ZETEX ZXF36L01W24

ZXF36L01
VARIABLE Q FILTER
DESCRIPTION
APPLICATIONS
The ZXF36L01 is a versatile analog high Q bandpass Many filter applications including: filter. The device contains two sections:
• Audio bandpass and notch
1
Variable Q bandpass filter.
• Micro controlled frequency
2
Mixer block.
• Adaptive filtering
The basic filter section requires 2 resistors and 2 • Sonar and Ultrasonic Systems
capacitors to set the centre frequency. The filter • Instrumentation
operates up to a frequency of 150kHz. Two external
resistors control filter Q Factor. The Q can be varied up
to 50.
FEATURES AND BENEFITS
The mixer is included to extend the frequency range up •
to 700kHz and to permit the centre frequency to be •
tuned. The local oscillator can be any waveform, •
making microprocessor control convenient.
•
•
Centre Frequency up to 700kHz
Tuneable centre frequency
Variable Q
Low power
Standby mode for improved battery life
ORDERING INFORMATION
SYSTEM DIAGRAM
ISSUE 3 - JANUARY 2002
1
PART NUMBER
PACKAGE
PART
MARK
ZXF36L01W24
SO24W
ZXF36L01
PART NUMBER
CONTAINER
INCREMENT
ZXF36L01W24TC
Reel 13”
330mm
1000
ZXF36L01W24
Tube
31
ZXF36L01
ABSOLUTE MAXIMUM RATINGS
Voltage on any pin
Operating temperature range
Storage temperature
7.0V (relative to Vss)
0 to 70°C (de-rated for -40 to 85ºC)
-55 to 125°C
ELECTRICAL CHARACTERISTICS
Test Coνditions: Temperature =25°C, VDD = 5.00V, VSS = 0.00V
GENERAL CHARACTERISTICS
Parameter
Operating current
Conditions
PD= V DD
Shutdown current
PD = V SS
IIH (PD)
VIH =5V (WRT V SS )
IIL (PD)
VIL =0V (WRT V SS )
Min.
Typical
Max.
Units
2.2
3.4
4.5
mA
160
300
µA
1.0
µA
-1.0
µA
FILTER CHARACTERISTICS
Max. operating frequency
150
Q usable range
0.5
kHz
50
Centre frequency temperature
coefficient
Q=30, fo = 1kHz
Note 1
10
ppm/°C
Average Q temperature
coefficient
Q=30, fo = 1kHz
Note 2
0.1
% /°C
Voltage noise
1 – 100 kHz
20
Input impedance
Max. output swing
30
Output load ≥10 kΩ
nV/√ Hz
50
kΩ
1.6
V pk-pk
Output sink current
150
µA
Output source current
150
µA
MIXER CHARACTERISTICS
Max. operating frequency
700
kHz
Maximum signal input
300
mV pk-pk
Maximum Local Oscillator input
100
mV pk-pk
Minimum Local Oscillator input
5
mV pk-pk
Local Oscillator input Impedance
60
Ω
NOTE 1
Centre frequency temperature coefficient is dominated by the external R & C components. On chip drift is
negligable.
Note 2
Average Q temperature coefficient is dominated by the external R components.
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ZXF36L01
TYPICAL ELECTRICAL CHARACTERISTICS
Test Coνditions:VDD = 5.00V, VSS = 0.00V
(Fo = 140 KHz)
Typical Gain at Fo V Q Factor
Gain at fo describes the peak gain of
the notch pass filter. This gain is
defined by the value of Q Factor.
50
45
Gain(dB)
40
35
30
25
20
10
20
30
40
50
60
70
80
90
100
Q Factor
Q Factor V Frequency
The curve shows Q Factor over
frequency for a fixed loop gain
(Rf/Ri).
32
30
28
QFactor
26
24
22
20
18
16
0
20
40
60
80
100
120
140
160
180
200
Frequency (kHz)
Components used: 1/8 watt metal
film resistors (+/- 50 ppm). Ceramic
capacitors (+/- 50 ppm).
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ZXF36L01
DESCRIPTION OF PIN FUNCTIONS
VDD
Positive supply connection (5 volts). Both pins to be connected.
To be decoupled with a 100nF capacitor to VSS.
VSS
Negative supply connection; system ground (0 volts). Both pins to be connected.
BG
Bias Generator output. To be decoupled with a 100nF capacitor to VSS.
BI
Bias inputs for internal circuitry, both to be connected to BG.
(or external supply referenced to VSS)
PD
Active low. This feature can be used to reduce power consumption for applications that
have a standby mode.
FI1,Fl2
Filter input, FI1 or FI2 depending on filter configuration.
FO
Filter output for all configurations.
LO
Local Oscillator signal input.
MXI
Mixer signal input.
MXO
Mixer signal output.
C1, RC1
Phase advance network nodes. Values R and C set centre frequency, fo.
R2, RC2
Phase retard network nodes. Values R and C set centre frequency, fo.
GP1,2,3
Loop gain programming nodes.
CONNECTION DIAGRAM
1
V SS
FI1
C1
RC1
R2
BI
MXO
RC2
GP1
GP2
GP3
V SS
V DD
FI2
FO
MXI
LO
BI
BG
N/C
N/C
N/C
PD
V DD
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ZXF36L01
FILTER CONFIGURATIONS AND RESPONSES
Notch Filter
5V
1
C
FI1
V DD
FI2
C1
FO
V SS
RC1
R
R
R2
BI
MXO
C
R=10kΩ
C=100nF
Rf=19.5kΩ
Ri=10kΩ
Ri
Rf
RC2
GP1
GP2
GP3
V SS
24
100nF
Input Signal
Output Signal
MXI
LO
BI
BG
N/C
N/C
N/C
PD
100nF
5V
V DD
100nF
Filter AC Performance
Notch Filter Gain Response
1
2πRC
Q ∝ (Rf / Ri )
5
fo =
0
Gain (dB)
-5
-10
Where R, Ri and Rf ≥10kΩ and C ≥ 50 pF
-15
-20
See “Designing for a Value of Q” for more
details.
-25
-30
-35
10
100
1000
10000
Frequency (Hz)
Notch Filter Phase Response
T y p i ca l r e sp o n se s f o r t h e ci r cu i t w i t h
component values shown in circuit diagram.
270
Phase (Degrees)
240
210
180
150
120
90
10
100
1000
Frequency (Hz)
10000
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ZXF36L01
FILTER CONFIGURATIONS AND RESPONSES (continued)
5V
1
100nF
Input Signal
V SS
FI1
C
C1
RC1
R
R
C
FO
LO
BI
MXO
BG
N/C
GP3
V SS
Rf
24
Output Signal
MXI
R2
BI
RC2
GP1
GP2
Ri
R=10kΩ
C=100nF
Rf=19.5kΩ
Ri=10kΩ
V DD
FI2
100nF
N/C
N/C
5V
PD
V DD
100nF
Filter AC Performance
Notch Pass Filter Gain Response
1
2πRC
Q ∝ (Rf / Ri)
fo =
30
25
Gain (dB)
20
Where R, Ri and Rf ≥10kΩ and C ≥ 50 pF
15
See “Designing for a Value of Q” for more
details.
10
5
0
-5
10
100
1000
10000
Frequency (Hz)
T y p i ca l r e sp o n se s f o r t h e ci r cu i t w i t h
component values shown in circuit diagram.
Notch Pass Filter Phase Response
-90
Phase (Degrees)
-120
-150
-180
-210
-240
-270
10
100
1000
10000
Frequency (Hz)
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ZXF36L01
FILTER CONFIGURATIONS AND RESPONSES (continued)
Notch Filter (with attenuating skirts)
5V
1
100nF
C
R
R2
BI
MXO
R
C
Ri
Output Signal
MXI
LO
BI
BG
N/C
N/C
RC2
GP1
GP2
Rf
24
FO
C1
RC1
R=10kΩ
C=100nF
Rf=19.5kΩ
Ri=10kΩ
V DD
FI2
V SS
FI1
Input Signal
100nF
N/C
PD
GP3
V SS
5V
V DD
100nF
Filter AC Performance
Notch Pass Filter 2 Gain Response
1
2πRC
Q ∝ (Rf / Ri)
fo =
30
20
Gain (dB)
10
Where R, Ri and Rf ≥10kΩ and C ≥ 50 pF
0
See “Designing for a Value of Q” for more
details.
The skirt ‘roll off’ away from the peak is
-20dB/decade regardless of chosen Q.
-10
-20
-30
1
10
100
1000
10000
Frequency (Hz)
Notch Pass Filter 2 Phase Response
T y p i ca l r e sp o n se s f o r t h e ci r cu i t w i t h
component values shown in circuit diagram.
120
Phase (Degrees)
90
60
30
0
-30
-60
-90
-120
1
10
100
1000
10000
Frequency (Hz)
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ZXF36L01
DESIGNING FOR A VALUE OF Q
10k
As mentioned on the configuration pages, there is a
proportional, but non-linear relationship between the
ratio of Rf and Ri, and Q.
These resistors define the gain of an inverting amplifier
that determines the peak value gain and therefore the Q
of the filter,Q is defined as:
Q=
fO
−3dB Bandwidth
2k
22k
Pin 9
Pin 11
Pin 10
Suggestion
for gain
setting
component
values. for
Below
are some
typical
values
of gain required
several example conditions:
Example1
This value of required gain is critical. As the maximum
value of Q is approached, too much gain will cause the
filter to oscillate at the centre frequency, fo. A small
reduction of gain will cause the value of Q to fall
significantly. Therefore, for high values of Q or tight
tolerances of lower values of Q, the resistor ratio must
be trimmed as shown.
Frequency dependant effects must be accounted for in
determining the appropriate gain. As the frequency
increases because of internal phase shift effects the
effective circuit gain reduces and thus Q Factor reduces.
The frequency effect is not a problem for circuits where
the fo remains constant, as the phase shifts are
accounted for permanently. For designs where Q is high
and fo is to be ‘swept’, care must be taken that a gain
appropriate at the highest frequency does not cause
oscillation at the lowest.
fo = 48kHz,
Q=60,
R = 10kΩ, C = 320pF
Rf/Ri = 36.6kΩ / 18 kΩ => 2.033
Example2
fo = 140kHz,
Q=15,
R = 10kΩ, C = 100pF
Rf/Ri = 37kΩ / 18kΩ => 2.055
It can be seen from these examples that the higher Q
example actually has a lower inverting amplifier gain.
As mentioned before, the frequency will affect the
value of gain. The Q Factor v Frequency graph
illustrates this effect.
These examples show that the gain required is
nominally 2. For the specified range of Q: 0.5 to 50
(values up to 250 are obtainable), the gain values vary
from 1.9 to 2.5 correspondingly.
Due to internal gain errors, when the absolute value
of Q is increased, the device to device variation in Q
will also increase.
This diagram shows the exponential relationship between gain and Q Factor. (fo = 140 kHz)
ISSUE 3 - JANUARY 2002
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ZXF36L01
FILTERING HIGHER FREQUENCIES USING
THE MIXER
MIXER CONFIGURATION WITH NOTCH PASS FILTER
(with attenuating skirts)
Frequencies above 150 kHz cannot be filtered directly;
the mixer enables the notch pass filter to function up to
700kHz.
The mixer can only be used with this filter configuration, as
the other types have 0dB stop bands. The mixer output
‘MXO’ becomes the input of the filter.
The signal to be filtered is mixed with another
frequency (local oscillator), chosen so that the
difference (intermediate) frequency equals the filter’s
centre frequency, fo. The local oscillator signal
waveform can be of any shape (sine, square, etc.) but
must be approximately 50% duty cycle.
As the gain of the notch filter changes with Q, the output of
the mixer must be attenuated by some factor (VRAtten). This
will prevent the filter from being overdriven and allows the
user to set the required output level.
Note: As the local oscillator input, LO has a low input
impedance (60 Ω), it will often be necessary to increase it
for driving circuitry. As the input voltage required is low
(around 5 mV pk-pk min.), a series resistor ‘RMixer’ can be
inserted. A value of 1 kΩ per 100mV (pk) oscillator signal
input will be suitable.
Example
Input frequency = 300 kHz, Local Oscillator (LO)
frequency = 250 kHz,
Output (IF) Frequency = 50 kHz.
If the bandwidth of the 50 kHz filter were 1 kHz, the filter’s Q
factor would be:
50/1 = 50.
The bandwidth of the filter is still 1 kHz when 300 kHz is
applied to the mixer’s input, but now the Q factor is:
300/1 = 300.
The mixer provides a Q factor improvement equal to the
ratio of the input frequency and the intermediate frequency.
The effective centre frequency can also be externally
controlled by changing the LO frequency. This allows
frequency tuning, trimming or sweeping while employing
fixed resistors and capacitors for the filter.
As the LO signal can be a square wave, this allows ‘fo’ to be
controlled using a microcontroller or microprocessor.
5V
1
V SS
FI1
VR Atten
C1
C
RC1
R
R2
BI
R
MXO
C
Ri
Rf
RC2
GP1
GP2
GP3
V SS
V DD
FI2
24
FO
100nF
MXI
100nF
LO
R Mixer
BI
BG
100nF
N/C
N/C
N/C
PD
V DD
5V
100nF
ISSUE 3 - JANUARY 2002
9
Output Signal
Input Signal
Oscillator Input (LO)
ZXF36L01
Application Note
An assembled evaluation PCB is available from Zetex Plc, part code: ZXF36L01-EVB. It provides a fast and easy way of
testing the filter configurations mentioned in this datasheet. This board is configured for 10kHz operation.
J1 - J5
1
C1
100n
INPUT
INPUT GND
2
ZXF36L01
3
4
5
C
R 1.5nF
10k
VR2
100k
R
C 10k
1.5nF
RI
10k
VR1
2k
RF
22k
1 VSS
V DD 24
2 FI1
FI2 23
3 C1
FO 22
4 RC1
MXI 21
5 R2
LO 20
6 BI
BI 19
7 MXO
BG 18
8 RC2
NC 17
9 GP1
NC 16
10 GP2
NC 15
C2
100n
+5V
OUTPUT
OUTPUT GND
OSC. INPUT
C5
100n
R MIX
1k
OSC. GND
C3
100n
1
11 GP3
PD 14
12 VSS
V DD 13
2 J6
C4
100n
3
POWER GND
JUMPER SETTINGS
1
2
NOTCH FILTER
INPUT IS FI2
FEEDBACK FO TO FI1
3
4
5
1
NOTCH PASS FILTER
WITH 0dB STOPBAND
2
INPUT IS FI1
FEEDBACK FI2 TO FI1
3
4
5
1
NOTCH PASS FILTER 2 2
WITH ATTENUATING 3
SKIRTS 4
INPUT IS FI1
NO EXTERNAL FEEDBACK
5
1
MIXER CONFIGURATION
WITH NOTCH
PASS FILTER 2
INPUT IS MXI
MIXED SIGNAL MXO TO FI1
NO EXTERNAL FEEDBACK
2
3
4
5
1
NORMAL OPERATION
2 J6
3
1
POWER DOWN
2 J6
3
ISSUE 3 - JANUARY 2002
10
ZXF36L01
Evaluation
An evaluation board (ZXF36L01-EVB) is available to assist with in-system
or stand-alone performance evaluation. The board can be set, by simple
jumper links, to perform any of the filter characteristic responses. The
mixer can be selected in conjunction with the notch pass filter 2 functions.
Evaluation boards can be purchased from our catalogue distributors.
Digi-Key North America (www.digikey.com)
Tel:1-800344-4539
Europe - Farnell (www.farnell.com)
Tel:44-113-263-6311
ISSUE 3 - JANUARY 2002
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ZXF36L01
PACKAGE DIMENSION
PACKAGE OUTLINE
DIM
Millimetres
Inches
Min
Max
Min
Max
A
15.20
15.40
0.598
0.606
B
1.27
–
0.05
–
C
0.66
–
0.026
–
D
0.36
0.46
0.014
0.018
E
7.40
7.60
0.291
0.299
F
2.44
2.64
0.096
0.104
G
0.10
0.30
0.004
0.012
H
0°
7°
0°
7°
I
0.23
0.28
0.009
0.011
J
10.11
10.51
0.398
0.414
K
0°
8°
0°
8°
L
0.51
1.01
0.02
0.04
R
0.63
0.89
0.025
0.035
a
7°BSC
SOIC 24 LEAD
7°BSC
© Zetex plc 2001
Zetex plc
Fields New Road
Chadderton
Oldham, OL9 8NP
United Kingdom
Telephone (44) 161 622 4422
Fax: (44) 161 622 4420
Zetex GmbH
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D-81673 München
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Hauppauge, NY11788
Germany
Telefon: (49) 89 45 49 49 0
Fax: (49) 89 45 49 49 49
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Telephone: (631) 360 2222
Fax: (631) 360 8222
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Telephone: (852) 26100 611
Fax: (852) 24250 494
These offices are supported by agents and distributors in major countries world-wide.
This publication is issued to provide outline information only which (unless agreed by the Company in writing) may not be used, applied or reproduced
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reserves the right to alter without notice the specification, design, price or conditions of supply of any product or service.
For the latest product information, log on to
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ISSUE 3 - JANUARY 2002
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