
amplifier (Figure 3).
Figure 3. Wideband Buffer
In a printed circuit layout any signal trace, clock source
trace or power supply trace should be at least 0.1 inches
away from any inverting input pins
Summing Input Pins
Inverting Input Pins
These are voltage input pins. If used, they should be driven
with a source impedance below 5k. When they are not
used, they should be tied to the analog ground pin.
These pins are the inverting inputs of internal op amps and
are susceptible to stray capacitive coupling from low
impedance signal outputs and power supply lines.
The summing pin connections determine the circuit topology (mode) of each 2nd order section. Please refer to
Modes of Operation.
W
BLOCK DIAGRAM
HPA/NA
(13)
INV A
(14)
–
AGND
(7)
+
BPA
(12)
+
+
Σ
+∫
LPC
(25)
BPC
(26)
+∫
+∫
RA*
CLK (21)
AGND (7)
RB*
V – (23)
NC (9)
–
LPD
(18)
BPD
(17)
SC
(24)
NC (20)
NC (22)
+
Σ
+∫
+∫
–
SD
(19)
10
+∫
NC (6)
+
HPD/ND
(16)
+
V + (8)
SB
(5)
+
–
Σ
*THE RATIO RA/RB VARIES ± 2%
–
HPC/NC
(27)
INV D
(15)
LPB
(4)
SA
(10)
–
–
+∫
BPB
(3)
+
INV C
(28)
+∫
DEVICE
RA RB
LTC1068
LTC1068-200 10k 10k
LTC1068-25
LTC1068-50 11.3k 8.6k
–
HPB/NB
(2)
INV B
(1)
Σ
LPA
(11)
PIN 28-LEAD SSOP PACKAGE
1068 BD
LTC1068 Series
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MODES OF OPERATION
Linear Technology’s universal switched-capacitor filters
are designed for a fixed internal, nominal fCLK/fO ratio. The
fCLK/fO ratio is 100 for the LTC1068, 200 for the LTC1068200, 50 for the LTC1068-50 and 25 for the LTC1068-25.
Filter designs often require the fCLK/fO ratio of each section
to be different from the nominal ratio and in most cases
different from each other. Ratios other than the nominal
value are possible with external resistors. Operating modes
use external resistors, connected in different arrangements to realize different fCLK/fO ratios. By choosing the
proper mode, the fCLK/fO ratio can be increased or decreased from the part’s nominal ratio.
The choice of operating mode also effects the transfer
function at the HP/N pins. The LP and BP pins always give
the lowpass and bandpass transfer functions respectively,
regardless of the mode utilized. The HP/N pins have a
different transfer function depending on the mode used.
Mode 1 yields a notch transfer function. Mode 3 yields a
highpass transfer function. Mode 2 yields a highpass
notch transfer function (i.e., a highpass with a stopband
notch). More complex transfer functions, such as lowpass
notch, allpass or complex zeros, are achieved by summing
two or more of the LP, BP or HP/N outputs. This is
illustrated in sections Mode 2n and Mode 3a.
Choosing the proper mode(s) for a particular application
is not trivial and involves much more than just adjusting
the fCLK/fO ratio. Listed here are four of the nearly twenty
modes available. To make the design process simpler and
quicker, Linear Technology has developed the FilterCAD
for Widows design software. FilterCAD is an easy-to-use,
powerful and interactive filter design program. The designer can enter a few filter specifications and the program
produces a full schematic. FilterCAD allows the designer to
concentrate on the filter’s transfer function and not get
bogged down in the details of the design. Alternatively,
those who have experience with the Linear Technology
family of parts can control all of the details themselves. For
a complete listing of all the operating modes, consult the
appendices of the FilterCAD manual or the Help files in
FilterCAD. FilterCAD can be obtained free of charge on the
Linear Technology web site (www.linear-tech.com) or you
can order the FilterCAD CD-ROM by contacting Linear
Technology Marketing.
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 the part’s nominal ratio. 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 Operating Limits paragraph under Applications Information for a guide to the use of capacitor CC.
CC
R3
R2
S
N
VIN
R1
–
+
+
AGND
Σ
–
∫
fCLK
;f =f
RATIO n O
R2
R3
Q = R3 ; HON = –
;H
=–
R1 OBP
R1
R2
fO =
HOLP = HON
LP
BP
∫
RATIO
DEVICE
100
LTC1068
LTC1068-200 200
50
LTC1068-50
25
LTC1068-25
1068 F04
Figure 4. Mode 1, 2nd Order Filter Providing Notch,
Bandpass and Lowpass Outputs
Mode 1b
Mode 1b is derived from Mode 1. In Mode 1b (Figure 5)
two additional resistors R5 and R6 are added to lower the
amount of voltage fed back from the lowpass output into
the input of the SA (or SB) switched-capacitor summer.
This allows the filter’s clock-to-center frequency ratio to
be adjusted beyond the part’s nominal ratio. Mode 1b
maintains the speed advantages of Mode 1 and should be
considered an optimum mode for high Q designs with fCLK
to fCUTOFF (or fCENTER) ratios greater than the part’s
nominal ratio.
The parallel combination of R5 and R6 should be kept
below 5k.
Please refer to the Operating Limits paragraph under Applications Information for a guide to the use of capacitor CC.
11
LTC1068 Series
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MODES OF OPERATION
CC
CC
R6
R4
R5
R3
R3
R2
R2
N
VIN
R1
–
S
+
+
Σ
–
∫
√
–
∫
f
R6 ; f = f
fO = CLK
RATIO (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
VIN
)
–
∫
∫
1
R3 R2
R2
R3
√ R4 ; Q = 1.005 (R2) √ R4 (1 – (RATIO)(0.32)(R4)
)
R3
HOHP = – R2 ; HOBP = –
R1
R1
1068 F05
(
1
R3
1–
(RATIO)(0.32)(R4)
1068 F06
CC
R4
R3
R2
HPN
R1
VIN
Please refer to the Operating Limits paragraph under Applications Information for a guide to the use of capacitor CC.
–
+
S
Σ
–
∫
+
∫
RATIO
DEVICE
100
LTC1068
LTC1068-200 200
50
LTC1068-50
25
LTC1068-25
AGND
12
√ 1 + R4 ; f = RATIO
R3
1
Q = 1.005 ( ) 1 + R2
R2 √
R4
R3
(1– (RATIO)(0.32)(R4)
)
fO =
fCLK
RATIO
HOHPN = –
HOBP = –
R2
n
fCLK
R2
(AC GAIN, f >> fO); HOHPN = – R2
R1
R1
R3
R1
(
1–
1068 F07
1
1 + R2
R4
(
1
; HOLP = – R2
R1
R3
(RATIO)(0.32)(R4)
)
LP
BP
Mode 2
Please refer to the Operating Limits paragraph under Applications Information for a guide to the use of capacitor CC.
)
Figure 6. Mode 3, 2nd Order Section Providing
Highpass, Bandpass and Lowpass Outputs
Mode 3
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 the part’s nominal ratio. The
advantage of Mode 2 is that it provides less sensitivity to
resistor tolerances than does Mode 3. Mode 2 has a
highpass notch output where the notch frequency depends solely on the clock frequency and is therefore less
than the center frequency, fO.
; HOLP = – R4
R1
RATIO
DEVICE
100
LTC1068
LTC1068-200 200
50
LTC1068-50
25
LTC1068-25
Figure 5. Mode 1b, 2nd Order Filter Providing Notch,
Bandpass and Lowpass Outputs
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 the parts nominal ratio. 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.
Σ
LP
BP
1/4 LTC1068
f
fO = CLK
RATIO
AGND
S
+
+
RATIO
DEVICE
100
LTC1068
LTC1068-200 200
50
LTC1068-50
25
LTC1068-25
AGND
√
HP
LP
BP
)
(DC GAIN)
1
1 + R2
R4
(
)
Figure 7. Mode 2, 2nd Order Filter Providing Highpass
Notch, Bandpass and Lowpass Outputs
LTC1068 Series
U
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APPLICATIONS INFORMATION
Operating Limits
The Maximum Q vs Center Frequency (fO) graphs, under
Typical Performance Characteristics, define an upper limit
of operating Q for each LTC1068 device 2nd order section.
These graphs indicate the power supply, fO and Q value
conditions under which a filter implemented with an
LTC1068 device will remain stable when operated at
temperatures of 70°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 7. 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 an LTC1068 device near the
limits defined by the Maximum Q vs Frequency graphs,
passband gain variations of 2dB or more should be expected.
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 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 rising and
falling edges of the incoming clock are not part of the clock
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, 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 is used to deter-
mine the operating signal-to-noise ratio. Most of its frequency contents lie within the filter passband and cannot
be reduced with post filtering. For a notch filter the noise
of the filter is centered at the notch frequency.
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. Please refer
to the Noise vs Q graphs under the Typical Performance
Characteristics.
Aliasing
Aliasing is an inherent phenomenon of switched-capacitor
filters and occurs when the frequency of the input signals
that produce the strongest aliased components have a
frequency, fIN, such as (fSAMPLING – fIN) that falls into the
filter’s passband. For an LTC1068 device the sampling
frequency is twice fCLK. If the input signal spectrum is not
band-limited, aliasing may occur.
Demonstration Circuit 104
DC104 is a surface mount printed circuit board for the
evaluation of Linear Technology’s LTC1068 product family in a 28-lead SSOP package. The LTC1068 product
family consists of four monolithic clock-tunable filter
building blocks.
Demo Board 104 is available in four assembled versions:
Assembly 104-A features the low noise LTC1068CG (clockto-center frequency ratio = 100), assembly 104-B features
the low noise LTC1068CG-200 (clock-to-center frequency
ratio = 200), assembly 104-C features the high frequency
LTC1068CG-25 (clock-to-center frequency ratio = 25) and
assembly 104-D features the low power LTC1068CG-50
(clock-to-center frequency ratio = 50).
All DC104 boards are assembled with input, output and
power supply test terminals, a 28-lead SSOP filter device
(LTC1068CG Series), a dual op amp in an SO-8 for input
or output buffers and decoupling capacitors for the filter
and op amps. The filter and dual op amps share the power
13
LTC1068 Series
U
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APPLICATIONS INFORMATION
supply inputs to the board. Jumpers JPA to JPD on the
board configure the filter’s second order circuit modes,
jumper JP1 configures the filter for dual or single supply
operation and jumpers JP2 (A-D) to JP3 (A-D) configure
the op amp buffers as inverting or noninverting. Surface
mount pads are available on the board for 1206 size
surface mount resistors. The printed circuit layout of
DC104 is arranged so that most of the resistor connections for one 8th order filter or two 4th order filters are
available on the board. A resistor makes a connection
between two filter nodes on the board and for most filter
designs, no wiring is required.
DC104 Component Side Silkscreen
DC104 Component Side
14
DC104 Solder Side
E4
SGND
E13
CLK
E3
VIN1
E12
FGND
E2
SGND
VIN2
E1
E11
V–
E10
SGND
RI1
R12
C1
0.1µF
1
2
JPA
ASSEMBLED AS NONINVERTING
BUFFER DUAL SUPPLY
INVERTING BUFFER
DUAL SUPPLY
NONINVERTING BUFFER
SINGLE SUPPLY
FOR NONINVERTING BUFFER
SINGLE SUPPLY
3
SHORT
OPEN
SHORT
RES
SHORT
RES
JP2A
RL2
RB2
RH2
R23
R33
R43
OPEN
SHORT
OPEN
SHORT
U2A
JP2B
14
13
12
11
10
9
8
7
6
5
4
3
R31
R41
2
1
SHORT
OPEN
OPEN
OPEN
JP2C
BPD
LPD
SD
NC
CLK
NC
JP2D
OPEN
OPEN
OPEN
RES
SHORT
RES
SHORT
15
16
17
18
19
20
21
22
23
24
25
26
27
28
JP3A
OPEN
SHORT
OPEN
SHORT
RH1
R G1
RL3
INV D
HPD/ND
RB3
U1
V–
SC
LPC
BPC
HPC/NC
INV C
RB1
SHORT
RH3
INV A
HPA/NA
BPA
LPA
SA
NC
V+
AGND
NC
SB
LPB
BPB
HPB/NB
INV B
RL1
BOLD LINE INDICATES FGND
R21
OPEN
R G2
R51
SHORT
R53
C5
10µF
CI1
R11
JPB
FGND LPD
R63
R61
2
1 FGND LPB 3
BUFFERS CONFIGURATION
V+
V–
SINGLE
3 SUPPLY
1 DUAL
SUPPLY
2 JP1
V–
C7
10µF
16V
C6
10µF
16V
R52
OPEN
SHORT
OPEN
SHORT
SHORT
OPEN
OPEN
OPEN
JP3C
R24
R34
R44
R7 200Ω
U2A
JP3B
R42
R32
R22
RH5
RL5
JPC
R62
JP3D
OPEN
OPEN
SHORT
OPEN
2
4
3
2
1
V–
4
3
5
6
7
8
5
6
7
8
5
6
3
2
4
8
U2
LT1211
LT1211
LT1213
LT1498
U2B
CO1
V–
U2A
U1
LTC1068CG
LTC1068CG-200
LTC1068CG-25
LTC1068CG-50
JP3D
JP3C
JP3B
JP3A
C2
0.1µF
JP2D
JP2C
JP2B
DEMO BOARD
DC104B-A
DC104B-B
DC104B-C
DC104B-D
RL4
RB4
RH4
R64
JPD
3 LPD FGND 1
R54
2
3 LPC FGND 1
RB5
2
1
JP2A
V
+
CO2
7
1068 TA03
RG1
C4
0.1µF
1
C3
0.1µF
RG2
E8
SGND
E7
VOUT1
BUFFER 1
E6
SGND
E5
VOUT2
BUFFER 2
U
U
W
E9
V+
APPLICATIONS INFORMATION
U
DC104 Schematic
+
–
+
–
V+
LTC1068 Series
15
LTC1068 Series
U
U
W
U
APPLICATIONS INFORMATION
A Surface Mount Printed Circuit Layout
the folowing figures for an 8th order elliptic bandpass
filter. The total board area of this 8th order filter is 1" by
0.8". No attempt was made to design the smallest possible
printed circuit layout.
A very compact surface mount printed circuit layout can
be designed with 0603 size surface mount resistors,
capacitors and a 28-pin SSOP of the LTC1068 product
family. An example of a printed circuit layout is shown in
70kHz Elliptic Bandpass Filter, fCENTER = fCLK/25 (Maximum fCENTER is 80kHz, VS = ±5V)
RH1 28k
RL2 23.2k
RH2 11.3k
1
R21 4.99k
R11 29.4k
2
R31 24.9k
VIN
3
R41 20.5k
4
R51
4.99k
5
INV C
HPB/NB
HPC/NC
BPB
BPC
LPC
LPB
27
R22 4.99k
26
R32 107k
25
24
U1
SC
LTC1068-25
6
23
V–
NC
7
22
NC
AGND
8 +
21
CLK
V
R61 11.3k
5V
C1
0.1µF
9
10
R43 43.2k
11
R33 59k
12
R23 4.99k
INV B
28
13
14
RL3
45.3K
SB
NC
NC
SA
SD
LPA
LPD
BPA
BPD
HPA/NA
INV A
HPD/ND
INV D
20
19
18
17
16
15
R52
4.99k R62 56.2k
–5V
C2
0.1µF
1.75MHz
R64 10k
R54
4.99k
R44 17.4k
R34 63.4k
R24 7.5k
RH3 15.4k
VOUT
1068 TA07a
Gain vs Frequency
FilterCAD Custom Inputs for fC = 70kHz
10
2nd ORDER SECTION
fO (kHz)
Q
fN (kHz)
TYPE
MODE
B
67.7624
5.7236
58.3011
HPN
2b
C
67.0851
20.5500
81.6810
LPN
1bn
–20
A
73.9324
15.1339
81.0295
LPN
2n
–30
D
73.3547
16.3491
BP
2b
0
GAIN (dB)
–10
–40
–50
–60
–70
–80
–90
20
30
40
50 60 70 80
FREQUENCY (kHz)
90
100
1068 TA07b
16
LTC1068 Series
U
U
W
U
APPLICATIONS INFORMATION
Surface Mount Components
(Board Area = 1" × 0.8")
RH1
R11
R21
R22
R51
R31
U1
R52
R32
R41
R61
R62
C2
C1
R64
R43
R44
R33
R34
R54
R23
R24
RH2
RL3
RL2
RH3
1068 TA08
Component Side
Solder Side
VIN
RH1
R11
R51 R21
R22
R32 R52
R31
R61
GND
R41
GND
V–
R62
R64
R43
R44
R33
R54
V+
R34
R23
RL3
R24
RH2
RL2
RH3
VOUT
1068 TA09
1068 TA10
17
LTC1068 Series
U
TYPICAL APPLICATIONS
LTC1068-200 8th Order Linear Phase Lowpass, fCUTOFF = fCLK/400
for Ultralow Frequency Applications
RL1
23.2k
R11
14.3k
VIN
R31 10k
R41 15.4k
2
3
4
5
6
8
5V
0.1µF
9
10
R43 12.4k
11
R33 12.4k
12
R23 10k
13
14
RL3
23.2k
INV C
HPB/NB
HPC/NC
BPB
BPC
LPB
LPC
SB
SC
LTC1068-200
NC
V–
AGND
NC
V+
CLK
NC
NC
SA
SD
LPA
LPD
BPA
BPD
HPA/NA
INV A
HPD/ND
INV D
28
27
R22 15.4k
26
R32 10k
25
R52 5.11k
Gain and Group Delay
vs Frequency
10
R62 9.09k
24
0
23
– 5V
22
21
0.1µF
400kHz
R64 9.09k
20
19
R54 5.11k
18
17
R34 10k
16
R24 15.4k
VOUT
1.0
0.8
–20
0.7
–30
0.6
– 40
– 50
0.5
GROUP
DELAY
0.4
– 60
0.3
–70
0.2
– 80
0.1
– 90
0.1
0
1
FREQUENCY (Hz)
15
10
1068 TA11b
RB3 23.2k
1068 TA11a
FilterCAD Custom Inputs for fC = 1Hz
18
0.9
GAIN
–10
2nd ORDER SECTION
fO (Hz)
Q
B
1.7947
0.7347
C
1.6002
0.5195
A
1.7961
1.1369
D
1.6070
0.5217
QN
1.0159
TYPE
MODE
LP
3
LP
1b
LPBP
3s
LP
1b
GROUP DELAY (SEC)
7
INV B
GAIN (dB)
1
R21 12.4k
RL2
14.3k
LTC1068 Series
U
TYPICAL APPLICATIONS
LTC1068-50 8th Order Linear Phase Lowpass, fCUTOFF = fCLK/50
for Single Supply Low Power Applictions. Maximum fCUTOFF is
20kHz with a 3.3V Supply and 40kHz with a 5V Supply
R11
22.6k
VIN
R31 10k
R41 22.6k
2
3
4
5
6
8
3.3V
0.1µF
9
10
1µF
R43 48.7k
11
R33 12.7k
12
R23 10.7k
13
14
RB1
13.3k
RH2
34k
INV B
INV C
HPB/NB
HPC/NC
BPB
BPC
LPB
LPC
SB
SC
LTC1068-50
NC
V
–
NC
AGND
V+
CLK
NC
NC
SA
SD
LPA
LPD
BPA
BPD
HPA/NA
INV A
HPD/ND
INV D
28
27
R22 43.2k
26
R32 43.2k
25
R42 196k
Gain and Group Delay
vs Frequency
150
10
24
0
23
–10
130
22
–20
120
21
500kHz
20
19
140
GAIN
–30
110
GROUP
DELAY
– 40
100
– 50
90
18
R44 34.8k
– 60
80
17
R34 14.3k
–70
70
16
R24 16.9k
– 80
10
FREQUENCY (kHz)
1
15
GROUP DELAY (µs)
7
RL2
9.09k
GAIN (dB)
1
R21 20.5k
RA1
56.2k
60
100
1068 TA12b
RL3
26.7k
RB3 24.9k
VOUT
1068 TA12a
FilterCAD Custom Inputs for fC = 10kHz
2nd ORDER SECTION
fO (kHz)
Q
B
9.5241
0.5248
C
11.0472
1.1258
A
11.0441
1.3392
D
6.9687
0.6082
fN (kHz)
QN
TYPE
MODE
0.5248
AP
4a3
LPN
2n
1.5781
LPBP
2s
LP
3
21.7724
19
LTC1068 Series
U
TYPICAL APPLICATIONS
LTC1068-25 8th Order Lowpass, fCUTOFF = fCLK/32,
Attenuation – 50dB at (1.25)(fCUTOFF)and – 60dB at
(1.5)(fCUTOFF). Maximum fCUTOFF = 120kHz
RH1 18.2k
RL2 40.2k
RL1
26.7k
RH2 36.5k
R21 10k
R11 32.4k
R31 10k
VIN
2
3
4
R61
2.21k
R51
4.99k
5
6
7
8
5V
0.1µF
R63 8.45k
9
10
R53
4.99k
R33 118k
R23 10k
11
12
13
14
RL3
20.5K
INV B
INV C
HPB/NB
HPC/NC
BPB
BPC
LPB
LPC
SB
SC
LTC1068-25
NC
V–
NC
AGND
V+
CLK
NC
NC
SA
SD
LPA
LPD
BPA
BPD
HPA/NA
HPD/ND
INV A
INV D
28
27
R22 10k
26
R32 32.4k
Gain vs Frequency
25
24
R52
4.99k
23
22
19
18
0
–5V
0.1µF
–10
21
20
10
R62 5.9k
–20
3.2MHz
GAIN (dB)
1
R64 3.16k
R54
4.99k
17
R34 15k
16
R24 10k
–30
–40
–50
– 60
–70
– 80
20
15
500
1069 TA13b
RH3 53.6k
VOUT
1068 TA13a
FilterCAD Custom Inputs for fC = 100kHz
20
100
FREQUENCY (kHz)
2nd ORDER SECTION
fO (kHz)
Q
fN (kHz)
TYPE
MODE
B
70.9153
0.5540
127.2678
LPN
1bn
C
94.2154
2.3848
154.1187
LPN
1bn
A
101.4936
9.3564
230.5192
LPN
1bn
D
79.7030
0.9340
LP
1b
LTC1068 Series
U
TYPICAL APPLICATIONS
LTC1068 8th Order Linear Phase Bandpass, fCENTER = fCLK/128,
Passband – 3dB at (0.88)(fCENTER) and (1.12)(fCENTER). Maximum
fCENTER = 40kHz with ±5V Supplies
R L1
63.4k
RH1
7.5k
R11
26.1k
2
R31
19.6k
VIN
3
R41
12.1k
4
INV B
INV C
HPB/NB
HPC/NC
BPB
BPC
LPB
LPC
24
23
R22
4.99k
22
R32
21.5k
5V
20
SC
19
–
V
0.1µF
CLK
8
R43
10.7k
R33
14.7k
R23
4.99k
9
10
11
12
RL3
14.7k
SA
SD
LPA
LPD
BPA
HPA/NA
BPD
HPD/ND
INV A
INV D
10
21
LTC1068
5
SB
6
AGND
7 +
V
Gain vs Frequency
18
–10
–20
–5V
0.1µF
1.28MHz
17
16
R54
4.99k
15
R34
28.7k
14
0
R62
7.5k
R52
4.99k
GAIN(dB)
1
R21
4.99k
RB2
16.2k
R64 17.8k
–30
–40
–50
–60
–70
VOUT
–80
–90
R24
4.99k
1
10
FREQUENCY (kHz)
13
100
1068 TA14b
RH3
40.2k
24-Lead Package
1068 TA14a
FilterCAD Custom Inputs for fC = 10kHz
2nd ORDER SECTION
fO (kHz)
Q
fN (kHz)
TYPE
MODE
B
8.2199
2.6702
4.4025
HPN
3a
C
9.9188
3.3388
BP
1b
A
8.7411
2.1125
D
11.3122
5.0830
21.1672
LPN
3a
BP
1b
21
LTC1068 Series
U
TYPICAL APPLICATIONS
LTC1068 8th Order Linear Phase Bandpass, fCENTER = fCLK/100,
Passband – 3dB at (0.88)(fCENTER) and (1.12)(fCENTER). Maximum
fCENTER = 50kHz with ±5V Supplies
RL1
24.9k
RB2
14.3k
RH1
51.1k
2
R31
25.5k
R11
24.3k
VIN
3
R41
107k
4
5
0.1µF
R33
17.4k
R23
7.32k
HPB/NB
HPC/NC
BPB
BPC
LPB
LPC
SB
SC
V–
fCLK
8
R43
16.9k
INV C
6
AGND
7 +
V
LTC1068
5V
R63
2.32k
INV B
R53
4.99k
9
10
11
12
SA
SD
LPA
LPD
BPA
BPD
HPA/NA
HPD/ND
INV A
INV D
RB3
18.7k
24
23
R22
10k
22
R32
32.4k
21
R42
26.1k
Gain vs Frequency
10
0
20
–10
19
18
–5V
0.1µF
–20
GAIN(dB)
1
R21
10k
1MHz
17
16
R44
12.1k
15
R34
19.1k
14
R24
10k
–30
–40
–50
–60
–70
–80
–90
1
13
10
FREQUENCY (kHz)
1068 TA15b
24-Lead Package
VOUT
1068 TA15a
FilterCAD Custom Inputs for fC = 10kHz
22
100
2nd ORDER SECTION
fO (kHz)
Q
fN (kHz)
TYPE
MODE
B
10.4569
2.6999
17.4706
LPN
2n
C
11.7607
3.9841
BP
2
A
8.6632
2.1384
BP
2b
D
9.0909
1.8356
BP
3
LTC1068 Series
U
TYPICAL APPLICATIONS
LTC1068 8th Order Linear Phase Bandpass, fCENTER = fCLK/100,
Passband – 3dB at (0.7)(fCENTER) and (1.3)(fCENTER), Superior Sinewave
Burst Response, Maximum fCENTER = 60kHz with ±5V Supplies
RL1
348k
RL2
10k
RH1
11k
R31
10k
R11
11k
VIN
2
3
R41
14.3k
4
5
5V
0.1µF
R33
11.3k
R23
21k
INV C
HPB/NB
HPC/NC
BPB
BPC
LPB
LPC
SB
SC
6
AGND
7 +
V
LTC1068
V–
fCLK
8
R43
21.5k
INV B
9
10
11
12
SA
SD
LPA
LPD
BPA
BPD
HPA/NA
INV A
HPD/ND
INV D
RH3
95.3k
24
23
R22
18.2k
22
R32
10k
21
R42
18.7k
Gain vs Frequency
10
0
20
–10
19
18
–5V
0.1µF
–20
GAIN(dB)
1
R21
14.7k
RH2
200k
1MHz
17
–30
–40
–50
16
R44
10k
–70
15
R34
17.8k
–90
14
R24
15.4k
–60
–80
10
FREQUENCY (kHz)
1
13
100
1068 TA16b
VOUT
RL3
12.4k
24-Lead Package
1068 TA16a
FilterCAD Custom Inputs for fC = 10kHz
2nd ORDER SECTION
fO (kHz)
Q
fN (kHz)
TYPE
MODE
B
10.1389
0.7087
1.7779
HPN
3a
C
9.8654
0.5540
44.7214
LPN
3a
27.7227
LPN
3a
BP
3
A
9.8830
0.5434
D
12.4097
1.5264
QN
23
LTC1068 Series
U
TYPICAL APPLICATIONS
LTC1068-50 8th Order Linear Phase Bandpass, fCENTER = fCLK/40,
Passband – 3dB at (0.8)(fCENTER) and (1.2)(fCENTER) for Single Supply
Low Power Applicaions. Maximum fCENTER = 25kHz with a Single 5V Supply
RH1 18.2k
RL2 17.8k
RH2 84.5k
R21 10k
R11 36.5k
VIN
R31 30.1k
R41 10.7k
R61
1.74k
R51
4.99k
INV B
2
3
4
5
NC
AGND
V+
9
10
R43 12.1k
R33 26.7k
R23 10k
11
12
13
14
RL3
15.8K
LPC
LPB
LTC1068-50
8
0.1µF
BPC
SB
7
1µF
HPC/NC
BPB
6
5V
INV C
HPB/NB
R22 11.3k
26
R32 29.4k
25
R42 10k
Gain vs Frequency
10
0
23
V–
22
NC
21
CLK
– 20
NC
SA
SD
LPA
LPD
BPA
BPD
HPD/ND
INV A
27
24
SC
NC
HPA/NA
28
INV D
–10
GAIN (dB)
1
400kHz
20
– 30
– 40
– 50
19
18
R44 22.1k
17
R34 28k
16
R24 10k
– 60
– 70
– 80
2 4 6 8 10 12 14 16 18 20 22 24 26 28
FREQUENCY (kHz)
15
1068 TA17b
RH3 47.5k
VOUT
1068 TA17a
FilterCAD Custom Inputs for fC = 10kHz
2nd ORDER SECTION
24
fO (kHz)
Q
fN (kHz)
TYPE
MODE
B
8.7384
4.0091
4.0678
HPN
2b
C
11.6756
4.6752
19.1786
LPN
2n
A
10.8117
4.2066
16.0127
LPN
2n
D
9.6415
3.6831
BP
2
LTC1068 Series
U
TYPICAL APPLICATIONS
LTC1068-25 8th Order Bandpass, fCENTER = fCLK/32,
Passband – 3dB at (0.965)(fCENTER) and (1.35)(fCENTER).
Maximum fCENTER = 80kHz with ±5V Supplies
RH1 118k
R11 121k
R31 97.6k
VIN
2
3
4
R61
8.87k
R51
4.99k
5
6
7
8
5V
0.1µF
R63 6.49k
9
10
R53
4.99k
11
R33 124k
12
R23 4.99k
13
14
INV B
HPB/NB
INV C
HPC/NC
BPB
BPC
LPB
LPC
SB
SC
LTC1068-25
NC
V–
AGND
NC
V+
CLK
NC
NC
SA
SD
LPA
LPD
BPA
BPD
HPA/NA
INV A
HPD/ND
INV D
28
27
R22 4.99k
26
R32 130k
Gain vs Frequency
25
24
10
R52
4.99k
0
R62 9.53k
23
22
21
20
19
18
–10
–5V
0.1µF
320kHz
R64 6.98k
R54
4.99k
GAIN (dB)
1
R21 4.99k
RB2 47.5k
– 20
– 30
– 40
– 50
– 60
17
R34 102k
16
R24 4.99k
– 70
7.5
15
8
8.5
9 9.5 10 10.5 11 11.5 12 12.5
FREQUENCY (kHz)
1068 TA18b
RL3
78.7K
VOUT
1068 TA18a
FilterCAD Custom Inputs for fC = 10kHz
2nd ORDER SECTION
fO (kHz)
Q
TYPE
MODE
B
10.2398
15.6469
BP
1b
C
10.3699
21.1060
BP
1b
A
9.6241
18.6841
LP
1b
D
9.7744
15.6092
LP
1b
25
LTC1068 Series
U
TYPICAL APPLICATIONS
LTC1068-200 8th Order Highpass, fCENTER = fCLK/200,
Attenuation – 60dB at (0.6)(fCENTER).
Maximum fCUTOFF = 20kHz with ±5V Supplies
RH1 11.8k
RL1
66.5k
RH2 20.5k
R11 18.2k
VIN
2
R31 16.5k
R41 11.3k
3
4
5
6
7
8
5V
R63 2.55k
0.1µF
R53
R43 20.5k 4.99k
R33 36.5k
R23 10k
9
10
11
12
13
14
INV B
INV C
HPB/NB
HPB/NC
BPB
BPC
LPB
LPC
SB
SC
LTC1068-200
NC
V–
AGND
NC
V+
CLK
NC
NC
SA
SD
LPA
LPD
BPA
BPD
HPA/NA
HPD
INV A
INV D
28
27
R22 21.5k
26
R32 10.2k
25
R42 18.7k
Gain vs Frequency
10
0
24
– 10
23
22
– 5V
– 20
0.1µF
21
GAIN (dB)
1
R21 10k
RL2 249k
200kHz
20
– 30
– 40
– 50
19
18
R44 21k
17
R34 14.3k
16
R24 20.5k
– 60
– 70
– 80
0.2
1
FREQUENCY (kHz)
15
1068TA19b
RH3 10k
VOUT
C23 [1/(2π • R23 • C23) = (160)(fCUTOFF)]
1068 TA19a
FilterCAD Custom Inputs for fC = 1kHz
26
10
2nd ORDER SECTION
fO (kHz)
Q
fN (kHz)
TYPE
MODE
B
0.9407
1.5964
0.4212
HPN
3a
C
1.0723
0.5156
0.2869
HPN
3a
A
0.9088
3.4293
0.5815
HPN
2b
D
0.9880
0.7001
0.0000
HP
3
LTC1068 Series
U
PACKAGE DESCRIPTION
Dimensions in inches (millimeters) unless otherwise noted.
G Package
28-Lead Plastic SSOP (0.209)
(LTC DWG # 05-08-1640)
0.397 – 0.407*
(10.07 – 10.33)
28 27 26 25 24 23 22 21 20 19 18 17 16 15
0.301 – 0.311
(7.65 – 7.90)
1 2 3 4 5 6 7 8 9 10 11 12 13 14
0.205 – 0.212**
(5.20 – 5.38)
0.068 – 0.078
(1.73 – 1.99)
0° – 8°
0.0256
(0.65)
BSC
0.022 – 0.037
(0.55 – 0.95)
0.005 – 0.009
(0.13 – 0.22)
*DIMENSIONS DO NOT INCLUDE MOLD FLASH. MOLD FLASH
SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE
**DIMENSIONS DO NOT INCLUDE INTERLEAD FLASH. INTERLEAD
FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE
0.002 – 0.008
(0.05 – 0.21)
0.010 – 0.015
(0.25 – 0.38)
G28 SSOP 0694
N Package
24-Lead PDIP (Narrow 0.300)
(LTC DWG # 05-08-1510)
1.265*
(32.131)
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
0.255 ± 0.015*
(6.477 ± 0.381)
0.300 – 0.325
(7.620 – 8.255)
0.130 ± 0.005
(3.302 ± 0.127)
0.045 – 0.065
(1.143 – 1.651)
0.020
(0.508)
MIN
0.009 – 0.015
(0.229 – 0.381)
(
+0.035
0.325 –0.015
8.255
+0.889
–0.381
)
0.125
(3.175)
MIN
0.065
(1.651)
TYP
0.100 ± 0.010
(2.540 ± 0.254)
0.018 ± 0.003
(0.457 ± 0.076)
N24 1197
*THESE DIMENSIONS DO NOT INCLUDE MOLD FLASH OR PROTRUSIONS.
MOLD FLASH OR PROTRUSIONS SHALL NOT EXCEED 0.010 INCH (0.254mm)
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.
27
LTC1068 Series
U
TYPICAL APPLICATION
LTC1068-200 8th Order Notch, fNOTCH = fCLK/256, f – 3dB at (0.9) (fNOTCH) and (1.05)(fNOTCH),
Attenuation at fNOTCH Greater Than 70dB for fNOTCH in the Frequency Range 200Hz to 5kHz
C22 470pF
RH1 5.11k
C21
470pF
RH2 5.11k
1
R21 5.11k
R11 51.1k
2
R31 51.1k
VIN
3
R41 100k
4
R51
5.11k
R61
8.06k
5
INV C
HPB/NB
HPB/NC
BPB
BPC
LPB
LPC
SB
SC
28
27
R22 6.34k
26
R32 84.3k
25
5V
0.1µF
9
R63
8.06k
10
R53
5.11k
11
12
R33 124k
13
R23 10k
14
C23 470pF
RL2 66.5k
R62 5.76k
R52
5.11k
24
LTC1068-200 – 23
V
7
22
NC
AGND
8 +
21
CLK
V
6
R43
178k
INV B
–5V
NC
NC
NC
SA
SD
LPA
LPD
BPA
BPD
HPA/NA
HPD
INV A
INV D
0.1µF
fCLK = (256)(fNOTCH)
20
R64 7.87k
19
R54
5.11k
18
17
R34 75k
16
R24 7.32k
RG
15k
15
RH4 5.11k
RH3 5.11k
–
RL4 475k
+
LT1354
VOUT
1068 TA01
Gain vs Frequency
10
0
–10
GAIN (dB)
– 20
– 30
– 40
– 50
– 60
–70
– 80
– 90
0.8
1.0
1.1
1.2
0.9
RELATIVE FREQUENCY (fIN/fNOTCH)
1068 TA02
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
LTC1064
Universal Filter, Quad 2nd Order
50:1 and 100:1 Clock-to-fO Ratios, fO to 100kHz, VS = Up to ±7.5V
LTC1067/LTC1067-50
Low Power, Dual 2nd Order
Rail-to-Rail, VS = 3V to ±5V
LTC1164
Low Power Universal Filter, Quad 2nd Order
50:1 and 100:1 Clock-to-fO Ratios, fO to 20kHz, VS = Up to ±7.5V
LTC1264
High Speed Universal Filter, Quad 2nd Order
20:1 Clock-to-fO Ratio, fO to 200kHz, VS = Up to ±7.5V
28
Linear Technology Corporation
1068fa LT/TP 0998 2K REV A • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408)432-1900 ● FAX: (408) 434-0507 ● www.linear-tech.com
 LINEAR TECHNOLOGY CORPORATION 1996