National Semiconductor LMF100 Technical data

LMF100
High Performance Dual Switched Capacitor Filter

General Description

The LMF100 consists of two independent general purpose
high performance switched capacitor filters. With an external
clock and 2 to 4 resistors, various second-order and
first-order filtering functions can be realized by each filter
block. Each block has 3 outputs. One output can be config­ured to perform either an allpass, highpass, or notch func­tion. The other two outputs perform bandpass and lowpass
functions. The center frequency of each filter stage is tuned
by usinganexternalclock or a combination of a clock and re­sistor ratio. Up to a 4th-order biquadratic function can be re­alized with a single LMF100. Higher order filters are imple­mented by simply cascading additional packages, and all the
classical filters (such as Butterworth, Bessel, Elliptic, and
Chebyshev) can be realized.

The LMF100 is fabricated on National Semiconductor’s high
performance analog silicon gate CMOS process,

LMCMOS
set, high frequency filter building block. The LMF100 is
pin-compatible with the industry standard MF10, but pro­vides greatly improved performance.

Features

n Wide 4V to 15V power supply range
n Operation up to 100 kHz
n Low offset voltage: typically

n Low crosstalk −60 dB
n Clock to center frequency ratio accuracy
n f
n Pin-compatible with MF10

4th Order 100 kHz Butterworth Lowpass Filter

™

. This allows for the production of a very low off-

=

(50:1 or 100:1 mode): Vos1

x Q range up to 1.8 MHz

0

Vos2
Vos3

=
=

±

±

15 mV

±

15 mV

5mV

July 1999

±

0.2%typical

LMF100 High Performance Dual Switched Capacitor Filter

DS005645-3

DS005645-2

Connection Diagram

Surface Mount and Dual-In-Line Package

DS005645-18

Top View

Order Number

LMF100CCN or LMF100CIWM

See NS Package Number N20A or M20B

LMCMOS™is a trademark of National Semiconductor Corporation.

© 1999 National Semiconductor Corporation DS005645 www.national.com

Absolute Maximum Ratings (Note 1)

If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.

(Note 14)
Supply Voltage (V

Voltage at Any Pin V

Input Current at Any Pin (Note 2) 5 mA
Package Input Current (Note 2) 20 mA
Power Dissipation (Note 3) 500 mW
Storage Temperature 150˚C
ESD Susceptability (Note 11) 2000V
Soldering Information

N Package: 10 sec. 260˚C

+−V−

) 16V

V

+

+ 0.3V

−

− 0.3V

J Package: 10 sec. 300˚C
SO Package:

Vapor Phase (60 sec.) 215˚C
Infrared (15 sec.) 220˚C

See AN-450 “Surface Mounting Methods and Their Effect
on Product Reliability” (Appendix D) for other methods of
soldering surface mount devices.

Operating Ratings (Note 1)

Temperature Range T

LMF100CCN 0˚C ≤ TA≤ +70˚C
LMF100CIWM −40˚C ≤ T

Supply Voltage 4V ≤ V

MIN

≤ TA≤ T

≤ +85˚C

A

+−V−

MAX

≤15V

Electrical Characteristics

=

The following specifications apply for Mode 1, Q=10 (R
specified. Boldface limits apply for T

Symbol Parameter Conditions

Maximum Supply Current f

I

s

Center Frequency MIN 0.1 0.1 Hz

f

0

f

CLK

f

CLK/f0

H
H

V
V

V

V

GBW Op Amp Gain BW Product 5 5 MHz
SR Op Amp Slew Rate 20 20 V/µs
I

sc

Range MAX 100 100 kHz

Clock Frequency MIN 5.0 5.0 Hz

Range MAX 3.5 3.5 MHz

Clock to Center Frequency
Ratio Deviation

Q Error (MAX) (Note 4) Q=10, Mode 1

Bandpass Gain at f

OBP

DC Lowpass Gain R

OLP

DC Offset Voltage (Note 5) f

OS1

DC Offset Voltage (Note 5) f

OS2

DC Offset Voltage (Note 5) f

OS3

Crosstalk (Note 6) A Side to B Side or

Output Noise (Note 12) f

Clock Feedthrough
(Note 13)

Minimum Output R

OUT

Voltage Swing (All Outputs) −4.7 −4.7

Maximum Output
Short

Circuit Current
(Note 7)

0

Source (All Outputs) 12 12 mA

Sink 45 45 mA

to T

MIN

=

250 kHz 9 13 13 9 13 mA

CLK

No Input Signal

=

V

Pin12

=

f

1 MHz

CLK

=

V

Pin12

=

1 MHz

f

CLK

=

f

1 MHz 0

CLK

=

R

1

2

=

250 kHz

f

CLK

=

250 kHz

CLK

=

250 kHz S

CLK

=

250 kHz

CLK

B Side to A Side

=

250 kHz N 40 40

CLK

20 kHz Bandwidth BP 320 320 µV
100:1 Mode LP 300 300

=

250 kHz 100:1 Mode 6 6 mV

f

CLK

=

5k +4.0

L

=

R

3.5k +3.9 +3.9

L

(All Outputs) −4.6 −4.6

; all other limits T

MAX

5V or 0V

5V or 0V

=

10k 0

A/B

S

A/B

=

R

100k, R

1

3

(Note 8)

2

=

=

T

A

J

LMF100CCN LMF100CIWM

Typical

Tested

Limit

(Note 9)

±

±

0.2

±

0.5

±
±

±

+

=

V

−

=

V

±

5.0

±

±

30

±

±

15

±

±

15

−60 −60 dB

±

=

10k), V

25˚C.

0.8

±

5

0.4

0.2

15
80
70
40

3.8

+

=

Design

Limit

(Note 10)

±

0.8

±

6

±

0.4 0

±

0.2 0

±

15

±

80

±

70

±

60

±

3.7

+5V and V

Typical

(Note 8)

±

0.2

±

0.5

±

5.0

±

30

±

15

±

15

+4.0

−

=

−5V unless otherwise

Tested

(Note 9)

Design

Limit

(Note 10)

±

0.8

±

6

±

0.4 dB

±

0.2 dB

±

15 mV

±

80 mV

±

70 mV

±

60 mV

±

3.7 V

Limit

Units

%

%

V

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Electrical Characteristics (Continued)

The following specifications apply for Mode 1, Q=10 (R
specified. Boldface limits apply for T

MIN

to T

MAX

; all other limits T

=

=

R

100k, R

1

3

2

=

=

T

A

J

=

10k), V

25˚C.

+

=

+5V and V

LMF100CCN LMF100CIWM

Typical

Symbol Parameter Conditions

Input Current on Pins: 4, 5, 10 10 µA

I

IN

(Note 8)

Tested

(Note 9)

Limit

Design

Limit

(Note 10)

6, 9, 10, 11, 12, 16, 17

Typical

(Note 8)

−

=

−5V unless otherwise

Tested

Limit

(Note 9)

Design

Limit

(Note 10)

Units

Electrical Characteristics

The following specifications apply for Mode 1, Q=10 (R
erwise specified. Boldface limits apply for T

MIN

to T

MAX

=

=

R

100k, R

1

3

; all other limits T

2

A

=

10k), V

=

+

=

+2.50V and V

=

T

25˚C.

J

−

=

−2.50V unless oth-

LMF100CCN LMF100CIWM

Symbol Parameter Conditions

Maximum Supply

I

s

Current
Center Frequency MIN 0.1 0.1 Hz

f

0

=

f

250 kHz

CLK

No Input Signal

Typical

(Note 8)

Tested

Limit

(Note 9)

Design

Limit

(Note

10)

Typical

(Note 8)

Tested

Limit

(Note 9)

Design

Limit

(Note

10)

81212 8 12 mA

Range MAX 50 50 kHz

Clock Frequency MIN 5.0 5.0 Hz

f

CLK

Range MAX 1.5 1.5 MHz

CLK

Pin12

=

=
1 MHz

2.5V or 0V

±

0.2

±

±

1

±

1

0.2

±

1

Clock to Center V

f

CLK/f0

Frequency Ratio Deviation f

Q Error (MAX) Q=10, Mode 1
(Note 4) V

Bandpass Gain at f

H

OBP

DC Lowpass Gain R

H

OLP

DC Offset Voltage (Note 5) f

V

OS1

DC Offset Voltage (Note 5) f

V

OS2

DC Offset Voltage (Note 5) f

V

OS3

=

5V or 0V

Pin12

=

1 MHz

f

CLK

=

f

0

1 MHz 0

CLK

=

=

R

10k 0

1

2

=

250 kHz

f

CLK

=

250 kHz

CLK

=

250 kHz S

CLK

S

=

250 kHz

CLK

A/B
A/B

±

±

+

=

±

V

−

=

±

V

±

0.5

5.0
20
10
10

±

±
±

±
±
±
±

0.4

0.2

±

5

±
±

15
60
50
25

8

0.5 0

0.2 0

±

15

±

60

±

60

±

30

±

±

±
±
±

0.5

±

±

5.0
20
10
10

±

8

0.5 dB

0.2 dB

±

15 mV

±

60 mV

±

60 mV

±

30 mV

Crosstalk (Note 6) A Side to B Side or −65 −65 dB

B Side to A Side

=

Output Noise (Note 12) f

250 kHz N 25 25

CLK

20 kHz Bandwidth BP 250 250 µV
100:1 Mode LP 220 220

=

Clock Feedthrough (Note 13) f
Minimum Output R

V

OUT

Voltage Swing (All Outputs) −2.2 −2.2

250 kHz 100:1 Mode 2 2 mV

CLK

=

5k +1.6

L

=

R

3.5k +1.5 +1.5 V

L

±

1.5

±

1.4

+1.6

±

1.4 V

(All outputs) −2.1 −2.1
GBW Op Amp Gain BW Product 5 5 MHz
SR Op Amp Slew Rate 18 18 V/µs
I

sc

Maximum Output
Short Circuit

Source (All Outputs) 10 10 mA

Current (Note 7) Sink 20 20 mA

Units

%

%

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Logic Input Characteristics

=

Boldface limits apply for T

MIN

to T

MAX

; all other limits T

Parameter Conditions

+

−

=

=

+5V, V

CMOS Clock MIN Logical “1” V
Input Voltage MAX Logical “0” V

MIN Logical “1” V

MAX Logical “0” V
TTL Clock MIN Logical “1” V
Input Voltage MAX Logical “0” V

MIN Logical “1” V

MAX Logical “0” V
CMOS Clock MIN Logical “1” V
Input Voltage MAX Logical “0” V

MIN Logical “1” V

MAX Logical “0” V
TTL Clock MIN Logical “1” V
Input Voltage MAX Logical “0” V

Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is in­tended to be functional. These ratings do not guarantee specific performance limits, however. For guaranteed specifications and test conditions, see the Electrical
Characteristics. The guaranteed specifications apply only for the test conditions listed. Some performance characteristics may degrade when the device is not op­erated under the listed test conditions.

Note 2: When the input voltage (V
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.

Note 3: The maximum power dissipation must be derated at elevated temperatures and is dictated by T
allowable power dissipation at any temperature is P

=

T

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

JMAX

66˚C/W.

Note 4: Theaccuracy of the Q value is a function of the center frequency (f
Note 5: V
Note 6: Crosstalk between the internal filter sections is measured by applyinga1V

of the other bandpass filter section. The crosstalk is the ratio between the output of the grounded filter section and the 1 V
Note 7: 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.

Note 8: Typicals are at 25˚C and represent most likely parametric norm.
Note 9: Tested limits are guaranteed to National’s AOQL (Average Outgoing Quality Level).
Note 10: Design limits are guaranteed to National’s AOQL (Average Outgoing Quality Level) but are not 100%tested.
Note 11: Human body model, 100 pF discharged through a 1.5 kΩ resistor.
Note 12: In 50:1 mode the output noise is 3 dB higher.
Note 13: In 50:1 mode the clock feedthrough is 6 dB higher.
Note 14: A military RETS specification is available upon request.

os1,Vos2

, and V

os3

LSh
+

=

LSh
+

=

LSh
+

=

LSh
+

=

LSh
+

=

LSh
+

=

LSh

) at any pin exceeds the power supply rails (V

IN

refer to the internal offsets as discussed in the Applications Information section 3.4.

−5V, +3.0 +3.0 +3.0 V

=

0V −3.0 −3.0 −3.0 V

−

=

+10V, V

=

+5V, V

=

+10V, V

=

+2.5V, V

=

+5V, V

=

+5V, V

=

0V, +8.0 +8.0 +8.0 V

+5V +2.0 +2.0 +2.0 V

−

=

−5V, +2.0 +2.0 +2.0 V

0V +0.8 +0.8 +0.8 V

−

=

0V, +2.0 +2.0 +2.0 V

0V +0.8 +0.8 +0.8 V

−

=

−2.5V, +1.5 +1.5 +1.5 V

0V −1.5 −1.5 −1.5 V

−

=

0V, +4.0 +4.0 +4.0 V

+2.5V +1.0 +1.0 +1.0 V

−

=

0V, +2.0 +2.0 +2.0 V

+

=

0V, V

0V +0.8 +0.8 +0.8 V

D

=

D

)/θJAor the number given in the Absolute Maximum Ratings, whichever is lower. For this device,

(T

JMAX−TA

=

T

25˚C.

A

J

LMF100CCN LMF100CIWM

Typical Tested Design Typical Tested Design

(Note 8) Limit Limit (Note 8) Limit Limit

(Note 9) (Note 10) (Note 9) (Note 10)

<

IN

). This is illustrated in the curves under the heading “Typical Peformance Characteristics”.

0

RMS

>

V−or V

V+) the absolute value of current at that pin should be limited

IN

, θJA, and the ambient temperature, TA. The maximum

JMAX

10 kHz signal to one bandpass filter section input and grounding the input

input signal of the other section.

RMS

Units

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Typical Performance Characteristics

Power Supply Current vs
Power Supply Voltage

Positive Output Swing
vs Temperature

Negative Output Voltage
Swing vs Load Resistance

DS005645-40

DS005645-43

Power Supply Current vs
Temperature

Negative Output Swing
vs Temperature

f

Ratio vs Q

CLK/f0

DS005645-41

DS005645-44

Output Swing vs
Supply Voltage

Positive Output Voltage
Swing vs Load Resistance

f

Ratio vs Q

CLK/f0

DS005645-42

DS005645-45

f

CLK/f0

Ratio vs f

CLK

DS005645-46

DS005645-49

f

CLK/f0

Ratio vs f

CLK

DS005645-47

DS005645-50

f

CLK/f0

Ratio vs f

DS005645-48

CLK

DS005645-51

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Typical Performance Characteristics (Continued)

Ratio vs f

f

CLK/f0

CLK

Q Deviation vs Clock
Frequency

Q Deviation vs Clock
Frequency

DS005645-52

DS005645-55

f

Ratio vs Temperature

CLK/f0

Q Deviation vs Clock
Frequency

Q Deviation vs Temperature

DS005645-53

DS005645-56

f

Ratio vs Temperature

CLK/f0

Q Deviation vs Clock
Frequency

Q Deviation vs Temperature

DS005645-54

DS005645-57

DS005645-58

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DS005645-59

DS005645-60

Typical Performance Characteristics (Continued)

Maximum f0vsQat

=

±

V

7.5V

s

DS005645-61

Maximum f0vsQat

=

±

V

s

LMF100 System Block Diagram

5.0V

DS005645-62

Maximum f0vsQat

=

±

V

2.5V

s

DS005645-63

DS005645-1

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Pin Descriptions

LP(1,20),
BP(2,19),
N/AP/HP(3,18)

INV(4,17) The inverting input of the

S1(5,16) S1 is a signal input pin used in

(6) This pin activates a switch that

S

A/B

+

(7) (Note 15) This is both the analog and digital

V

A

+

V

(8) (Note 15) This pin needs to be tied to V

D

−

(14), V

−

D

V

A

The second order lowpass,
bandpass and
notch/allpass/highpass outputs.
These outputs can typically swing
to within 1V of each supply when
drivinga5kΩload. For optimum
performance, capacitive loading
on these outputs should be
minimized. For signal frequencies
above 15 kHz the capacitance
loading should be kept below
30 pF.

summing opamp of each filter.
These are high impedance inputs.
The non-inverting input is
internally tied to AGND so the
opamp can be used only as an
inverting amplifier.

modes 1b, 4, and 5. The input
impedance is 1/f
pin should be driven with a source

x 1 pF. The

CLK

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

connects one of the inputs of each
filter’s second summer either to
AGND (S
lowpass (LP) output (S

+

). This offers the flexibility

V

tied to V−)ortothe

A/B

A/B

needed for configuring the filter in
its various modes of operation.

positive supply.

except when the device is to
operate on a single 5V supply and
a TTL level clock is applied. For
5V, TTL operation, V
tied to ground (0V).

(13) Analog and digital negative

supplies. V
derived from the same source.

−

A

and V

+

D

−

should be

D

should be

They have been brought out
separately so they can be
bypassed by separate capacitors,
if desired. They can also be tied
together externally and bypassed
with a single capacitor.

tied to

LSh(9) Level shift pin. This is used to

accommodate various clock levels
with dual or single supply
operation. With dual
and CMOS (

±

±

5V supplies

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

For 0V–10V single supply
operation the AGND pin should be
biased at +5V and the LSh pin
should be tied to the system
ground for TTL clock levels. LSh

±

should be biased at +5V for

5V

CMOS clock levels.
The LSh pin is tied to system

±

ground for

2.5V operation. For

single 5V operation the LSh and

+ pins are tied to system

V

D

ground for TTL clock levels.

CLK(10,11) 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%, especially when
clock frequencies above 200 kHz
are used. This allows the
maximum time for the internal
opamps to settle, which yields
optimum filter performance.

+

50/100(12)
(Note 15)

By tying this pin to V
to filter center frequency ratio is

a 50:1 clock

obtained. Tying this pin at
mid-supply (i.e., system ground
with dual supplies) or to V

−

allows

the filter to operate at a 100:1

+

AGND(15) This is the analog ground pin.

clock to center frequency ratio.

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

Note 15: This device is pin-for-pin compatible with the MF10 except for the
following changes:

1. Unlike the MF10, the LMF100 has a single positive supply pin (V

2. On the LMF100 V
on the MF10.

3. Unlike the MF10, the LMF100 does not support the current limiting mode.
When the 50/100 pin is tied to V

+

is a control pin and is not the digital positive supply as

D

−

the LMF100 will remain in the 100:1 mode.

+).

A

www.national.com 8

1.0 Definitions of Terms

f

: the frequency of the external clock signal applied to pin

CLK

10 or 11.

f

: center frequency of the second order function complex

0

pole pair. f
LMF100, and is the frequency of maximum bandpass gain.
(

Figure 1

f

notch

notch outputs.

f

: the center frequency of the second order complex zero

z

pair, if any. If f
observed as the frequency of a notch at the allpass output.
(

Figure 13

Q: “quality factor” of the 2nd order filter. Q is measured at the
bandpass outputs of the LMF100 and is equal to f
by the −3 dB bandwidth of the 2nd order bandpass filter (

ure 1

filter responses as shown in

: the quality factor of the second order complex zero pair,

Q

z

if any. Q
written:

is measured at the bandpass outputs of the

0

).

: the frequency of minimum (ideally zero) gain at the

is different from f0and if Qzis high, it can be

z

).

divided

0

Fig-

). The value of Q determines the shape of the 2nd order

Figure 6

.

is related to the allpass characteristic, which is

Z

where Q

H
H

(

H

(

H

f→f
below the center frequency (

=

Q for an all-pass response.

Z

: the gain (in V/V) of the bandpass output at f=f0.

OBP

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

OLP

Figure 2

).

: the gain (in V/V) of the highpass output as f→f

OHP

Figure 3

).

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

ON

/2, when the notch filter has equal gain above and

CLK

Figure 4

). When the

CLK

low-frequency gain differs from the high-frequency gain, as
in modes 2 and 3a (
tities below are used in place of H

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

H

ON1

: the gain (in V/V) of the notch output as f→f

H

ON2

Figure 10

and

Figure 12

.

ON

), the two quan-

/2.

CLK

/2

(a)

DS005645-19

FIGURE 1. 2nd-Order Bandpass Response

DS005645-20

(b)

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