LMF100CIWM/NOPB - NATIONAL SEMICONDUCTOR

Product

Folder

Sample &

Buy

Technical

Documents

Tools &

Software

Support &

Community

LMF100

SNOSBG9B –JULY 1999–REVISED JUNE 2015

LMF100 Dual High-Performance Switched Capacitor Filters

Not Recommended for New Designs

1 Features 3 Description

The LMF100 device consists of two independent

1• Wide 4-V to 15-V Power Supply Range general-purpose, high-performance switched

• Operation up to 100 kHz capacitor filters. With an external clock and two to

• Low Offset Voltage: four resistors, each filter block can realize various

second-order and first-order filtering functions. Each

– Typically (50:1 or 100:1 mode): block has three outputs. One output can be

– Vos1 = ±5 mV configured to perform either an allpass, highpass, or

– Vos2 = ±15 mV notch function. The other two outputs perform

bandpass and lowpass functions. The center

– Vos3 = ±15 mV frequency of each filter stage is tuned by using an

• Low Crosstalk: –60 dB external clock or a combination of a clock and resistor

• Clock to Center Frequency Ratio Accuracy ±0.2% ratio. Up to a fourth-order biquadratic function can be

(Typical) realized with one LMF100. Higher order filters are

implemented by simply cascading additional

• f0× Q Range up to 1.8 MHz packages, and all the classical filters (such as

• Pin-Compatible With MF10 Butterworth, Bessel, Elliptic, and Chebyshev) can be

realized.

2 Applications The LMF100 is fabricated on TI’s high-performance

• Replacing Active RC Filters With Reduced Form analog silicon gate CMOS process, LMCMOS™. This

Factors and Higher Accuracy and Tunability allows for the production of a very low-offset, high-

• An Alternative to Integrated Continuous Time frequency filter building block. The LMF100 is pin-

Filters compatible with the industry standard MF10, but

provides greatly improved performance.

Device Information(1)

PART NUMBER PACKAGE BODY SIZE (NOM)

SOIC (20) 12.60 mm × 10.00 mm

LMF100 PDIP (20) 24.33 mm × 6.35 mm

(1) For all available packages, see the orderable addendum at

the end of the data sheet.

Fourth-Order 100-kHz Butterworth Lowpass Filter Transfer Curve of Butterworth LP Filter Roll-Off

Magnitude vs Frequency

An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,

intellectual property matters and other important disclaimers. PRODUCTION DATA.

Not Recommended for New Designs

LMF100

SNOSBG9B –JULY 1999–REVISED JUNE 2015

www.ti.com

Table of Contents

8.1 Overview................................................................. 16

1 Features.................................................................. 18.2 Functional Block Diagram....................................... 16

2 Applications ........................................................... 18.3 Feature Description................................................. 16

3 Description............................................................. 18.4 Device Functional Modes........................................ 16

4 Revision History..................................................... 29 Application and Implementation ........................ 24

5 Pin Configuration and Functions......................... 39.1 Application Information............................................ 24

6 Specifications......................................................... 49.2 Typical Application ................................................. 24

6.1 Absolute Maximum Ratings ...................................... 410 Power Supply Recommendations ..................... 32

6.2 ESD Ratings ............................................................ 411 Layout................................................................... 32

6.3 Recommended Operating Conditions....................... 411.1 Layout Guidelines ................................................. 32

6.4 Thermal Information ................................................. 512 Device and Documentation Support................. 33

6.5 Electrical Characteristics for V+= +5 V and V−=−5

V................................................................................. 512.1 Device Support .................................................... 33

6.6 Electrical Characteristics for V+= +2.5 V and V−=12.2 Community Resources.......................................... 33

−2.5 V......................................................................... 612.3 Trademarks........................................................... 33

6.7 Logic Input Characteristics........................................ 812.4 Electrostatic Discharge Caution............................ 34

6.8 Typical Characteristics............................................ 10 12.5 Glossary................................................................ 34

7 Parameter Measurement Information ................ 14 13 Mechanical, Packaging, and Orderable

7.1 Definition of Terms Graphics .................................. 14 Information........................................................... 34

8 Detailed Description............................................ 16

4 Revision History

Changes from Revision A (July 1999) to Revision B Page

• Added ESD Ratings table, Feature Description section, Device Functional Modes,Application and Implementation

section, Power Supply Recommendations section, Layout section, Device and Documentation Support section, and

Mechanical, Packaging, and Orderable Information section. ................................................................................................ 1

Product Folder Links: LMF100

Not Recommended for New Designs

LMF100

www.ti.com

SNOSBG9B –JULY 1999–REVISED JUNE 2015

5 Pin Configuration and Functions

DW and N Package

20-Pin SOIC and PDIP (N20 or M20B)

(Top View)

Pin Functions

PIN I/O DESCRIPTION

NAME NO.

LP 20 The second order lowpass, bandpass and notch, allpass and highpass outputs. These outputs can typically swing to

BP I/O within 1 V of each supply when driving a 5-kΩload. For optimum performance, capacitive loading on these outputs

19 should be minimized. For signal frequencies above 15 kHz, the capacitance loading should be kept below 30 pF.

N/AP/HP 18

4The inverting input of the summing op-amp of each filter. These are high impedance inputs. The noninverting input is

INV I internally tied to AGND so the opamp can be used only as an inverting amplifier.

5S1 is a signal input pin used in modes 1b, 4, and 5. The input impedance is 1/fCLK x 1 pF. The pin should be driven with

S1 I a source impedance of less than 1 kΩ. If S1 is not driven with a signal it should be tied to AGND (mid-supply).

This pin activates a switch that connects one of the inputs of each filter’s second summer either to AGND (SA/B tied to V−)

SA/B 6 I or to the lowpass (LP) output (SA/B tied to V+). This offers the flexibility needed for configuring the filter in its various

modes of operation.

7(1) I This is both the analog and digital positive supply.

VA+

Analog and digital negative supplies. VA–and VD–should be derived from the same source. They have been brought out

8(1) I

VD+separately so they can be bypassed by separate capacitors, if desired. They can also be tied together externally and

bypassed with a single capacitor.

VA–Analog and digital negative supplies. VA–and VD–should be derived from the same source. They have been brought out

Iseparately so they can be bypassed by separate capacitors, if desired. They can also be tied together externally and

VD–bypassed with a single capacitor.

Level shift pin. This is used to accommodate various clock levels with dual or single supply operation. With dual ±5-V

supplies and CMOS (±5 V) or TTL (0 V–5 V) clock levels, LSh should be tied to system ground.

For 0-V to 10-V single-supply operation the AGND pin should be biased at +5 V and the LSh pin should be tied to the

LSh 9 I system ground for TTL clock levels. LSh should be biased at +5 V for ±5-V CMOS clock levels.

The LSh pin is tied to system ground for ±2.5V operation. For single 5V operation the LSh and VD+pins are tied to

system ground for TTL clock levels.

10 Clock inputs for the two switched capacitor filter sections. Unipolar or bipolar clock levels may be applied to the CLK

inputs according to the programming voltage applied to the LSh pin. The duty cycle of the clock should be close to 50%,

CLK I especially when clock frequencies above 200 kHz are used. This allows the maximum time for the internal opamps to

11 settle, which yields optimum filter performance.

By tying this pin to V+ a 50:1 clock to filter center frequency ratio is obtained. Tying this pin at mid-supply (i.e., system

50/100 12(1) Iground with dual supplies) or to V–allows the filter to operate at a 100:1 clock to center frequency ratio.

This is the analog ground pin. This pin should be connected to the system ground for dual supply operation or biased to

AGND 15 I mid-supply for single-supply operation. For a further discussion of mid-supply biasing techniques see the Applications

Information (Section 3.2). For optimum filter performance a “clean” ground must be provided.

(1) This device is pin-for-pin compatible with the MF10 except for the following changes:

(a) Unlike the MF10, the LMF100 has a single positive supply pin (VA+).

(b) On the LMF100 VD+is a control pin and is not the digital positive supply as on the MF10.

(c) Unlike the MF10, the LMF100 does not support the current limiting mode. When the 50/100 pin is tied to V–the LMF100 will remain

in the 100:1 mode.

Product Folder Links: LMF100

Not Recommended for New Designs

LMF100

SNOSBG9B –JULY 1999–REVISED JUNE 2015

www.ti.com

6 Specifications

6.1 Absolute Maximum Ratings

over operating free-air temperature range (unless otherwise noted)(1)

MIN MAX UNIT

Supply Voltage (V+– V–) 16 V

V++ 0.3

Voltage at any pin V

V–– 0.3

Input current at any pin(2) 5 mA

Package input current(2) 20 mA

Power dissipation(3) 500 mW

N Package: 10 sec. 250

Soldering information(4) Vapor Phase (60 sec) 215 °C

SOIC Package Infrared (15 sec) 220

Storage temperature, Tstg 150 °C

(1) Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings

only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended

Operating Conditions. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.

(2) When the input voltage (VIN) at any pin exceeds the power supply rails (VIN < V–or the absolute value of current at that pin should be

limited to 5 mA or less. The sum of the currents at all pins that are driven beyond the power supply voltages should not exceed

20 mA.VIN+)

(3) The maximum power dissipation must be derated at elevated temperatures and is dictated by TJMAX, RθJA, and the ambient

temperature, TA. The maximum allowable power dissipation at any temperature is PD= (TJMAX −TA)/RθJA or the number given in the

Absolute Maximum Ratings, whichever is lower. For this device, TJMAX = 125°C, and the typical junction-to-ambient thermal resistance

of the LMF100CIN when board mounted is 55°C/W. For the LMF100CIWM this number is 66°C/W.

(4) See AN-450Surface Mounting Methods and Their Effect on Product Reliability(Appendix D) for other methods of soldering surface

mount devices.

6.2 ESD Ratings VALUE UNIT

V(ESD) Electrostatic discharge Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001(1)(2) ±2000 V

(1) JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.

(2) A military RETS specification is available upon request.

6.3 Recommended Operating Conditions

over operating free-air temperature range (unless otherwise noted) MIN NOM MAX UNIT

LMF100CCN 0 70

Temperature °C

LMF100CIWM –40 85

Supply voltage 4 ≤V+– V–≤15 V

Product Folder Links: LMF100

Not Recommended for New Designs

LMF100

www.ti.com

SNOSBG9B –JULY 1999–REVISED JUNE 2015

6.4 Thermal Information LMF100

THERMAL METRIC(1) DW (SOIC) N (PDIP) UNIT

20 PINS 20 PINS

RθJA Junction-to-ambient thermal resistance 63.8 49.5 °C/W

RθJC(top) Junction-to-case (top) thermal resistance 27.2 41.1 °C/W

RθJB Junction-to-board thermal resistance 31.8 30.4 °C/W

ψJT Junction-to-top characterization parameter 5.7 18.3 °C/W

ψJB Junction-to-board characterization parameter 31.3 30.3 °C/W

RθJC(bot) Junction-to-case (bottom) thermal resistance — — °C/W

(1) For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application

report, SPRA953.

6.5 Electrical Characteristics for V+= +5 V and V−=−5 V

The following specifications apply for Mode 1, Q = 10 (R1= R3= 100 k, R2= 10 k), V+= +5 V and V−=−5 V unless otherwise

specified. All limits are TA= TJ= 25°C unless otherwise specified. LMF100CCN LMF100CIWM

PARAMETER TEST CONDITIONS UNIT

MIN TYP MAX MIN TYP MAX

9 9

Tested

fCLK = 250 kHz,

IsMaximum supply current Limit(1) mA

TMIN to TMAX 13

No Input Signal Design TMIN to TMAX 13

Limit(2)

10000

f0Center frequency 0.1 0.1 100000 Hz

35000

fCLK Clock frequency 5 5 3500000 Hz

±0.2% ±0.2%

±0.8%

Tested

fCLK/f Clock to center frequency ratio VPin12 = 5 V or 0 Limit(1) TMIN to TMAX ±0.8%

0deviation V, fCLK = 1 MHz Design TMIN to TMAX ±0.8%

Limit(2)

±0.5% ±0.5%

Q = 10, Mode 1, ±5%

Tested

VPin12 = 5 V or 0

Q Error (MAX) (3) Limit(1) TMIN to TMAX ±6%

fCLK = 1 MHz Design TMIN to TMAX ±6%

Limit(2)

0 0

±0.4

Tested

HOBP Bandpass gain at f0fCLK = 1 MHz Limit(1) dB

TMIN to TMAX ±0.4

Design TMIN to TMAX ±0.4

Limit(2)

0 0

±0.2

Tested

R1= R2= 10 k,

HOLP DC Lowpass gain Limit(1) dB

TMIN to TMAX ±0.2

fCLK = 250 kHz Design TMIN to TMAX ±0.2

Limit(2)

±5 ±5

±15

Tested

VOS1 DC Offset voltage(4) fCLK = 250 kHz Limit(1) mV

TMIN to TMAX ±15

Design TMIN to TMAX ±15

Limit(2)

(1) Tested limits are specified to Texas Instruments AOQL (Average Outgoing Quality Level).

(2) Design limits are specified to Texas Instruments AOQL (Average Outgoing Quality Level) but are not 100% tested.

(3) The accuracy of the Q value is a function of the center frequency (f0). This is illustrated in the curves under the heading Typical

Characteristics.

(4) Vos1, Vos2, and Vos3 refer to the internal offsets as discussed in Application Information.

Product Folder Links: LMF100

Not Recommended for New Designs

LMF100

SNOSBG9B –JULY 1999–REVISED JUNE 2015

www.ti.com

Electrical Characteristics for V+= +5 V and V−=−5 V (continued)

The following specifications apply for Mode 1, Q = 10 (R1= R3= 100 k, R2= 10 k), V+= +5 V and V−=−5 V unless otherwise

specified. All limits are TA= TJ= 25°C unless otherwise specified. LMF100CCN LMF100CIWM

PARAMETER TEST CONDITIONS UNIT

MIN TYP MAX MIN TYP MAX

±30 ±30

±80

Tested Limit(1) mV

SA/B = V+TMIN to TMAX ±80

Design Limit(2) TMIN to TMAX ±80

VOS2 DC Offset voltage(4) fCLK = 250 kHz ±15 ±15

±70

Tested Limit(1) mV

SA/B = V–TMIN to TMAX ±70

Design Limit(2) TMIN to TMAX ±70

±15 ±15

±40

Tested

VOS3 DC Offset voltage(4) fCLK = 250 kHz Limit(1) mV

TMIN to TMAX ±60

Design TMIN to TMAX ±60

Limit(2)

Crosstalk(5) A Side to B Side or B Side to A Side –60 –60 dB

fCLK = 250 kHz N 40 40

Output noise(6) 20 kHz Bandwidth BP 320 320 µV

100:1 Mode LP 300 300

Clock feedthrough(7) fCLK = 250 kHz 100:1 Mode 6 6 mV

4 4

−4.7 −4.7

±3.8

RL= 5 k Tested

(All Outputs) Limit(1) TMIN to TMAX ±3.7

VOUT Minimum output voltage swing V

Design TMIN to TMAX ±3.7

Limit(2)

RL= 3.5 k 3.9 3.9

(All Outputs) −4.6 −4.6

GB Operational amplifier gain BW 5 5 MHz

W product

SR Operational amplifier slew rate 20 20 V/µs

Source All Outputs 12 12 mA

Maximum output,

Isc Short circuit current(8) Sink All Outputs 45 45 mA

Tested Limit(1) 10

Input current on Pins: 4, 5, 6, 9,

IIN µA

10, 11, 12, 16, 17 Design Limit(2) TMIN to TMAX 10

(5) Crosstalk between the internal filter sections is measured by applying a 1 VRMS 10-kHz signal to one bandpass filter section input and

grounding the input of the other bandpass filter section. The crosstalk is the ratio between the output of the grounded filter section and

the 1 VRMS input signal of the other section.

(6) In 50:1 mode the output noise is 3 dB higher.

(7) In 50:1 mode the clock feed through is 6 dB higher.

(8) The short circuit source current is measured by forcing the output that is being tested to its maximum positive voltage swing and then

shorting that output to the negative supply. The short circuit sink current is measured by forcing the output that is being tested to its

maximum negative voltage swing and then shorting that output to the positive supply. These are the worst case conditions.

6.6 Electrical Characteristics for V+= +2.5 V and V−=−2.5 V

The following specifications apply for Mode 1, Q = 10 (R1= R3= 100 k, R2= 10 k), V+= +2.50 V and V−=−2.50 V unless

otherwise specified. All limits are TA= TJ= 25°C unless otherwise specified. LMF100CCN LMF100CIWM

PARAMETER TEST CONDITIONS UNIT

MIN TYP MAX MIN TYP MAX

8 8

12 12

Tested

fCLK = 250 kHz,

IsMaximum supply current Limit(1) mA

TMIN to TMAX

No Input Signal Design 12

Limit(2)

f0Center frequency 0.1 50000 0.1 50000 Hz

(1) Tested limits are specified to Texas Instruments AOQL (Average Outgoing Quality Level).

(2) Design limits are specified to Texas Instruments AOQL (Average Outgoing Quality Level) but are not 100% tested.

Product Folder Links: LMF100

Not Recommended for New Designs

LMF100

www.ti.com

SNOSBG9B –JULY 1999–REVISED JUNE 2015

Electrical Characteristics for V+= +2.5 V and V−=−2.5 V (continued)

The following specifications apply for Mode 1, Q = 10 (R1= R3= 100 k, R2= 10 k), V+= +2.50 V and V−=−2.50 V unless

otherwise specified. All limits are TA= TJ= 25°C unless otherwise specified. LMF100CCN LMF100CIWM

PARAMETER TEST CONDITIONS UNIT

MIN TYP MAX MIN TYP MAX

15000

fCLK Clock frequency 5 5 1500000 Hz

±0.2% ±0.2%

Tested

fCLK/f Clock to center frequency ratio VPin12 = 5 V or 0 TMIN to TMAX ±1% ±1%

Limit(1)

0deviation V, fCLK = 1 MHz Design ±1%

Limit(2)

±0.5% ±0.5%

Q = 10, Mode 1, ±5%

Tested

VPin12 = 5 V or 0

Q Error (MAX) (3) Limit(1) TMIN to TMAX ±8%

fCLK = 1 MHz Design TMIN to TMAX ±8%

Limit(2)

0 0

±0.4

Tested

HOBP Bandpass gain at f0fCLK = 1 MHz Limit(1) dB

TMIN to TMAX ±0.5

Design TMIN to TMAX ±0.5

Limit(2)

0 0

±0.2

Tested

R1= R2= 10 k,

HOLP DC Lowpass gain Limit(1) dB

TMIN to TMAX ±0.2

fCLK = 250 kHz Design TMIN to TMAX ±0.2

Limit(2)

±5 ±5

±15 ±15

Tested

VOS1 DC Offset voltage(4) fCLK = 250 kHz Limit(1) mV

TMIN to TMAX

Design TMIN to TMAX ±15

Limit(2)

±20 ±20

±60

Tested Limit(1) mV

SA/B = V+TMIN to TMAX ±60

Design Limit(2) TMIN to TMAX ±60

VOS2 DC Offset voltage(4) fCLK = 250 kHz ±10 ±10 mV

±50

Tested Limit(1)

SA/B = V–TMIN to TMAX ±60

Design Limit(2) TMIN to TMAX ±60

±10 ±10

±25

Tested

VOS3 DC Offset voltage(4) fCLK = 250 kHz Limit(1) mV

TMIN to TMAX ±30

Design TMIN to TMAX ±30

Limit(2)

Crosstalk(5) A Side to B Side or B Side to A Side –65 –65 dB

fCLK = 250 kHz N 25 25

Output noise(6) 20 kHz Bandwidth BP 250 250 µV

100:1 Mode LP 220 220

Clock feedthrough(7) fCLK = 250 kHz 100:1 Mode 2 2 mV

(3) The accuracy of the Q value is a function of the center frequency (f0). This is illustrated in the curves under the heading Typical

Characteristics.

(4) Vos1, Vos2, and Vos3 refer to the internal offsets as discussed in the Application Information.

(5) Crosstalk between the internal filter sections is measured by applying a 1 VRMS 10-kHz signal to one bandpass filter section input and

grounding the input of the other bandpass filter section. The crosstalk is the ratio between the output of the grounded filter section and

the 1 VRMS input signal of the other section.

(6) In 50:1 mode the output noise is 3 dB higher.

(7) In 50:1 mode the clock feed through is 6 dB higher.

Product Folder Links: LMF100

Not Recommended for New Designs

LMF100

SNOSBG9B –JULY 1999–REVISED JUNE 2015

www.ti.com

Electrical Characteristics for V+= +2.5 V and V−=−2.5 V (continued)

The following specifications apply for Mode 1, Q = 10 (R1= R3= 100 k, R2= 10 k), V+= +2.50 V and V−=−2.50 V unless

otherwise specified. All limits are TA= TJ= 25°C unless otherwise specified. LMF100CCN LMF100CIWM

PARAMETER TEST CONDITIONS UNIT

MIN TYP MAX MIN TYP MAX

RL= 5 k 1.6 1.6

All Outputs −2.2 −2.2

±1.5

Tested V

Limit(1)

RL= 5 k (All TMIN to TMAX ±1.4

VOUT Minimum output voltage swing Outputs) Design TMIN to TMAX ±1.4

Limit(2)

1.5 1.5

RL= 3.5 k V

All Outputs −2.1 −2.1

GB Operational amplifier gain BW 5 5 MHz

W product

SR Operational amplifier slew rate 18 18 V/µs

Source All Outputs 10 10 mA

Maximum output,

Isc Short circuit current(8) Sink All Outputs 20 20 mA

(8) The short circuit source current is measured by forcing the output that is being tested to its maximum positive voltage swing and then

shorting that output to the negative supply. The short circuit sink current is measured by forcing the output that is being tested to its

maximum negative voltage swing and then shorting that output to the positive supply. These are the worst case conditions.

6.7 Logic Input Characteristics

All limits apply to TA= TJ= 25°C unless otherwise specified. LMF100CCN LMF100CIWM

PARAMETER TEST CONDITIONS UNIT

MIN TYP MAX MIN TYP MAX

Tested Limit(1)

MIN Logical “1” TMIN to TMAX 3 V

V+= +5 V, V−=−5 V,

Design Limit(2) TMIN to TMAX 3

−3

Tested Limit(1)

MAX Logical “0” VLSh = 0 V TMIN to TMAX –3 V

Design Limit(2) TMIN to TMAX −3

CMOS Clock

Input Voltage 8

Tested Limit(1)

MIN Logical “1” TMIN to TMAX 8 V

V+= +10 V, V−= 0 V,

Design Limit(2) TMIN to TMAX 8

Tested Limit(1)

MAX Logical “0” VLSh = +5 V TMIN to TMAX 2 V

Design Limit(2) TMIN to TMAX 2

Tested Limit(1)

MIN Logical “1” TMIN to TMAX 2 V

V+= +5 V, V−=−5 V,

Design Limit(2) TMIN to TMAX 2

0.8

Tested Limit(1)

MAX Logical “0” VLSh = 0 V TMIN to TMAX 0.8 V

Design Limit(2) TMIN to TMAX 0.8

TTL Clock

Input Voltage 2

Tested Limit(1)

MIN Logical “1” TMIN to TMAX 2 V

V+= +10 V, V−= 0 V,

Design Limit(2) TMIN to TMAX 2

0.8

Tested Limit(1)

MAX Logical “0” VLSh = 0 V TMIN to TMAX 0.8 V

Design Limit(2) TMIN to TMAX 0.8

(1) Tested limits are specified to Texas Instruments AOQL (Average Outgoing Quality Level).

(2) Design limits are specified to Texas Instruments AOQL (Average Outgoing Quality Level) but are not 100% tested.

Product Folder Links: LMF100

Not Recommended for New Designs

LMF100

www.ti.com

SNOSBG9B –JULY 1999–REVISED JUNE 2015

Logic Input Characteristics (continued)

All limits apply to TA= TJ= 25°C unless otherwise specified. LMF100CCN LMF100CIWM

PARAMETER TEST CONDITIONS UNIT

MIN TYP MAX MIN TYP MAX

1.5

Tested Limit(1)

MIN Logical “1” TMIN to TMAX 1.5 V

V+= +2.5 V, V−=−2.5 V,

Design Limit(2) TMIN to TMAX 1.5

−1.5

Tested Limit(1)

MAX Logical “0” VLSh = 0 V TMIN to TMAX −1.5 V

Design Limit(2) TMIN to TMAX −1.5

CMOS Clock

Input Voltage 4

Tested Limit(1)

MIN Logical “1” TMIN to TMAX 4 V

V+= +5 V, V−= 0 V,

Design Limit(2) TMIN to TMAX 4

Tested Limit(1)

MAX Logical “0” VLSh = +2.5 V TMIN to TMAX 1 V

Design Limit(2) TMIN to TMAX 1

Tested Limit(1)

MIN Logical “1” TMIN to TMAX 2 V

V+= +5 V, V−= 0 V,

Design Limit(2) TMIN to TMAX 2

TTL Clock

Input Voltage 0.8

Tested Limit(1)

MAX Logical “0” TMIN to TMAX 0.8 V

VLSh = 0 V, VD+= 0 V

Design Limit(2) TMIN to TMAX 0.8

Product Folder Links: LMF100

Not Recommended for New Designs

LMF100

SNOSBG9B –JULY 1999–REVISED JUNE 2015

www.ti.com

6.8 Typical Characteristics

Figure 1. Power Supply Current vs Power Supply Voltage Figure 2. Power Supply Current vs Temperature

Figure 4. Positive Output Swing vs Temperature

Figure 3. Output Swing vs Supply Voltage

Figure 5. Negative Output Swing vs Temperature Figure 6. Positive Output Voltage Swing vs Load Resistance

Product Folder Links: LMF100

Not Recommended for New Designs

LMF100

www.ti.com

SNOSBG9B –JULY 1999–REVISED JUNE 2015

Typical Characteristics (continued)

Figure 8. fCLK/f0Ratio vs Q

Figure 7. Negative Output Voltage Swing vs Load

Resistance

Figure 9. fCLK/f0Ratio vs Q Figure 10. fCLK/f0Ratio vs fCLK

Figure 12. fCLK/f0Ratio vs fCLK

Figure 11. fCLK/f0Ratio vs fCLK

Product Folder Links: LMF100

Not Recommended for New Designs

LMF100

SNOSBG9B –JULY 1999–REVISED JUNE 2015

www.ti.com

Typical Characteristics (continued)

Figure 14. fCLK/f0Ratio vs Temperature

Figure 13. fCLK/f0Ratio vs fCLK

Figure 15. fCLK/f0Ratio vs Temperature Figure 16. Q Deviation vs Clock Frequency

Figure 17. Q Deviation vs Clock Frequency Figure 18. Q Deviation vs Clock Frequency

Product Folder Links: LMF100

Not Recommended for New Designs

LMF100

www.ti.com

SNOSBG9B –JULY 1999–REVISED JUNE 2015

Typical Characteristics (continued)

Figure 20. Q Deviation vs Temperature

Figure 19. Q Deviation vs Clock Frequency

Figure 22. Maximum f0vs Q at Vs= ±7.5 V

Figure 21. Q Deviation vs Temperature

Figure 23. Maximum f0vs Q at Vs= ±5 V Figure 24. Maximum f0vs Q at Vs= ±2.5 V

Product Folder Links: LMF100

Not Recommended for New Designs

LMF100

SNOSBG9B –JULY 1999–REVISED JUNE 2015

www.ti.com

7 Parameter Measurement Information

7.1 Definition of Terms Graphics

Figure 25. Second-Order Bandpass Response Gain Figure 26. Second-Order Bandpass Response

Phase

Figure 27. Second-Order Lowpass Response Gain Figure 28. Second-Order Lowpass Response

Phase

Figure 29. Second-Order Highpass Response Gain Figure 30. Second-Order Highpass Response

Phase

Figure 31. Second-Order Notch Response Gain Figure 32. Second-Order Notch Response Phase

Figure 33. Second-Order Allpass Response Gain Figure 34. Second-Order Allpass Response Phase

Product Folder Links: LMF100

Not Recommended for New Designs

LMF100

www.ti.com

SNOSBG9B –JULY 1999–REVISED JUNE 2015

Definition of Terms Graphics (continued)

Figure 35. Bandpass Response of Various Second-Order Figure 36. Lowpass Response of Various Second-Order

Filters as a Function of Q. Filters as a Function of Q.

Gains and Center Frequencies are Normalized to Unity Gains and Center Frequencies are Normalized to Unity

Gain Phase

Figure 37. Highpass Response of Various Second-Order Figure 38. Notch Response of Various Second-Order

Filters as a Function of Q. Filters as a Function of Q.

Gains and Center Frequencies are Normalized to Unity Gains and Center Frequencies are Normalized to Unity

Gain Gain

Figure 39. Allpass Response of Various Second-Order Filters as a Function of Q.

Gains and Center Frequencies are Normalized to Unity Gain

Product Folder Links: LMF100

Not Recommended for New Designs

LMF100

SNOSBG9B –JULY 1999–REVISED JUNE 2015

www.ti.com

8 Detailed Description

8.1 Overview

The LMF100 device contains two general-purpose, very high-performance switched capacitor filters that are cost-

effective and space-saving. It enables designers to implement all the classical filters up to fourth-order biquad

with one chip. This switched capacitor filters can be used in a broad range of industrial and consumer application

such as audio, communication, instrumentation, medical, telemetry, etc. It can be directly cascaded to implement

higher order filters,

8.2 Functional Block Diagram

8.3 Feature Description

The LMF100 is an all CMOS switched capacitor filter device that consists of two filters capable of wide supply

range from 4 V to 15 V. It features much higher performance than the pin-compatible MF10 device with operation

frequency to 100 kHz, which is 3X broader, and fo x Q range to 1.8 MHz which is 9X higher. Furthermore, it has

pins that also function to configure filter modes of operation, level shifting, clock to filter center frequency setting,

and power rail selections enabling flexibility and ease of programming.

8.4 Device Functional Modes

8.4.1 Modes of Operation

The LMF100 is a switched capacitor (sampled data) filter. To fully describe its transfer functions, a time domain

analysis is appropriate. Because this is cumbersome, and because the LMF100 closely approximates continuous

filters, the following discussion is based on the well-known frequency domain. Each LMF100 can produce two full

second-order functions. See Table 1 for a summary of the characteristics of the various modes.

Product Folder Links: LMF100

OBP

Circuit dynamics : H Q=

OBP

H 1(noninverting)=

OBP

= -

OLP OLP(peak) OLP

H 1; H Q H (for high Q's)= - @ ´

CLK CLK

f f

f or

100 50

OLP(peak) OLP

H Q H (for high Q 's)@ ´

OBP

OLP OBP OLP ON

H or H H Q H Q

= = ´ = ´

OBP

Circuit dynamics : H Q=

BW the 3 dB bandwidth of the bandpass output.= -

fR3

Q quality factor of the complex pole pair

BW R2

= = =

H Notch output gain as=

f 0®

CLK

f f / 2®

OBP

H Bandpass gain (at f 0) R1

= ® = -

OLP

H Lowpass gain (as f 0) R1

= ® = -

notch 0

f center frequency of the imaginary zero pair f= =

CLK CLK

f f

f center frequency of the complex pole pair or

100 50

= =

Not Recommended for New Designs

LMF100

www.ti.com

SNOSBG9B –JULY 1999–REVISED JUNE 2015

Device Functional Modes (continued)

8.4.1.1 MODE 1: Notch 1, Bandpass, Lowpass Outputs:

fnotch = f0(See Figure 40)

(1)

(2)

(3)

(4)

(5)

(6)

(7)

(8)

(9)

(10)

8.4.1.2 MODE 1a: Noninverting BP, LP (See Figure 41)

(11)

(12)

(13)

(14)

(15)

(16)

Note: VIN should be driven from a low-impedance (<1 kΩ) source.

Figure 40. MODE 1 Figure 41. MODE 1a

Product Folder Links: LMF100

2 1 2

OBP OLP ON OLP ON

Filter dynamics : H Q H H H H= =

CLK

H Notch output gain as f R2 / R1

æ ö

= ® = -

ç ÷

è ø

R2 / R1

H Notch output gain (as f 0) R2 / R4 1

= ® = -

OBP 0

H Bandpass gain (at f f ) R3 / R1= ® = -

OLP

R2 / R1

H Lowpass output gain (as f 0) R2 / R4 1

= ® = -

R2 / R4 1

Q quality factor of the complex pole pair R2 / R3

= =

CLK CLK

notch

f f

f or

100 50

CLK CLK

f f

R2 R2

f center frequency 1 or 1

100 R4 50 R4

= = ´ + ´ +

OLP(peak) OLP

H Q H (for high Q 's)@ ´

OBP

H Q

OBP

OLP OBP OLP

H or H H Q 2

= = ´ =

BW the 3 dB bandwidth of the bandpass output.= -

fR3

Q quality factor of the complex pole pair

BW R2

= = =

H Notch output gain as=

f 0®

CLK

f f / 2®

OBP

H Bandpass gain (at f 0) R1

= ® = -

OLP

H Lowpass gain (as f 0) R1

= ® = -

notch 0

f center frequency of the imaginary zero pair f= =

CLK CLK

f f

f center frequency of the complex pole pair 2 or 2

100 50

= = ´ ´

Not Recommended for New Designs

LMF100

SNOSBG9B –JULY 1999–REVISED JUNE 2015

www.ti.com

Device Functional Modes (continued)

8.4.1.3 MODE 1b: Notch 1, Bandpass, Lowpass Outputs:

fnotch = f0(See Figure 42)

(17)

(18)

(19)

(20)

(21)

(22)

(23)

Circuit dynamics:

(24)

(25)

(26)

8.4.1.4 MODE 2: Notch 2, Bandpass, Lowpass: fnotch < f0(See Figure 43)

(27)

(28)

(29)

(30)

(31)

(32)

(33)

(34)

Product Folder Links: LMF100

CLK CLK

h h

l l

f f

R R

f notch frequency or

100 R 50 R

= =

OLP

= -

OBP

= -

OHP

= -

R2 R3

R4 R2

= ´

CLK CLK

f f

R2 R2

f or

100 R4 50 R4

= ´ ´

OHP(peak) OHP

H Q H (for high Q 's)@ ´

OLP(peak) OLP

H Q H (for high Q 's)@ ´

OHP OBP OHP OLP

OLP

Circuit dynamics : ; H H H Q

R4 H

= = ´ ´

OLP

H Lowpass gain (as f 0) R1

= ® = -

( )

OBP 0

H Bandpass gain as f f R1

= ® = -

CLK

OLP

fR2

H Highpass gain at f 2 R1

æ ö

= ® = -

ç ÷

è ø

R2 R3

Q quality factor of the complex pole pair R4 R2

= = ´

CLK CLK

f f

R2 R2

f 1 or

100 R4 50 R4

= ´ + ´

Not Recommended for New Designs

LMF100

www.ti.com

SNOSBG9B –JULY 1999–REVISED JUNE 2015

Device Functional Modes (continued)

Figure 42. MODE 1b Figure 43. MODE 2

8.4.1.5 MODE 3: Highpass, Bandpass, Lowpass Outputs (See Figure 44)

(35)

(36)

(37)

(38)

(39)

(40)

(41)

(42)

8.4.1.6 MODE 3a: HP, BP, LP and Notch With External Op Amp (See Figure 45)

(43)

(44)

(45)

(46)

(47)

(48)

Product Folder Links: LMF100

CLK CLK

f f

R1 R1

f 1 or 1

R4 100 R4 50

= - ´ - ´

CLK CLK

f f

R2 R2

f 1 or 1

R4 100 R4 50

= + ´ + ´

( )

OBP OLP OAP

Circuit dynamics : H H Q H 1 Q= ´ = +

( )

OBP 0

R3 R2 R3

H Bandpass gain at f f 1 2

R2 R1 R2

æ ö æ ö

= ® = - + = -

ç ÷ ç ÷

è ø è ø

( )

OLP

H Lowpass gain as f 0 1 2

æ ö

= ® = - + = -

ç ÷

è ø

CLK

OAP

fR2

H * Allpass gain at 0 f 1

2 R1

æ ö

= - = = - = -

ç ÷

è ø

fR3 R3

Q ; Qz quality factor of the complex zero pair

BW R2 R1

= ´ = -

CLK CLK

0 z 0

f f

f center frequency or ;f * center frequency of the complex zero f

100 50

= = = »

CLK

n2 OHP

H gain of notch as f H

2 R

æ ö

= ® = ´

ç ÷

è ø

( ) g

n1 OLP

H gain of notch as f 0 H

= ® = ´

g g

ON 0 OLP OHP

l h

R R

H gain of notch at f f Q H H

R R

æ ö

= = = -

ç ÷

è ø

Not Recommended for New Designs

LMF100

SNOSBG9B –JULY 1999–REVISED JUNE 2015

www.ti.com

Device Functional Modes (continued)

(49)

(50)

(51)

*In Mode 3, the feedback loop is closed around the input summing amplifier; the finite GBW product of this op amp

causes a slight Q enhancement. If this is a problem, connect a small capacitor (10 pF−100 pF) across R4 to provide

some phase lead.

Figure 44. MODE 3 Figure 45. MODE 3a

8.4.1.7 MODE 4: Allpass, Bandpass, Lowpass Outputs (See Figure 46)

(52)

(53)

For AP output make R1 = R2 (54)

(55)

(56)

(57)

(58)

*Due to the sampled data nature f the filter, as light mismatch for fzand f0occurs, causing a 0.4-dB peaking

around f0of the allpass filter amplitude response (which theorectically should be a straight line). If this is

unacceptable, TI recommends Mode 5.

8.4.1.8 MODE 5: Numerator Complex Zeros, BP, LP (See Figure 47)

(59)

(60)

Product Folder Links: LMF100

CLK CLK

f f

R2 R2

f cutoff frequency of LP outputs or

R3 100 R3 50

= =

OHP

= -

OLP

= -

CLK CLK

f f

R2 R2

f cutoff frequency of LP or HP output or

R3 100 R3 50

= =

OLP

R2 R1 R4

R2 R4 R1

æ ö

= - ´

ç ÷

è ø

OBP

R2 R3

H 1

R1 R2

æ ö

= - + ´

ç ÷

è ø

CLK

fR2

H2 gain at C.Z. output as f 2 R1

æ ö -

= ®

ç ÷

è ø

( ) ( )

( )

0z1

R2 R4 R1

H gain at C.Z. output as f 0 Hz R1 R2 R4

- -

= ® +

Q 1 R1/ R4

= - ´

Q 1 R2 / R4

= + ´

Not Recommended for New Designs

LMF100

www.ti.com

SNOSBG9B –JULY 1999–REVISED JUNE 2015

Device Functional Modes (continued)

(61)

(62)

(63)

(64)

(65)

(66)

Figure 46. MODE 4 Figure 47. MODE 5

8.4.1.9 MODE 6a: Single-Pole, HP, LP Filter (See Figure 48)

(67)

(68)

(69)

Figure 48. MODE 6a

8.4.1.10 MODE 6b: Single-Pole LP Filter (Inverting and Noninverting) (See Figure 49)

(70)

Product Folder Links: LMF100

CLK CLK

16 8

int egrator time constant or

f f

t = @

1 2 3

R R R= =

OLP

H 2= -

OAP CLK

H 1(as f f / 2)= - ®

OAP

H 1(as f 0)= ®

CLK CLK

f f

f or

100 50

OHP

( )

OLP

H 1 noninverting=

Not Recommended for New Designs

LMF100

SNOSBG9B –JULY 1999–REVISED JUNE 2015

www.ti.com

Device Functional Modes (continued)

(71)

(72)

8.4.1.11 MODE 6c: Single-Pole, AP, LP Filter (See Figure 50)

(73)

(74)

(75)

(76)

(77)

Figure 49. MODE 6b Figure 50. MODE 6c

8.4.1.12 Summing Integrator (See Figure 52)

Figure 51. Equivalent Circuit

Figure 52. MODE 7

Product Folder Links: LMF100

OLP1

OLP2

H 1

= +

Not Recommended for New Designs

LMF100

www.ti.com

SNOSBG9B –JULY 1999–REVISED JUNE 2015

Device Functional Modes (continued)

Table 1. Summary of Modes(1)

NUMBER ADJUSTABLE

MODE BP LP HP N AP NOTES

RESISTOR fCLK/f0

1 * * * 3 No

HOBP1 =−Q

1a HOLP = + 1 2 No May need input buffer. Poor dynamics for high Q.

HOBP2 =+1

1b * * * 3 No Useful for high-frequency applications.

Yes (above fCLK/50 or

2 * * * 3 fCLK/100)

Universal State-Variable Filter. Best general-purpose

3 * * * 4 Yes mode.

3a * * * * 7 Yes As above, but also includes resistor-tuneable notch.

Gives Allpass response with HOAP =−1 and HOLP =

4 * * * 3 No −2.

Gives flatter allpass response than above

5 * * * 4 Yes if R1= R2= 0.02R4.

6a * * 3 Yes Single pole.

6b 2 Yes Single pole.

6c * * 3 No Single pole.

7 2 Yes Summing integrator with adjustable time constant.

(1) Realizable filter types (that is, lowpass) denoted by asterisks (*). Unless otherwise noted, gains of various filter outputs are inverting and

adjustable by resistor ratios.

Product Folder Links: LMF100

Not Recommended for New Designs

LMF100

SNOSBG9B –JULY 1999–REVISED JUNE 2015

www.ti.com

9 Application and Implementation

NOTE

Information in the following applications sections is not part of the TI component

specification, and TI does not warrant its accuracy or completeness. TI’s customers are

responsible for determining suitability of components for their purposes. Customers should

validate and test their design implementation to confirm system functionality.

9.1 Application Information

The LMF100 is a general purpose dual second-order state variable filter whose center frequency is proportional

to the frequency of the square wave applied to the clock input (fCLK). The various clocking options are

summarized in Table 2.

Table 2. Clocking Options

POWER SUPPLY CLOCK LEVELS LSh VD+

−5 V and +5 V TTL (0 V to 5 V) 0 V +5 V

−5 V and +5 V CMOS (−5 V to +5 V) 0 V +5 V

0 V and 10 V TTL (0 V to 5 V) 0 V +10 V

0 V and 10 V CMOS (0 V to 10 V) +5 V +10 V

−2.5 V and +2.5 V CMOS 0 V +2.5 V

0 V and 5 V (−2.5 V to +2.5 V) TTL (0 V to 5 V) 0 V 0 V

0 V and 5 V CMOS (0 V to 5 V) +2.5 V +5 V

By connecting pin 12 to the appropriate DC voltage, the filter center frequency, f0, can be made equal to either

fCLK/100 or fCLK/50. f0can be very accurately set (within ±0.6%) by using a crystal clock oscillator, or can be

easily varied over a wide frequency range by adjusting the clock frequency. If desired, the fCLK/f0ratio can be

altered by external resistors as in Figure 43 through Figure 49. This is useful when high-order filters (greater than

two) are to be realized by cascading the second-order sections. This allows each stage to be stagger tuned while

using only one clock. The filter Q and gain are set by external resistor ratios.

All of the five second-order filter types can be built using either section of the LMF100. These are illustrated in

Figure 25 through Figure 33 along with their transfer functions and some related equations. Figure 35 shows the

effect of Q on the shapes of these curves.

9.2 Typical Application

When designing a LP filter that has similar pass band characteristic as a Butterworth topology but requiring a

much steeper roll off then a fourth-order Chebyshev topology can implement the need with one LMF100.

Figure 53. Implement a Fourth-Order Chebyshev LP Filter Having a 1-kHz Cutoff Frequency and 1-dB PB

Ripple With an LMF100

Product Folder Links: LMF100

( )

4B 1B

2B 4B 2 2

CLK

4 4

3B B 2B 4B

R 20k

R R 20k

f(993)

R R 20k 19.7k

(1000)

f / 100

R Q R R 3.559 1.97 10 2 10 70.6k

= =

= = =

= = ´ ´ ´ =

( )

2A 4A 2 2

CLK

3 4

3A A 2A 4A

f(529)

R R 2 10 5.6k and

(1000)

f / 100

R Q R R 0.785 5.6 10 2 10 8.3k

= = ´ ´ =

= = ´ ´ ´ =

CLK

Not Recommended for New Designs

LMF100

www.ti.com

SNOSBG9B –JULY 1999–REVISED JUNE 2015

Typical Application (continued)

9.2.1 Design Requirements

In order to design a filter using the LMF100, we must define the necessary values of three parameters for each

second-order section: f0, the filter section’s center frequency; H0, the passband gain; and the filter’s Q. These are

determined by the characteristics required of the filter being designed.

As an example, assume that a system requires a fourth-order Chebyshev lowpass filter with 1-dB ripple, unity

gain at DC, and 1000 Hz cutoff frequency. As the system order is four, it is realizable using both second-order

sections of an LMF100. Many filter design texts (and TI Switched Capacitor Filter Handbook) include tables that

list the characteristics (f0 and Q) of each of the second-order filter sections needed to synthesize a given higher-

order filter. For the Chebyshev filter defined above, such a table yields the following characteristics:

f0A = 529 Hz — — QA= 0.785

f0B = 993 Hz — — QB= 3.559

For unity gain at DC, we also specify:

H0A = 1

H0B = 1

The desired clock-to-cutoff-frequency ratio for the overall filter of this example is 100, and a 100-kHz clock signal

is available. The required center frequencies for the two second-order sections will not be obtainable with clock-

to-center-frequency ratios of 50 or 100. It will be necessary to adjust externally. From Table 1, we see that

Mode 3 can be used to produce a lowpass filter with resistor-adjustable center frequency.

In most filter designs involving multiple second-order stages, it is best to place the stages with lower Q values

ahead of stages with higher Q, especially when the higher Q is greater than 0.707. This is due to the higher

relative gain at the center frequency of a higher-Q stage. Placing a stage with lower Q ahead of a higher-Q stage

will provide some attenuation at the center frequency and thus help avoid clipping of signals near this frequency.

For this example, stage A has the lower Q (0.785) so it will be placed ahead of the other stage.

For the first section, we begin the design by choosing a convenient value for the input resistance: R1A = 20 k.

The absolute value of the passband gain HOLPA is made equal to 1 by choosing R4A such that: R4A =−HOLPAR1A =

R1A = 20 k. If the 50/100/CL pin is connected to mid-supply for nominal 100:1 clock-to-center-frequency ratio, we

find R2A by:

The resistors for the second section are found in a similar fashion:

Product Folder Links: LMF100

Not Recommended for New Designs

LMF100

SNOSBG9B –JULY 1999–REVISED JUNE 2015

www.ti.com

Typical Application (continued)

The complete circuit is shown in Figure 54 for split ±5-V power supplies. TI highly recommends Supply bypass

capacitors.

±5-V power supply. 0-V to 5-V TTL or ±5-V CMOS logic levels.

Figure 54. Fourth-Order Chebyshev Lowpass Filter from Example in 3.1.

9.2.2 Detailed Design Procedure

9.2.2.1 Single-Supply Operation

The LMF100 can also operate with a single-ended power supply. Figure 55 shows the example filter with a

single-ended power supply. VA+and VD+are again connected to the positive power supply (4 to 15 volts), and

VA−and VD−are connected to ground. The AGND pin must be tied to V+/2 for single-supply operation. This half-

supply point should be very “clean”, as any noise appearing on it will be treated as an input to the filter. It can be

derived from the supply voltage with a pair of resistors and a bypass capacitor (Figure 56), or a low-impedance

half-supply voltage can be made using a three-terminal voltage regulator or an operational amplifier (Figure 57

and Figure 58). The passive resistor divider with a bypass capacitor is sufficient for many applications, provided

that the time constant is long enough to reject any power supply noise. It is also important that the half-supply

reference present a low impedance to the clock frequency, so at very low clock frequencies the regulator or

operational amplifier approaches may be preferable because they will require smaller capacitors to filter the clock

frequency. The main power supply voltage should be clean (preferably regulated) and bypassed with 0.1 μF

Product Folder Links: LMF100

Not Recommended for New Designs

LMF100

www.ti.com

SNOSBG9B –JULY 1999–REVISED JUNE 2015

Typical Application (continued)

Single 10-V power supply. 0-V to 5-V TTL logic levels. Input signals should be referred to half-supply or applied

through a coupling capacitor.

Figure 55. Fourth-Order Chebyshev Lowpass Filter from Example in 3.1.

Figure 56. Three Ways of Generating V+/2 for Figure 57. Three Ways of Generating V+/2 for

Single-Supply Operation Option A Single-Supply Operation Option B

Figure 58. Three Ways of Generating V+/2 for Single-Supply Operation Option C

9.2.2.2 Dynamic Considerations

The maximum signal handling capability of the LMF100, like that of any active filter, is limited by the power

supply voltages used. The amplifiers in the LMF100 can swing to within about 1 volt of the supplies, so the input

signals must be kept small enough that none of the outputs will exceed these limits. If the LMF100 is operating

on ±5 volts, for example, the outputs will clip at about 8 Vp-p. The maximum input voltage multiplied by the filter

gain should therefore be less than 8 Vp-p.

Product Folder Links: LMF100

OS3

OS(N) OS3 OS2 p

OS(BP) OS3

OS(LP) OS(N) OS2

R2 1 1

V 1 V V : R R1|| R3 || R4

Rp 1 R2 / R4 1 R4 / R2 Q 1 R2 / R4

V V

V V V

æ ö

= + ´ + - =

ç ÷ + + +

è ø

= -

OS(N) OS1 OS3

OS(BP) OS3

OS(N) OS2

OS(LP)

R2 R2 R2

V V 1 V

R3 R1 R3

V V

V2 2

æ ö

= + + -

ç ÷

è ø

= -

OS3

OS OS1

OS OS3

OS OS OS2

V (N.INV.BP) 1 V

Q Q

V (INV.BP) V

V (LP) V (N.INV.BP) V

æ ö

= + -

ç ÷

è ø

= -

OS3

OS(N) OS1 OLP

OS(BP) OS3

OS(LP) OS(N) OS2

V V 1 H

Q Q

V V

V V V

æ ö

= + + -

ç ÷

è ø

= -

Not Recommended for New Designs

LMF100

SNOSBG9B –JULY 1999–REVISED JUNE 2015

www.ti.com

Typical Application (continued)

If the filter Q is high, the gain at the lowpass or highpass outputs will be much greater than the nominal filter gain

(Figure 35). As an example, a lowpass filter with a Q of 10 will have a 20-dB peak in its amplitude response at f0.

If the nominal gain of the filter (HOLP) is equal to 1, the gain at f0will be 10. The maximum input signal at f0must

therefore be less than 800 mVp-p when the circuit is operated on ±5 volt supplies.

Also, one output can have a reasonable small voltage on it while another is saturated. This is most likely for a

circuit such as the notch in Mode 1 (Figure 40). The notch output will be very small at f0, so it might appear safe

to apply a large signal to the input. However, the bandpass will have its maximum gain at f0and can clip if

overdriven. If one output clips, the performance at the other outputs will be degraded, so avoid overdriving any

filter section, even ones whose outputs are not being directly used. Accompanying Figure 40 through Figure 50

are equations labeled circuit dynamics, which relate the Q and the gains at the various outputs. These should be

consulted to determine peak circuit gains and maximum allowable signals for a given application.

9.2.2.3 Offset Voltage

The switched capacitor integrators of the LMF100 have a slightly higher input offset voltage than found in a

typical continuous time active filter integrator. Because of TI's new LMCMOS process and new design techniques

the internal offsets have been minimized, compared to the industry standard MF10. Figure 59 shows an

equivalent circuit of the LMF100 from which the output DC offsets can be calculated. Typical values for these

offsets with SA/B tied to V+are:

VOS1 = opamp offset = ±5 mV

VOS2 = ±30 mV at 50:1 or 100:1

VOS3 = ±15 mV at 50:1 or 100:1

When SA/B is tied to V−, VOS2 will approximately halve. The DC offset at the BP output is equal to the input offset

of the lowpass integrator (VOS3). The offsets at the other outputs depend on the mode of operation and the

resistor ratios, as described in the following expressions.

Mode 1 and Mode 4

Mode 1a

Mode 1b

Mode 2 and Mode 5

Product Folder Links: LMF100

OS(LP(N.INV)) OS2

3 3

OS(LP(INV)) OS1 OS2

2 2

V V

R R

V V 1 V

R R

æ ö

= + -

ç ÷

è ø

OS(HP) OS2

3 3 3

OS(LP) OS1 OS2

2 1 2

V V

R R R

V V 1 V

R R R

æ ö

= + + -

ç ÷

è ø

OS(HP) OS2

OS(BP) OS3

OS(LP) OS1 OS2 OS3

V V

R4 R4 R4

V V 1 V V

R R2 R3

R R1|| R2 || R3

é ù æ ö æ ö

= + - -

ê ú ç ÷ ç ÷

è ø è ø

ê ú

ë û

Not Recommended for New Designs

LMF100

www.ti.com

SNOSBG9B –JULY 1999–REVISED JUNE 2015

Typical Application (continued)

Mode 3

Mode 6a and 6c

Mode 6b

Figure 59. Offset Voltage Sources

In many applications, the outputs are AC-coupled and DC offsets are not bothersome unless large signals are

applied to the filter input. However, larger offset voltages will cause clipping to occur at lower AC signal levels,

and clipping at any of the outputs will cause gain nonlinearities and will change f0and Q. When operating in

Mode 3, offsets can become excessively large if R2and R4are used to make fCLK/f0significantly higher than the

nominal value, especially if Q is also high.

For example, Figure 60 shows a second-order 60-Hz notch filter. This circuit yields a notch with about 40 dB of

attenuation at 60 Hz. A notch is formed by subtracting the bandpass output of a mode 3 configuration from the

input using the unused side B operational amplifier. The Q is 10 and the gain is 1 V/V in the passband. However,

fCLK/f0= 1000 to allow for a wide input spectrum. This means that for pin 12 tied to ground (100:1 mode),

R4/R2 = 100. The offset voltage at the lowpass output (LP) will be about 3 V. However, this is an extreme case

and the resistor ratio is usually much smaller. Where necessary, the offset voltage can be adjusted by using the

circuit of Figure 61. This allows adjustment of VOS1, which will have varying effects on the different outputs as

described in the above equations. Some outputs cannot be adjusted this way in some modes, however (VOS(BP)

in modes 1a and 3, for example).

Product Folder Links: LMF100

Not Recommended for New Designs

LMF100

SNOSBG9B –JULY 1999–REVISED JUNE 2015

www.ti.com

Typical Application (continued)

Figure 60. Second-Order Notch Filter

Figure 61. Method for Trimming VOS

9.2.2.4 Sampled Data System Considerations

The LMF100 is a sampled data filter, and as such, differs in many ways from conventional continuous-time filters.

An important characteristic of sampled-data systems is their effect on signals at frequencies greater than one-

half the sampling frequency. (The sampling frequency of the LMF100 is the same as its clock frequency.) If a

signal with a frequency greater than one-half the sampling frequency is applied to the input of a sampled data

system, it will be reflected to a frequency less than one-half the sampling frequency. Thus, an input signal whose

Product Folder Links: LMF100

Not Recommended for New Designs

LMF100

www.ti.com

SNOSBG9B –JULY 1999–REVISED JUNE 2015

Typical Application (continued)

frequency is fs/2 + 100 Hz will cause the system to respond as though the input frequency was fs/2 −100 Hz.

This phenomenon is known as aliasing, and can be reduced or eliminated by limiting the input signal spectrum to

less than fs/2. This may in some cases require the use of a bandwidth-limiting filter ahead of the LMF100 to limit

the input spectrum. However, because the clock frequency is much higher than the center frequency, this will

often not be necessary.

Another characteristic of sampled-data circuits is that the output signal changes amplitude once every sampling

period, resulting in “steps” in the output voltage which occur at the clock rate (Figure 62). If necessary, these can

be “smoothed” with a simple R-C lowpass filter at the LMF100 output.

The ratio of fCLK to fc(normally either 50:1 or 100:1) will also affect performance. A ratio of 100:1 will reduce any

aliasing problems and is usually recommended for wideband input signals. In noise-sensitive applications, a ratio

of 100:1 will result in 3 dB lower output noise for the same filter configuration.

The accuracy of the fCLK/f0ratio is dependent on the value of Q. This is shown in the curves under the heading

Figure 54. As Q is changed, the true value of the ratio changes as well. Unless the Q is low, the error in fCLK/f0

will be small. If the error is too large for a specific application, use a mode that allows adjustment of the ratio with

external resistors.

Figure 62. The Sampled-Data Output Waveform

9.2.3 Application Curve

Figure 63. The Wide BW of a Fourth-Order Butterworth LP Implemented With One LMF100

Product Folder Links: LMF100

Not Recommended for New Designs

LMF100

SNOSBG9B –JULY 1999–REVISED JUNE 2015

www.ti.com

10 Power Supply Recommendations

The LMF100 can operate with a single-ended power supply as well as bipolar supplies. Refer to Figure 56

through Figure 58 for methods of generating V+/2 for single-supply operation. In this circumstance, pins VA+ and

VD+ are connected to the positive power supply (4 to 15 V), and VA−and VD−are connected to ground. The

AGND pin must be tied to V+/2. Furthermore, the half-supply node should be very “clean”, as any noise

appearing on it will be treated as an input to the filter. Ensure liberal bypassing is employed to reject any supply

noise and present a low impedance to the clock frequency. Bypass caps should always be located as close to

the supply pins a practical. Moreover, the regulator or op-amp approaches of generating V+/e is preferred for

very low clock frequency applications. The main power supply voltage should also be clean (preferably

regulated) and bypassed with 0.1-µF nonpolar ceramic capacitor. If there is no bulk cap nearby, a 10-uF

electrolytic tantalum in parallel with the 0.1-µF supply bypass cap should achieve cleaner and optimal transient

response. Select capacitors with low ESR and ESL rating and test them to ensure no ringing occurs. The power

source is preferably a linear supply or regulator. If a switching supply is used ensure it is a clean switcher and

deploy proper bypassing or post regulate with an LDO as necessary.

11 Layout

11.1 Layout Guidelines

The most critical part to the success of a switched capacitor filter design is a properly layout PCB. Because of

the mixed signal circuitry involved, take extra care in the board design for noise abatement, star-grounding, and

shielding techniques. A ground plane must separate digital and analog ground planes if possible, or have

separate paths and join together only at the common return node at the supply source. All component leads and

PCB tracks are kept as short as possible. The filter clock input should be a shielded cable.

Product Folder Links: LMF100

2o o

OAP

AP 2 2

H s Q

H (s) s

æ ö

w + w

ç ÷

è ø

- + w

Not Recommended for New Designs

LMF100

www.ti.com

SNOSBG9B –JULY 1999–REVISED JUNE 2015

12 Device and Documentation Support

12.1 Device Support

12.1.1 Device Nomenclature

12.1.1.1 Definitions of Terms

fCLK:the frequency of the external clock signal applied to pin 10 or 11.

f0:center frequency of the second order function complex pole pair. f0is measured at the bandpass outputs of

the LMF100, and is the frequency of maximum bandpass gain. (Figure 25).

fnotch:the frequency of minimum (ideally zero) gain at the notch outputs.

fz:the center frequency of the second order complex zero pair, if any. If fz is different from f0 and if Qzis high, it

can be observed as the frequency of a notch at the allpass output. (Figure 46).

Q: “quality factor” of the 2nd order filter. Q is measured at the bandpass outputs of the LMF100 and is equal to f0

divided by the −3 dB bandwidth of the 2nd order bandpass filter (Figure 25). The value of Q determines the shape

of the 2nd order filter responses as shown in Figure 35.

Qz:the quality factor of the second order complex zero pair, if any. QZis related to the allpass characteristic,

which is written:

where QZ= Q for an allpass response.

HOLP:the gain (in V/V) of the lowpass output as f →0 Hz (Figure 27).

HOHP:the gain (in V/V) of the highpass output as f →fCLK/2 (Figure 29).

HON:the gain (in V/V) of the notch output as f →0 Hz and as f →fCLK/2, when the notch filter has equal gain

above and below the center frequency (Figure 31 ). When the low-frequency gain differs from the high-frequency

gain, as in modes 2 and 3a (Figure 43 and Figure 45), the two quantities below are used in place of HON.

HON1:the gain (in V/V) of the notch output as f →0 Hz.

HON2:the gain (in V/V) of the notch output as f →fCLK/2.

12.2 Community Resources

The following links connect to TI community resources. Linked contents are provided "AS IS" by the respective

contributors. They do not constitute TI specifications and do not necessarily reflect TI's views; see TI's Terms of

Use.

TI E2E™ Online Community TI's Engineer-to-Engineer (E2E) Community. Created to foster collaboration

among engineers. At e2e.ti.com, you can ask questions, share knowledge, explore ideas and help

solve problems with fellow engineers.

Design Support TI's Design Support Quickly find helpful E2E forums along with design support tools and

contact information for technical support.

12.3 Trademarks

LMCMOS, E2E are trademarks of Texas Instruments.

All other trademarks are the property of their respective owners.

Product Folder Links: LMF100

Not Recommended for New Designs

LMF100

SNOSBG9B –JULY 1999–REVISED JUNE 2015

www.ti.com

12.4 Electrostatic Discharge Caution

These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam

during storage or handling to prevent electrostatic damage to the MOS gates.

12.5 Glossary

SLYZ022 —TI Glossary.

This glossary lists and explains terms, acronyms, and definitions.

13 Mechanical, Packaging, and Orderable Information

The following pages include mechanical, packaging, and orderable information. This information is the most

current data available for the designated devices. This data is subject to change without notice and revision of

this document. For browser-based versions of this data sheet, refer to the left-hand navigation.

Product Folder Links: LMF100

PACKAGE OPTION ADDENDUM

www.ti.com 1-Oct-2016

Addendum-Page 1

PACKAGING INFORMATION

Orderable Device Status

(1)

Package Type Package

Drawing Pins Package

Qty Eco Plan

(2)

Lead/Ball Finish

(6)

MSL Peak Temp

(3)

Op Temp (°C) Device Marking

(4/5)

Samples

LMF100CIWM OBSOLETE SOIC DW 20 TBD Call TI Call TI -40 to 85 LMF100

CIWM

LMF100CIWM/NOPB OBSOLETE SOIC DW 20 TBD Call TI Call TI -40 to 85 LMF100

CIWM

LMF100CIWMX OBSOLETE SOIC DW 20 TBD Call TI Call TI -40 to 85 LMF100

CIWM

LMF100CIWMX/NOPB OBSOLETE SOIC DW 20 TBD Call TI Call TI -40 to 85 LMF100

CIWM

(1) The marketing status values are defined as follows:

ACTIVE: Product device recommended for new designs.

LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.

NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.

PREVIEW: Device has been announced but is not in production. Samples may or may not be available.

OBSOLETE: TI has discontinued the production of the device.

(2) Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability

information and additional product content details.

TBD: The Pb-Free/Green conversion plan has not been defined.

Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that

lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.

Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between

the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.

Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight

in homogeneous material)

(3) MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.

(4) There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.

(5) Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation

of the previous line and the two combined represent the entire Device Marking for that device.

(6) Lead/Ball Finish - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead/Ball Finish values may wrap to two lines if the finish

value exceeds the maximum column width.

PACKAGE OPTION ADDENDUM

www.ti.com 1-Oct-2016

Addendum-Page 2

Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information

provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and

continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.

TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.

In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.

www.ti.com

PACKAGE OUTLINE

TYP

10.63

9.97

2.65 MAX

18X 1.27

20X 0.51

0.31

11.43

TYP

0.33

0.10

0 - 8

0.3

0.1

0.25

GAGE PLANE

1.27

0.40

NOTE 3

13.0

12.6

B7.6

7.4

4220724/A 05/2016

SOIC - 2.65 mm max heightDW0020A

SOIC

NOTES:

1. All linear dimensions are in millimeters. Dimensions in parenthesis are for reference only. Dimensioning and tolerancing

per ASME Y14.5M.

2. This drawing is subject to change without notice.

3. This dimension does not include mold flash, protrusions, or gate burrs. Mold flash, protrusions, or gate burrs shall not

exceed 0.15 mm per side.

4. This dimension does not include interlead flash. Interlead flash shall not exceed 0.43 mm per side.

5. Reference JEDEC registration MS-013.

120

0.25 C A B

PIN 1 ID

AREA

NOTE 4

SEATING PLANE

0.1 C

SEE DETAIL A

DETAIL A

TYPICAL

SCALE 1.200

www.ti.com

EXAMPLE BOARD LAYOUT

(9.3)

0.07 MAX

ALL AROUND

0.07 MIN

ALL AROUND

20X (2)

20X (0.6)

18X (1.27)

(R )

TYP

0.05

4220724/A 05/2016

SOIC - 2.65 mm max heightDW0020A

SOIC

SYMM

LAND PATTERN EXAMPLE

SCALE:6X

10 11

NOTES: (continued)

6. Publication IPC-7351 may have alternate designs.

7. Solder mask tolerances between and around signal pads can vary based on board fabrication site.

METAL

SOLDER MASK

OPENING

NON SOLDER MASK

DEFINED

SOLDER MASK DETAILS

SOLDER MASK

OPENING

METAL UNDER

SOLDER MASK

DEFINED

www.ti.com

EXAMPLE STENCIL DESIGN

(9.3)

18X (1.27)

20X (0.6)

20X (2)

4220724/A 05/2016

SOIC - 2.65 mm max heightDW0020A

SOIC

NOTES: (continued)

8. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release. IPC-7525 may have alternate

design recommendations.

9. Board assembly site may have different recommendations for stencil design.

SYMM

10 11

SOLDER PASTE EXAMPLE

BASED ON 0.125 mm THICK STENCIL

SCALE:6X

IMPORTANT NOTICE

Texas Instruments Incorporated and its subsidiaries (TI) reserve the right to make corrections, enhancements, improvements and other

changes to its semiconductor products and services per JESD46, latest issue, and to discontinue any product or service per JESD48, latest

issue. Buyers should obtain the latest relevant information before placing orders and should verify that such information is current and

complete. All semiconductor products (also referred to herein as “components”) are sold subject to TI’s terms and conditions of sale

supplied at the time of order acknowledgment.

TI warrants performance of its components to the specifications applicable at the time of sale, in accordance with the warranty in TI’s terms

and conditions of sale of semiconductor products. Testing and other quality control techniques are used to the extent TI deems necessary

to support this warranty. Except where mandated by applicable law, testing of all parameters of each component is not necessarily

performed.

TI assumes no liability for applications assistance or the design of Buyers’ products. Buyers are responsible for their products and

applications using TI components. To minimize the risks associated with Buyers’ products and applications, Buyers should provide

adequate design and operating safeguards.

TI does not warrant or represent that any license, either express or implied, is granted under any patent right, copyright, mask work right, or

other intellectual property right relating to any combination, machine, or process in which TI components or services are used. Information

published by TI regarding third-party products or services does not constitute a license to use such products or services or a warranty or

endorsement thereof. Use of such information may require a license from a third party under the patents or other intellectual property of the

third party, or a license from TI under the patents or other intellectual property of TI.

Reproduction of significant portions of TI information in TI data books or data sheets is permissible only if reproduction is without alteration

and is accompanied by all associated warranties, conditions, limitations, and notices. TI is not responsible or liable for such altered

documentation. Information of third parties may be subject to additional restrictions.

Resale of TI components or services with statements different from or beyond the parameters stated by TI for that component or service

voids all express and any implied warranties for the associated TI component or service and is an unfair and deceptive business practice.

TI is not responsible or liable for any such statements.

Buyer acknowledges and agrees that it is solely responsible for compliance with all legal, regulatory and safety-related requirements

concerning its products, and any use of TI components in its applications, notwithstanding any applications-related information or support

that may be provided by TI. Buyer represents and agrees that it has all the necessary expertise to create and implement safeguards which

anticipate dangerous consequences of failures, monitor failures and their consequences, lessen the likelihood of failures that might cause

harm and take appropriate remedial actions. Buyer will fully indemnify TI and its representatives against any damages arising out of the use

of any TI components in safety-critical applications.

In some cases, TI components may be promoted specifically to facilitate safety-related applications. With such components, TI’s goal is to

help enable customers to design and create their own end-product solutions that meet applicable functional safety standards and

requirements. Nonetheless, such components are subject to these terms.

No TI components are authorized for use in FDA Class III (or similar life-critical medical equipment) unless authorized officers of the parties

have executed a special agreement specifically governing such use.

Only those TI components which TI has specifically designated as military grade or “enhanced plastic” are designed and intended for use in

military/aerospace applications or environments. Buyer acknowledges and agrees that any military or aerospace use of TI components

which have not been so designated is solely at the Buyer's risk, and that Buyer is solely responsible for compliance with all legal and

regulatory requirements in connection with such use.

TI has specifically designated certain components as meeting ISO/TS16949 requirements, mainly for automotive use. In any case of use of

non-designated products, TI will not be responsible for any failure to meet ISO/TS16949.

Products Applications

Audio www.ti.com/audio Automotive and Transportation www.ti.com/automotive

Amplifiers amplifier.ti.com Communications and Telecom www.ti.com/communications

Data Converters dataconverter.ti.com Computers and Peripherals www.ti.com/computers

DLP® Products www.dlp.com Consumer Electronics www.ti.com/consumer-apps

DSP dsp.ti.com Energy and Lighting www.ti.com/energy

Clocks and Timers www.ti.com/clocks Industrial www.ti.com/industrial

Interface interface.ti.com Medical www.ti.com/medical

Logic logic.ti.com Security www.ti.com/security

Power Mgmt power.ti.com Space, Avionics and Defense www.ti.com/space-avionics-defense

Microcontrollers microcontroller.ti.com Video and Imaging www.ti.com/video

RFID www.ti-rfid.com

OMAP Applications Processors www.ti.com/omap TI E2E Community e2e.ti.com

Wireless Connectivity www.ti.com/wirelessconnectivity

Mailing Address: Texas Instruments, Post Office Box 655303, Dallas, Texas 75265