NSC MF4

MF4 4th Order Switched Capacitor Butterworth
Lowpass Filter
General Description
Features
The MF4 is a versatile, easy to use, precision 4th order Butterworth low-pass filter. Switched-capacitor techniques eliminate external component requirements and allow a
clock-tunable cutoff frequency. The ratio of the clock frequency to the low-pass cutoff frequency is internally set to 50
to 1. A Schmitt trigger clock input stage allows two clocking
options, either self-clocking (via an external resistor and capacitor) for stand-alone applications, or for tighter cutoff frequency control an external TTL or CMOS logic compatible
clock can be applied. The maximally flat passband frequency
response together with a DC gain of 1 V/V allows cascading
MF4 sections together for higher order filtering.
n
n
n
n
n
n
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n
n
Low Cost
Easy to use
8-pin mini-DIP or 14-pin wide-body S.O.
No external components
5V to 14V supply voltage
Cutoff frequency range of 0.1 Hz to 20 kHz
Cutoff frequency accuracy of ± 0.3% typical
Cutoff frequency set by external clock
Separate TTL and CMOS/Schmitt-trigger clock inputs
Connection Diagram
Dual-In-Line Package
DS005064-2
Order Number MF4CN-50
See NS Package Number N08E
Block Diagram
DS005064-1
TRI-STATE ® is a registered trademark of National Semiconductor Corp.
© 1999 National Semiconductor Corporation
DS005064
www.national.com
MF4 4th Order Switched Capacitor Butterworth Lowpass Filter
July 1999
Block Diagram
(Continued)
Pin Descriptions
Pin
Pin
Function
#
Name
1
CLK IN
A CMOS Schmitt-trigger input to be
used with an external CMOS logic level
clock. Also used for self clocking
Schmitt-trigger oscillator (see section
1.1).
2
CLK R
A TTL logic level clock input when in
split supply operation ( ± 2.5V to ± 7V)
with L. Sh tied to system ground. This
pin becomes a low impedance output
when L. Sh is tied to V−. Also used in
conjunction with the CLK IN pin for a
self clocking Schmitt-trigger oscillator
(see section 1.1). The TTL input signal
must not exceed the supply voltages
by more than 0.2V.
3
L. Sh
Level shift pin; selects the logic
threshold levels for the clock. When
tied to V− it enables an internal tri-state
buffer stage between the Schmitt
trigger and the internal clock level shift
stage thus enabling the CLK IN
Schmitt-trigger input and making the
CLK R pin a low impedance output.
When the voltage level at this input
exceeds 25% (V+ − V−) + V− the
internal tri-state buffer is disabled
allowing the CLK R pin to become the
clock input for the internal clock
level-shift stage. The CLK R threshold
level is now 2V above the voltage on
the L. Sh pin. The CLK R pin will be
compatible with TTL logic levels when
the MF4 is operated on split supplies
with the L. Sh pin connected to system
ground.
5
FILTER
OUT
The output of the low-pass filter. It will
typically sink 0.9 mA and source 3 mA
and swing to within 1V of each supply
rail.
6
AGND
The analog ground pin. This pin sets
the DC bias level for the filter section
and must be tied to the system ground
for split supply operation or to
mid-supply for single supply operation
(see section 1.2). When tied to
mid-supply this pin should be well
bypassed.
7,
4
V+, V−
The positive and negative supply pins.
The total power supply range is 5V to
14V. Decoupling these pins with 0.1 µF
capacitors is highly recommended.
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2
Pin
Pin
#
Name
8
FILTER
IN
Function
The input to the low-pass filter. To
minimize gain errors the source
impedance that drives this input should
be less than 2K (see section 1.3 of the
Application Hints). For single supply
operation the input signal must be
biased to mid-supply or AC coupled
through a capacitor.
Absolute Maximum Ratings (Notes 1, 2)
Storage Temperature
ESD Susceptibility (Note 13)
Soldering Information (10 sec.)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Supply Voltage (V+–V−)
Voltage At Any Pin
Operating Ratings
14V
V+ + 0.2V
V− − 0.2V
5 mA
20 mA
500 mW
Input Current at Any Pin (Note 14)
Package Input Current (Note 14)
Power Dissipation (Note 15)
Temperature Range
MF4CN-50
Supply Voltage (V+–V−)
150˚C
800 V
260˚C
(Note 2)
Tmin ≤ TA ≤ Tmax
0˚C≤ TA≤ 70˚C
5V to 14V
Filter Electrical Characteristics
The following specifications apply for fCLK ≤ 250 kHz (Note 5) unless otherwise specified. Boldface limits apply for TMIN
to TMAX; all other limits TA = TJ = 25˚C.
Parameter
Conditions
Typical
Tested
Design
(Note 10)
Limit
Limit
(Note 11)
(Note 12)
Unit
V+ = +5V, V− = −5V
fc, Cutoff Frequency
Min
0.1
Range (Note 3)
Max
20k
fclk = 250 kHz
Supply Current
Maximum Clock
Filter Output
2.5
3.5
3.5
Hz
mA
Vin = 0V
Feedthrough
25
mV
(Peak-to-Peak)
Rsource ≤ 2 kΩ
0.0
± 0.15
fclk/fc, Clock to Cutoff
49.96
49.96
Frequency Ratio
± 0.3%
± 1%
Ho, DC Gain
± 0.15
± 15
fclk/fc Temperature
dB
ppm/˚C
Coefficient
Stopband Attenuation (Min)
−25.0
at 2 fc
DC Offset Voltage
−24.0
−24.0
−200
RL = 10 kΩ
Minimum Output Swing
Output Short Circuit
Current (Note 8)
dB
mV
+4.0
+3.5
+3.5
−4.5
−4.0
−4.0
V
V
Source
50
mA
Sink
1.5
mA
Dynamic Range (Note 4)
80
f = 6000 Hz
Additional Magnitude
Response Test Points
f = 4500 Hz
(Note 6)
fclk = 250 kHz
dB
−7.57
−7.57
± 0.47
± 0.47
−1.44
−1.44
± 0.12
± 0.12
dB
f = 3000 Hz
dB
f = 2250 Hz
V+ = +2.5V, V− = −2.5V
fc Cutoff Frequency
min
0.1
Range (Note 3)
max
10k
Supply Current
fclk = 250 kHz
1.5
Vin = 0V
15
2.25
2.25
Hz
mA
Maximum Clock
Feedthrough
Filter Output
mV
(Peak-to-Peak)
Rsource ≤ 2 kΩ
0.0
± 0.15
fclk/fc, Clock to Cutoff
50.07
50.07
Frequency Ratio
± 0.3%
± 1.0%
Ho, DC Gain
± 25
fCLK/fC Temperature
± 0.15
dB
ppm/˚C
Coefficient
3
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Filter Electrical Characteristics
(Continued)
The following specifications apply for fCLK ≤ 250 kHz (Note 5) unless otherwise specified. Boldface limits apply for TMIN
to TMAX; all other limits TA = TJ = 25˚C.
Parameter
Conditions
Typical
Tested
Design
(Note 10)
Limit
Limit
Unit
(Note 11)
(Note 12)
−24.0
−24.0
V+ = +2.5V, V− = −2.5V
Stopband Attenuation (Min)
−25.0
at 2 fc
DC Offset Voltage
RL = 10 kΩ
Minimum Output Swing
Output Short Circuit
Current (Note 8)
dB
−150
mV
+1.5
+1.0
+1.0
−2.2
−1.7
−1.7
V
V
Source
28
mA
Sink
0.5
mA
78
dB
Dynamic Range (Note 4)
fclk = 250 kHz
Additional Magnitude
Response Test Points
(Note 6)
(fc = 5 kHz)
f = 6000 Hz
Magnitude at
f = 4500 Hz
(fc = 2.5 kHz)
−7.57
−7.57
± 0.47
± 0.47
−1.46
−1.46
± 0.12
± 0.12
dB
dB
f = 3000 Hz
Magnitude
dB
f = 2250 Hz
Logic Input-Output Characteristics
The following specifications apply for V− = 0V (Note 7) unless otherwise specified. Boldface limits apply for TMIN to TMAX; all
other limits TA = TJ = 25˚C.
Parameter
Conditions
Typical
Tested
(Note 10)
Limit
Design
Limit
(Note 11)
(Note 12)
6.1
6.1
Unit
SCHMITT TRIGGER
VT+, Positive Going Threshold
Min
Voltage
Max
Min
V+ = 10V
7.0
V+ = 5V
3.5
Max
VT−, Negative Going Threshold
Min
Voltage
Max
Min
V+ = 10V
3.0
V+ = 5V
1.5
Max
Hysteresis (VT+–VT−)
Min
V+ = 10V
4.0
Max
Min
V+ = 5V
2.0
Max
Minimum Logical “1” Output Voltage
I0 = −10 µA
(pin 2)
Maximum Logical “0” Output Voltage
I0 = 10 µA
(pin 2)
V+ = 10V
V+ = 5V
V+ = 10V
V+ = 5V
3.1
3.1
4.4
4.4
1.3
1.3
3.8
3.8
0.6
0.6
1.9
1.9
2.3
2.3
7.6
7.6
1.2
1.2
3.8
3.8
V
V
V
V
V
9.0
9.0
V
4.5
4.5
V
1.0
1.0
V
0.5
0.5
V
mA
6.0
3.0
3.0
1.5
0.75
0.75
mA
CLK R Shorted
V+ = 10V
V+ = 5V
V+ = 10V
5.0
2.5
2.5
mA
to V+
V+ = 5V
1.3
0.65
0.65
mA
Minimum Output Source Current
CLK R Shorted
(pin 2)
to Ground
Maximum Output Sink Current
(pin 2)
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V
8.9
4
Logic Input-Output Characteristics
(Continued)
The following specifications apply for V− = 0V (Note 7) unless otherwise specified. Boldface limits apply for TMIN to TMAX; all
other limits TA = TJ = 25˚C.
Parameter
Conditions
Typical
Tested
(Note 10)
Limit
Design
Limit
(Note 11)
(Note 12)
Unit
TTL CLOCK INPUT, CLK R PIN (Note 9)
Maximum VIL, Logical “0” Input Voltage
0.8
Minimum VIH, Logical “1” Input Voltage
2.0
V
2.0
µA
Maximum Leakage Current at CLK R Pin
L. Sh Pin at Mid-Supply
V
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. AC and DC electrical specifications do not apply when operating
the device beyond its specified operating conditions.
Note 2: All voltages are with respect to GND.
Note 3: The cutoff frequency of the filter is defined as the frequency where the magnitude response is 3.01 dB less than the DC gain of the filter.
Note 4: For ± 5V supplies the dynamic range is referenced to 2.82 Vrms (4V peak) where the wideband noise over a 20 kHz bandwidth is typically 280 µVrms for
the MF4-50. For ± 2.5V supplies the dynamic range is referenced to 1.06 Vrms (1.5V peak) where the wideband noise over a 20 kHz bandwidth is typically 130 µVrms.
Note 5: The specifications for the MF4 have been given for a clock frequency (fCLK) of 250 kHz or less. Above the clock frequency the cutoff frequency begins to
deviate from the specified error band of ± 0.6% but the filter still maintains its magnitude characteristics. See Application Hints.
Note 6: Besides checking the cutoff frequency (fc) and the stopband attenuation at 2 fc, two additional frequencies are used to check the magnitude response of the
filter. The magnitudes are referenced to a DC gain of 0.0 dB.
Note 7: For simplicity all the logic levels have been referenced to V− = 0V (except for the TTL input logic levels). The logic levels will scale accordingly for ± 5V and
± 2.5V supplies.
Note 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 and then shorting that
output to the positive supply. These are worst case conditions.
Note 9: The MF4 is operating with symmetrical split supplies and L. Sh is tied to ground.
Note 10: Typicals are at 25˚C and represent most likely parametric norm.
Note 11: Guaranteed to National’s Average Outgoing Quality Level (AOQL).
Note 12: Guaranteed, but not 100% production tested. These limits are not used to determine outgoing quality levels.
Note 13: Human body model; 100 pF discharged through a 1.5 kΩ resistor.
Note 14: When the input voltage (VIN) at any pin exceeds the power supply rails (VIN < V−or VIN > V+) the absolute value of current at that pin should be limited
to 5 mA or less. The 20 mA package input current limits the number of pins that can exceed the power supply boundaries with a 5 mA current limit to four.
Note 15: Thermal Resistance
θJA (Junction to Ambient) N Package:
105˚C/W.
5
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Typical Performance Characteristics
Power Supply Current
vs Power Supply Voltage
Power Supply Current
vs Clock Frequency
DS005064-26
Positive Voltage Swing
vs Power Supply Voltage
DS005064-27
Negative Voltage Swing
vs Power Supply Voltage
DS005064-29
Negative Voltage Swing
vs Temperature
DS005064-28
Positive Voltage Swing
vs Temperature
DS005064-31
DS005064-30
fCLK/fc Deviation
vs Power Supply Voltage
DS005064-32
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Power Supply Current
vs Temperature
fCLK/fc Deviation
vs Clock Frequency
DS005064-34
6
DS005064-36
Typical Performance Characteristics
fCLK/fc Deviation
vs Temperature
(Continued)
DC Gain Deviation
vs Power Supply Voltage
DS005064-38
DC Gain Deviation
vs Temperature
DS005064-40
DS005064-41
1.2 POWER SUPPLY
1.0 MF4 Application Hints
The MF4 can be powered from a single supply or split supplies. The split supply mode shown in Figures 2, 3 is the
most flexible and easiest to implement. Supply voltages of
± 5V to ± 7V enable the use of TTL or CMOS clock logic levels. Figure 4 shows AGND resistor-biased to V+/2 for single
supply operation. In this mode only CMOS clock logic levels
can be used, and input signals should be capacitor-coupled
or biased near mid-supply.
The MF4 is a non-inverting unity gain low-pass fourth-order
Butterworth switched-capacitor filter. The switched-capacitor
topology makes the cutoff frequency (where the gain drops
3.01 dB below the DC gain) a direct ratio of the clock frequency supplied to the filter. Internal integrator time constants set the filter’s cutoff frequency. The resistive element
of these integrators is actually a capacitor which is
“switched” at the clock frequency (for a detailed discussion
see Input Impedance Section). Varying the clock frequency
changes the value of this resistive element and thus the time
constant of the integrators. The clock-to-cutoff-frequency ratio (fCLKfc) is set by the ratio of the input and feedback capacitors
in
the
integrators.
The
higher
the
clock-to-cutoff-frequency ratio the closer this approximation
is to the theoretical Butterworth response. The MF4 is available in fCLK/fc ratios of 50:1 (MF4-50).
1.3 INPUT IMPEDANCE
The MF4 low-pass filter input (FILTER IN) is not a high impedance buffer input. This input is a switched-capacitor resistor equivalent, and its effective impedance is inversely
proportional to the clock frequency. The equivalent circuit of
the filter’s input can be seen in Figure 5. The input capacitor
charges to Vin during the first half of the clock period; during
the second half the charge is transferred to the feedback capacitor. The total transfer of charge in one clock cycle is
therefore Q = CinVin, and since current is defined as the flow
of charge per unit time, the average input current becomes
Iin = Q/T
1.1 CLOCK INPUTS
The MF4 has a Schmitt-trigger inverting buffer which can be
used to construct a simple R/C oscillator. Pin 3 is connected
to V− which makes Pin 2 a low impedance output. The oscillator’s frequency is nominally
(where T equals one clock period) or
The equivalent input resistor (Rin) then can be expressed as
(1)
which, is typically
The input capacitor is 2 pF, so
(2)
for VCC = 10V.
Note that fCLK is dependent on the buffer’s threshold levels
as well as the resistor/capacitor tolerance (see Figure 1).
Schmitt-trigger threshold voltage levels can change significantly causing the R/C oscillator’s frequency to vary greatly
from part to part.
Where accurate cutoff frequency is required, an external
clock can be used to drive the CLK R input of the MF4. This
input is TTL logic level compatible and also presents a very
light load to the external clock source (∼2 µA). With split supplies and the level shift (L. Sh) tied to system ground, the
logic level is about 2V. (See the Pin Description for L. Sh).
The higher the clock-to-cutoff-frequency ratio, the greater
equivalent input resistance for a given clock frequency.
This input resistance will form a voltage divider with the
source impedance (Rsource). Since Rin is inversely proportional to the cutoff frequency, operation at higher cutoff frequencies will be more likely to load the input signal which
would appear as an overall decrease in gain to the output of
the filter. Since the filter’s ideal gain is unity, the overall gain
is given by:
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1.0 MF4 Application Hints
2.1 A LOW-PASS DESIGN EXAMPLE
(Continued)
Suppose the amplitude response specification in Figure 8 is
given. Can the MF4 be used? The order of the Butterworth
approximation will have to be determined using Equation (1):
If the MF were set up for a cutoff frequency of 10 kHz the input impedance would be:
Since n can only take on integer values, n = 4. Therefore the
MF4 can be used. In general, if n is 4 or less a single MF4
stage can be utilized.
In this example with a source impedance of 10K the overall
gain, if the MF4 had an ideal gain of 1 or 0 dB, would be:
Likewise, the attenuation at fs can be found using Equation
(4) with the above values and n = 4:
Attn (2 kHz) = 10 log [1 + 100.1 − 1) (2 kHz/1 kHz)8] =
18.28 dB
This result also meets the design specification given in Figure 8 again verifying that a single MF4 section will be adequate.
Since the MF4’s cutoff frequency (fc), which corresponds to
a gain attenuation of −3.01 dB, was not specified in this example, it needs to be calculated. Solving Equation (4) where
f = fc as follows:
Since the maximum overall gain error for the MF4 is
± 0.15 dB with Rs ≤ 2 kΩ the actual gain error for this case
would be +0.06 dB to −0.24 dB.
1.4 CUTOFF FREQUENCY RANGE
The filter’s cutoff frequency (fc) has a lower limit due to leakage currents through the internal switches draining the
charge stored on the capacitors. At lower clock frequencies
these leakage currents can cause millivolts of error, for example:
where fc = fCLK/50. To implement this example for the
MF4-50 the clock frequency will have to be set to fCLK =
50(1.184 kHz) = 59.2 kHz, or for the MF4-100, fCLK = 100
(1.184 kHz) = 118.4 kHz.
The propagation delay in the logic and the settling time required to acquire a new voltage level on the capacitors limit
the filter’s accuracy at high clock frequencies. The amplitude
characteristic on ± 5V supplies will typically stay flat until fCLK
exceeds 750 kHz and then peak at about 0.5 dB at the corner frequency with a 1 MHz clock. As supply voltage drops to
± 2.5V, a shift in the fCLK/fc ratio occurs which will become
noticeable when the clock frequency exceeds 250 kHz. The
response of the MF4 is still a good approximation of the ideal
Butterworth low-pass characteristic shown in Figures 6, 7.
2.2 CASCADING MF4s
When a steeper stopband attenuation rate is required, two
MF4s can be cascaded (Figure 9) yielding an 8th order slope
of 48 dB per octave. Because the MF4 is a Butterworth filter
and therefore has no ripple in its passband when MF4s are
cascaded, the resulting filter also has no ripple in its passband. Likewise the DC and passband gains will remain at
1V/V. The resulting response is shown in Figure 10, Figure
11.
In determining whether the cascaded MF4s will yield a filter
that will meet a particular amplitude response specification,
as above, Equations (5), (6) can be used, shown below.
2.0 Designing With The MF4
Given any low-pass filter specification, two equations will
come in handy in trying to determine whether the MF4 will do
the job. The first equation determines the order of the
low-pass filter required to meet a given response specification:
(5)
(3)
where n is the order of the filter, Amin is the minimum stopband attenuation (in dB) desired at frequency fs, and Amax is
the passband ripple or attenuation (in dB) at cutoff frequency
fb. If the result of this equation is greater than 4, more than a
single MF4 is required.
The attenuation at any frequency can be found by the following equation:
Attn (f) = 10 log [1 + (100.1Amax − 1) (f/fb)2n] dB
(4)
where n = 4 for the MF4.
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(6)
where n = 4 (the order of each filter).
Equation (5) will determine whether the order of the filter is
adequate (n ≤ 4) while Equation (6) can determine the actual
stopband attenuation and cutoff frequency (fc) necessary to
obtain the desired frequency response. The design procedure would be identical to the one shown in section 2.0.
8
2.0 Designing With The MF4
2.4 ALIASING CONSIDERATIONS
Aliasing effects have to be considered when input signal frequencies exceed half the sampling rate. For the MF4 this
equals half the clock frequency (fCLK). When the input signal
contains a component at a frequency higher than half the
clock frequency fCLK/2, as in Figure 14a, that component will
be “reflected” about fCLK/2 into the frequency range below
fCLK/2, as in Figure 14b. If this component is within the passband of the filter and of large enough amplitude it can cause
problems. Therefore, if frequency components in the input
signal exceed fCLK2 they must be attenuated before being
applied to the MF4 input. The necessary amount of attenuation will vary depending on system requirements. In critical
applications the signal components above fCLK/2 will have to
be attenuated at least to the filter’s residual noise level.
(Continued)
2.3 CHANGING CLOCK FREQUENCY
INSTANTANEOUSLY
The MF4 will respond favorably to an instantaneous change
in clock frequency. If the control signal in Figure 12 is low the
MF4-50 has a 100 kHz clock making fc = 2 kHz; when this
signal goes high the clock frequency changes to 50 kHz
yielding fc = 1 kHz. As the Figure illustrates, the output signal
changes quickly and smoothly in response to a sudden
change in clock frequency.
The step response of the MF4 in Figure 13 is dependent on
fc. The MF4 responds as a classical fourth-order Butterworth
low-pass filter.
DS005064-11
FIGURE 1. Schmitt Trigger R/C Oscillator
DS005064-12
VIH ≥ 0.8 Vcc
VIL ≤ 0.2 Vcc
Vcc = V+ − V−
FIGURE 2. Split Supply Operation with CMOS Level Clock
9
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2.0 Designing With The MF4
(Continued)
DS005064-13
FIGURE 3. Split Supply Operation with TTL Level Clock
DS005064-14
FIGURE 4. Single Supply Operation. ANGD Resistor Biased to V+/2
DS005064-15
a) Equivalent Circuit for MF4 Filter Input
DS005064-20
b) Actual Circuit for MF4 Filter Input
FIGURE 5. MF4 Filter Input
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10
2.0 Designing With The MF4
(Continued)
DS005064-44
DS005064-46
FIGURE 6. MF4-50 Amplitude Response with ± 5V
Supplies
FIGURE 7. MF4-50 Amplitude Response with ± 2.5V
Supplies
DS005064-22
FIGURE 8. Design Example Magnitude Response Specification where the Response of
the Filter Design must fall within the shaded area of the specification
11
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2.0 Designing With The MF4
(Continued)
DS005064-23
FIGURE 9. Cascading Two MF4s
DS005064-47
FIGURE 10. One MF4-50
vs Two MF4-50s Cascaded
DS005064-24
FIGURE 12. MF4-50 Abrupt Clock Frequency Change
DS005064-48
FIGURE 11. Phase Response
of Two Cascaded MF4-50s
DS005064-19
FIGURE 13. MF4-50 Input Step Response
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12
2.0 Designing With The MF4
(Continued)
DS005064-16
(a) input signal spectrum
DS005064-17
(b) Output signal spectrum. Note that the input signal
at fc/2 + f causes an output signal to appear at fc/2 − f.
FIGURE 14. The phenomenon of aliasing in sampled-data systems. An input signal whose
frequency is greater than one-half the sampling frequency will cause an output to appear
at a frequency lower than one-half the sampling frequency. In the MF4, fs = fCLK.
13
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MF4 4th Order Switched Capacitor Butterworth Lowpass Filter
Physical Dimensions
inches (millimeters) unless otherwise noted
Molded Dual-In-Line Package (N)
Order Number MF4CN-50
NS Package Number N08E
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