Low Noise Varactor Biasing with Switching Regulator

Application Note 85
August 2000
Low Noise Varactor Biasing with Switching Regulators
Vanquishing Villainous Vitiators Vis-à-Vis Vital Varactors
Jim Williams and David Beebe
INTRODUCTION
“hyperabrupt” devices. Response modification is possible,
with compromises in performance, particularly with regard
to linearity and sensitivity.2
Telecommunication, satellite links and set-top boxes all
require tuning a high frequency oscillator. The actual
tuning element is a varactor diode, a 2-terminal device that
changes capacitance as a function of reverse bias voltage.1 The oscillator is part of a frequency synthesizing
loop, as detailed in Figure 1. A phase locked loop (PLL)
compares a divided down representation of the oscillator
with a frequency reference. The PLL’s output is level
shifted to provide the high voltage necessary to bias the
varactor, which closes a feedback loop by voltage tuning
the oscillator. This loop forces the voltage controlled
oscillator (VCO) to operate at a frequency determined by
the frequency reference and the divider’s division ratio.
Note 1. Theoretical considerations of varactor diodes are treated in
Appendix A, “Zetex Variable Capacitance Diodes,” guest written by Neil
Chadderton of Zetex.
Note 2. The reader is again referred to Appendix A for in-depth discussion
of varactor diodes.
200
DIODE CAPACITANCE (pF)
100
Varactor Biasing Considerations
The high voltage bias is required to achieve wide-range
varactor operation. Figure 2 shows varactor capacitance
vs reverse voltage curves for a family of devices. A 10:1
capacitance shift is available, although a 0.1V to 30V swing
is required. The curves shown are characteristic of typical
ZC836
ZC835
ZC834
ZC833
ZC832
ZC831
ZC830
10
1
0.1
1
10
REVERSE VOLTAGE, VR (V)
100
AN85 A02b
Figure 2. Typical Capacitance Voltage Characteristics for the
Zetex ZC830-6 Range. 0.1V to 30V Swing Results in ≈10×
Capacitance Shift
LOOP
COMPENSATION
CAPACITOR
5V POWER
FREQUENCY
REFERENCE
32V POWERED
(TYPICAL)
PHASE
LOCKED
LOOP
OUTPUT
AMPLIFIER
LEVEL SHIFT
×10
PLL OUTPUT
0V TO 3V
(TYPICAL)
FILTER
0V TO 30V
OUTPUT
OSCILLATOR
VARACTOR
TUNING
DIODE
FREQUENCY
OUTPUT
VOLTAGE
CONTROLLED
OSCILLATOR
(VCO)
÷×
AN85 F01
Figure 1. Typical Phase Lock Loop-Based Frequency Synthesizer. Level Shift
Furnishes 0V to 30V Bias to VCO Varactor Diode, Although a 32V Supply is Required
AN85-1
Application Note 85
The bias voltage requirement has traditionally been met by
utilizing existing high voltage rails. The current trend
towards low voltage powered systems means the high
voltage bias must be locally generated. This implies some
form of voltage step-up switching regulator. This is certainly possible, but varactor noise sensitivity complicates
design. In particular, the varactor responds to any form of
amplitude variation of its bias, resulting in an undesired
capacitance shift. Such a shift causes VCO frequency
movement, resulting in spurious oscillator outputs. DC
and low frequency shifts are removed by PLL loop action,
but activity outside the loop’s passband causes undesired
outputs. Most applications require spurious oscillator
output content to be 80dB or more below the nominal
output frequency3. This implies a low noise, high voltage
supply, mandating caution in the switching regulator
design. Switching regulators are often associated with
noisy operation, making a varactor bias application seem
hazardous. Careful preparation can eliminate this concern, allowing a practical switching regulator-based approach to varactor biasing.
Low Noise Switching Regulator Design
In theory, a simple flyback regulator will work, but component choice and attention to layout are critical to
achieving low noise. Additionally, component count, size
and cost are usually considerations in varactor bias
applications. Figure 3 shows a step-up switching regulator that, properly incarnated, permits low noise varactor
biasing. The circuit is a simple boost regulator. L1, in
L1
10µH
5
1
VIN
SW
D2
R1*
12.5k
FB
GND
2
C2
4.7µF
50V
C3
0.12µF
Note 3. Spurious oscillator outputs are referred to as “spurs” in RF
parlance.
VOUT
VIN
L1
C1
D1
1
C2
D2
5
2
3
3
SHUTDOWN
4
R2*
499Ω
R2
AN85 F03
*1% METAL FILM RESISTORS
C1: TAIYO YUDEN JMK212BJ475MG
C2: MURATA GRM235Y5V475Z50
D1: 1N4148
D2: ON SEMICONDUCTOR MBR0540 OR LITE ON/DIODES INC. B0540W
L1: MURATA LQH3C100
Figure 3. LT1613-Based Boost Regulator with Appropriate
Component Selection and Layout Has Low Noise Characteristics
Needed for Varactor Biasing
AN85-2
Layout is the most crucial design aspect for obtaining low
noise. Figure 4 shows a suggested layout. Ground, VIN and
VOUT are distributed in planes, minimizing impedance. The
LT1613 GND pin (Pin 2) carries high speed, switched
current; its path to the circuit’s power exit should be direct
and highly conductive at all frequencies. R2’s return
current, to the extent possible, should not mix with Pin 2’s
large dynamic currents. C1 and C2 should be located
close to Pin 5 and D1 respectively. Their grounded ends
VOUT
32V
LT1613
SHDN
Layout Issues
D1
5V
C1
4.7µF
6.3V 4
conjunction with the SW pin’s ground-referred switching,
provides voltage step-up. D1 and C2 filter the output to
DC, D2 clips possible L1 negative excursions and the
feedback resistor ratio sets the loop servo point, and
hence, the output voltage. C3 tailors loop frequency
response, minimizing switching-frequency ripple components at the output. C1 and C2 are specified for low loss
dynamic characteristics and the LT®1613’s 1.7MHz switching frequency allows miniature, small value components.
This relatively high switching frequency also means that
ancillary “downstream” filtering is possible with similarly
miniature, small value components.
C3
R1
AN85 F04
GROUND
Figure 4. Layout Requires Attention to Component Placement
and Ground Current Flow Management. Compact Layout
Reduces Parasitic Inductance, Radiation and Crosstalk.
Grounding Scheme Minimizes Return Current Mixing
Application Note 85
should tie directly to the ground plane. L1 has a low
impedance path to VIN; its driven end returns directly to
LT1613 Pin 1. D1 and D2 should have short, low inductance runs to C2 and Pin 2, respectively; their common
connection mating tightly with Pin 1 and L1. Pin 1 has a
small area, minimizing radiation. Note that this point is
enclosed by planes operating at AC ground, forming a
shield. The feedback node (Pin 3) is further shielded from
switching radiation, preventing unwanted interaction.
Finally, L1 should be oriented so its radiation causes
minimal circuit disruption.
LT1613 regulator, an amplifier-based level shift and a GHz
range VCO. The amplifier is biased by a filtered LT1004
reference to a 12V output, simulating a typical varactor
bias point. The LT1613 configuration’s low noise output
receives additional filtering via the 100Ω-0.1µF network at
the amplifier power pin and by the amplifier’s power supply rejection ratio (PSRR). The RC combination
provides a theoretical (unloaded) break below 20kHz; the
amplifier’s PSRR benefit is derived from Figure 7. This
graph shows PSRR vs frequency for a typical amplifier.
There is a steep roll-off beyond 100Hz, although almost
20dB attenuation is available in the MHz region. This implies that the amplifier provides some beneficial filtering of
the LT1613’s residual 1.7MHz switching components.
Level Shifts
The low voltage PLL output (see Figure 1) requires an
analog level shift to bias the varactor. Figure 5 shows some
alternatives. Figure 5a is an amplifier powered from the
LT1613’s 32V output. The feedback ratio sets a gain of 10,
resulting in a 0V to 30V output for a 0V to 3V input. Figure
5b is a noninverting common base stage. Gain is less well
controlled than in Figure 5a, but overall frequency synthesizer loop action obviates this concern. Figure 5c’s common emitter circuit is similar except that it inverts.
A final RC filter section is placed directly at the VCO
varactor bias input. Ideally this filter’s break frequency is
far removed from the 1.7MHz switching rate for maximum
ripple attenuation. In practice, the filter is within the PLL
loop, placing restrictions on how much delay it can introduce. A PLL loop bandwidth of 5kHz is usually desirable,
dictating a filter point of about 50kHz to ensure closedloop stability. As such, the final RC filter (1.6k-0.002µF) is
set at this frequency. It is worth noting that the varactor’s
input resistance is quite high—essentially that of a reverse-biased diode—and no filter buffering is required to
drive it.
Test Circuit
Figure 6 combines the above considerations into a realistic test circuit. The 5V powered design is composed of the
32V
OPTIONAL
FEEDBACK
TO PLL
OUTPUT AMP
32V
0V TO 3V
FROM 5V
POWERED PLL
+
TO
VARACTOR
VIA RC FILTER
358
TYPE
–
FROM 5V
POWERED PLL
0V TO 3V
10k
2N3904
33k
10k
10k
OPTIONAL
FEEDBACK
TO PLL
OUTPUT AMP
32V
TO
VARACTOR
VIA RC FILTER
FROM 5V
POWERED PLL
0V TO 3V
TO
VARACTOR
VIA RC FILTER
33k
2N3904
33Ω
90k
5V
(5a)
(5b)
AN85 F05
(5c)
Figure 5. Level Shift Options Include Op Amp (5a), Noninverting Common Base (5b) and Inverting Common Emitter (5c).
Op Amp’s Operating Point is Inherently Stable; 5b and 5c Rely on PLL Closed-Loop Action Unless Optional Feedback is
Used
AN85-3
Application Note 85
L1
10µH
D1
32V
5V
5
1
VIN
C1
4.7µF
6.3V
D2
R1*
12.5k
LT1613
4
C2
4.7µF
50V
SW
SHDN
FB
C3
0.12µF
100Ω
3
0.1µF
R2*
499Ω
GND
2
2.7k
+V
10k
5V
LT1004
1.2V
*1% METAL FILM RESISTORS
C1: TAIYO YUDEN JMK212BJ475MG
C2: MURATA GRM235Y5V475Z50
D1: 1N4148
D2: MBR0540 OR BO540W
L1: MURATA LQH3C100
VCO: MINI-CIRCUITS POS-1400
NOTE: DO NOT USE OTHER SIDE OF 358 DUAL OP AMP.
WIRE AS GROUNDED INPUT FOLLOWER.
ALTERNATELY, LT1006 MAY BE USED
VCO
+
+
358 TYPE
(SEE NOTES)
1µF
–
VARACTOR
BIAS
INPUT
1.6k
0.002µF
VCO
OUTPUT
0.975GHz
TO 1.4GHz
0.001µF
AN85 F06
90k
10k
Figure 6. Noise Test Circuit Includes Step-Up Switching Regulator, Biased Op Amp Level Shift,
Filtering Elements and GHz Range VCO. Switching Regulator-Associated L1 is the Only Inductor Required
POWER SUPPLY REJECTION RATIO (dB)
120
TA = 25°C
100
80
60
Effects of Poor Measurement Technique
40
20
0
0.1
1
10
100 1k
10k
FREQUENCY (Hz)
100k
1M
AN85 F07
Figure 7. Typical Op Amp Power Supply Rejection Ratio
Degrades with Frequency, Although Nearly 20dB is Available
in LT1613’s MHz Switching Range
Noise Performance
Careful measurements permit verification of circuit noise
performance.4 Figure 8 shows about 2mV ripple at the
LT1613’s 32V output. Figure 9, taken at the amplifier
power pin, shows the effect of the 100Ω-0.1µF filter.
Ripple and noise are reduced to about 500µV. Figure 10,
recorded at the amplifier output, shows the influence of
amplifier PSRR. Ripple and noise are further reduced to
AN85-4
about 300µV. The actual ripple component is about 100µV.
The final RC filter, located directly at the VCO varactor
input, gives about 20dB further attenuation. Figure 11
shows ripple and noise inside 20µV with a ripple component of about 10µV.
The above results require good measurement technique.
The measurements were taken utilizing a purely coaxial
probing environment. Deviations from this regime will
produce misleading and unduly pessimistic indications.5
For example, Figure 12 shows a 50% amplitude error over
Figure 8, even though it nominally monitors the same
point. The difference is that Figure 12 utilizes a 3" probe
ground lead instead of Figure 8’s coaxial ground tip
adapter. Similarly, Figure 9’s amplifier power pin 500µV
measurement degrades to Figure 13’s indicated 2mV
representation using the 3" probe ground strap. The same
Note 4. See Appendix B, “Preamplifier and Oscilloscope Selection,” for
equipment recommendations to make the high sensitivity oscilloscope
measurements described in this section. See also Appendix C, “Probing
and Connection Techniques for Low Level, Wideband Signal Integrity.”
Note 5. Additional discourse along these lines is presented in Appendix C,
“Probing and Connection Techniques for Low Level, Wideband Signal
Integrity.” See also Reference 2-5.
Application Note 85
500µV/DIV
AC COUPLED
500µV/DIV
AC COUPLED
500ns/DIV
500ns/DIV
AN85 F08
Figure 8. LT1613-Based Output Shows 2mVP-P Ripple and Noise
AN85 F09
Figure 9. RC Filter at Amplifier’s Power Input Pin
Reduces Ripple and Noise to 500µVP-P
10µV/DIV
AC COUPLED
500µV/DIV
AC COUPLED
500ns/DIV
500ns/DIV
AN85 F10
Figure 10. Amplifier Output Shows Additional Filtering
Due to Amplifier PSRR. Aberrations Are Inside 300µV
500µV/DIV
AC COUPLED
AN85 F11
Figure 11. VCO Varactor Bias Input, After 50kHz RC Filter,
Displays Less Than 20µV Ripple and Noise. Content Coherent
with LT1613’s 1.7MHz Switching is Inside 10µV
500µV/DIV
AC COUPLED
500ns/DIV
AN85 F12
Figure 12. Improper Probing Technique. 3" Ground Lead
Causes 50% Display Error vs Figure 8’s Purely Coaxial
Measurement
500ns/DIV
AN85 F13
Figure 13. 3" Ground Lead Degrades
Figure 9’s 500µV Reading to 2mV
AN85-5
Application Note 85
ground strap causes pronounced error in Figure 14’s
apparent 2mV amplifier output vs Figure 10’s correct
300µV excursion. Figure 15 shows a 70µV indication at the
VCO varactor input using the 3" ground strap. That’s a long
way from Figure 11’s 20µV data taken with the coaxial
ground tip adapter!6
In Figure 16 the coaxial ground tip adapter is used but the
VCO varactor input shows a blizzard of noise compared to
Figure 11’s orderly trace. The reason is that a 12" voltmeter
lead was connected to the point. Pickup and stray RF act
against the node’s finite output impedance, corrupting the
measurement. Figure 17, also taken at the VCO input, is
better but still shows greater than 50% error. The culprit
Note 6. If you don’t think 70µV is a “long way” from 20µV, consider your
reaction to a 3.5× income tax reduction.
Note 7. The reader is not being requested to indulge wishful thinking.
Such a probe is more easily realized than might be supposed. See
Appendix C, “Probing and Connection Techniques for Low Level,
Wideband Signal Integrity.”
10µV/DIV
AC COUPLED
500µV/DIV
AC COUPLED
500ns/DIV
500ns/DIV
AN85 F14
Figure 14. Probe Ground Strap Causes Erroneous 2mV
Indication. Actual Value is Figure 10’s 300µV Reading
AN85 F15
Figure 15. Probe Ground Strap Causes 3.5× Readout Error vs
Figure 11’s Correctly Measured 20µV
10µV/DIV
AC COUPLED
10µV/DIV
AC COUPLED
500ns/DIV
AN85 F16
Figure 16. Effect of 12" Voltmeter Probe on VCO Varactor Input.
Coaxially Connected ‘Scope Probe is in Use. 2.5× Measurement
Error Referred to Figure 11 Results
AN85-6
here is a second probe, located at the LT1613 VSW pin,
used to trigger the oscilloscope. Even with coaxial techniques in use at both probe points, the trigger probe
dumps transient currents into the ground plane. This
introduces small common mode voltages, resulting in the
apparent noise increase. The cure is to trigger the oscilloscope with a noninvasive probe.7
500ns/DIV
AN85 F16
Figure 17. Oscilloscope Trigger Channel Probe at LT1613
SW Pin Causes 50% Measurement Error vs Figure 11
Application Note 85
Frequency-Domain Performance
Although the varactor bias noise amplitude measurements are critical, it is difficult to correlate them with
frequency-domain performance. Varactor bias noise
amplitude translates into spurious VCO outputs and that is
the measurement of ultimate concern. Although it is
possible to view the GHz range VCO on an oscilloscope
(Figure 18), this time domain measurement lacks adequate sensitivity to detect spurious activity. A spectrum
analyzer is required. Figure 19, a spectral plot of VCO
output, shows a center frequency of 1.14GHz, with no
apparent spurious activity within the ≈ 90dB measurement noise floor. A marker has been placed at 1.7MHz (3.5
divisions from center), corresponding to the LT1613’s
switching frequency. No readily distinguishable activity is
apparent at about – 90dBc. Succeeding figures “sanity
check” this performance by systematically degrading the
circuit and noting results. In Figure 20, the VCO varactor
input’s RC filter has been replaced with a direct connection. Now the 1.7MHz spurious outputs are easily seen,
about – 62dBc. In Figure 21, a 12" voltmeter lead as been
connected to the measurement point, resulting in a 4dB
AN85 F18
AN85 F19
Figure 18. GHz Range VCO Output is Viewable on Oscilloscope,
But Spurious Activity is Undetectable. Spectral Measurements
Are Required
AN85 F20
Figure 20. “Sanity Checking” Figure 19’s Results by Replacing
RC Filter at VCO Varactor Input with Direct Connection. LT1613
1.7MHz Switching Frequency Related Activity Appears at – 62dBc
Figure 19. HP-4396B Spectrum Analyzer Indicates Spurious
Outputs at Least –90dBc Referred to 1.14GHz VCO Center
Frequency
AN85 F21
Figure 21. Similar Measurement Conditions to Previous
Figure with 12" Voltmeter Probe Added. “Spurs” Increase
by 4dB to – 58dBc
AN85-7
Application Note 85
degradation, to about – 58dBc. Figure 22 shows pronounced effects due to poor LT1613 layout (power
ground pin routed circuitously, rather than directly, back
to input common) and component choice (lossy capacitor substituted for C2). Spurious activity jumps to
– 48dBc. In Figure 23 proper layout and components are
used, but the varactor bias line has been placed in close
proximity to switching inductor L1. Additionally, the bias
line and RC filter components have been distanced from
the ground plane. The resultant electromagnetic pickup
and increase in bias line effective inductance cause
1.7MHz “spurs” at – 54dBc. Additional harmonically
related activity, although less severe, is also apparent.
Figure 24 indicates favorable results when the bias line
and RC filter are restored to their proper orientation. The
plot is essentially identical to Figure 19. The lesson here
is clear. Layout and measurement practice are at least as
important as circuit design. As always, the “hidden
schematic” dominates performance.8
Note 8: Charly Gullett of Intel Corporation originated the quoted
descriptive, an author favorite.
AN85 F22
Figure 22. Deliberate Degradation of LT1613’s Grounding
Scheme and Output Capacitor Raise Spurious Outputs to – 48dBc
AN85 F22
Figure 23. Results with Varactor Bias Line Deliberately Routed
Near LT1613’s Switching Inductor, and RC Filter Components
Lifted from Ground Plane. 1.7MHz “Spurs” at –54dBc; Other
Harmonically Related Components Also Appear
AN85-8
AN85 F24
Figure 24. Varactor Bias Line and RC Filter Replaced
in Proper Orientation. Figure 19’s Silence is Restored
Application Note 85
REFERENCES
1. Chadderton, Neil, “Zetex Variable Capacitance Diodes,”
Application Note 9, Issue 2, January 1996. Zetex Applications Handbook, 1998. Zetex plc. UK.
3. Williams, Jim, “High Speed Amplifier Techniques,”
Linear Technology Corporation, Application Note 47,
August 1991.
2. Williams, Jim, “A Monolithic Switching Regulator with
100µV Output Noise,” Linear Technology Corporation,
Application Note 70, October 1997.
4. Hurlock, Les, “ABCs of Probes,” Tektronix, Inc., 1990
APPENDIX A
small change in bias voltage. This is particularly useful in
battery powered systems where the available bias voltage
is limited.
The following section, excerpted with permission from
Zetex Application Note 9 (see Reference 1), reviews theoretical considerations of varactor diodes.
ZETEX VARIABLE CAPACITANCE DIODES
5. McAbel, W. E., “Probe Measurements,” Tektronix, Inc.,
1971.
The varactor can be modelled as a variable capacitance
(Cjv), in series with a resistance (Rs). (Please refer to
Figure A1.)
Neil Chadderton, Zetex plc
Cjv
RS
Background
The varactor diode is a device that is processed so to
capitalise on the properties of the depletion layer of a P-N
diode. Under reverse bias, the carriers in each region
(holes in the P type and electrons in the N type) move away
from the junction, leaving an area that is depleted of
carriers. Thus a region that is essentially an insulator has
been created, and can be compared to the classic parallel
plate capacitor model. The effective width of this depletion
region increases with reverse bias, and so the capacitance
decreases. Thus the depletion layer effectively creates a
voltage dependent junction capacitance, that can be varied
between the forward conduction region and the reverse
breakdown voltage (typically +0.7V to –35V respectively
for the ZC830 and ZC740 series diodes).
Different junction profiles can be produced that exhibit
different Capacitance-Voltage (C-V) characteristics. The
Abrupt junction type of example, shows a small range of
capacitance due to its diffusion profile, and as a consequence of this is capable of high Q and low distortion,
while the Hyperabrupt variety allows a larger change in
capacitance for the same range of reverse bias. So called
Hyper-hyperabrupt, or octave tuning variable capacitance
diodes show a large change in capacitance for a relatively
AN85 A01
Figure A1. Common Model for the Varactor Diode
The capacitance, Cjv, is dependent upon the reverse bias
voltage, the junction area, and the doping densities of the
semiconductor material, and can be described by:
Cjv =
Cj 0
(1 + Vr/ϕ)N
where:
Cj0 = Junction capacitance at 0V
Cjv = Junction capacitance at applied bias voltage Vr
Vr = Applied bias voltage
ϕ = Contact potential
N = Power law of the junction or slope factor
The series resistance exists as a consequence of the
remaining undepleted semiconductor resistance, a contribution due to the die substrate, and a small lead and
package component, and is foremost in determining the
performance of the device under RF conditions.
AN85-9
Application Note 85
This follows, as the quality factor, Q, is given by:
1
2πfCjv RS
where:
Cjv = Junction capacitance at applied bias voltage Vr
RS = Series Resistance
f = Frequency
DIODE CAPACITANCE (pF)
Q=
300
10
0.1
1
10
REVERSE VOLTAGE, VR (V)
100
AN85 A02a
Figure A2a. Typical Capacitance-Voltage
Characteristics for the ZC740-54 Range
200
100
DIODE CAPACITANCE (pF)
Important Parameters
ZC754
ZC753
ZC752
ZC751
ZC750
ZC749
ZC748
ZC747
ZC746
ZC745
ZC744
ZC743
ZC742
ZC741
ZC740
1
So, to maximise Q, Rs must be minimised. This is achieved
by the use of an epitaxial structure so minimising the
amount of high resistivity material in series with the
junction.
Note: Zetex has produced a set of SPICE models to enable
designers to simulate their circuits in SPICE, PSPICE and
similar simulation packages. The models use a version of
the above capacitance equation and so the model parameters may also be of interest for other software packages.
Information is also provided to allow inclusion of parasitic
elements to the model. These models are available on
request, from any Zetex sales office.
100
This section reviews the important characteristics of varactor diodes with particular reference to the Zetex range of
variable capacitance diodes.
ZC836
ZC835
ZC834
ZC833
ZC832
ZC831
ZC830
10
1
0.1
1
10
REVERSE VOLTAGE, VR (V)
100
AN85 A02b
The capacitance ratio, commonly expressed as Cx/Cy
(where x and y are bias voltages), is a useful parameter
that shows how quickly the capacitance changes with
applied bias voltage. So, for an Abrupt junction device, a
AN85-10
Figure A2b. Typical Capacitance-Voltage
Characteristics for the ZC830-6 Range
200
100
DIODE CAPACITANCE (pF)
The characteristic of prime concern to the designer is the
Capacitance-Voltage relationship, illustrated by a C-V curve,
and expressed at a particular voltage by Cx, where x is the
bias voltage. The C-V curve summarises the range of
useful capacitance, and also shows the shape of the
relationship, which may be relevant when a specific
response is required. Figures A2a, A2b and A2c show
families of C-V curves for the ZC740-54 (Abrupt),
ZC830-6 (Hyperabrupt), and ZC930 (Hyper-hyperabrupt)
ranges respectively. Obviously, the choice of device type
depends upon the application, but aspects to consider
include: the range of frequencies the circuit must operate
with, and hence an appropriate capacitance range; the
available bias voltage; and the required response.
ZC934
10
ZC933
ZC932
ZC931
ZC930
1
1
10
REVERSE VOLTAGE, VR (V)
20
AN85 FA02c
Figure A2c. Typical Capacitance-Voltage
Characteristics for the ZC930-4 Range
Application Note 85
700
TJ = 0°C TO 85°C
600
500
ppm/°C
C2/C20 figure of 2.8 may be typical, whereas a C2/C20
ration of 6 may be expected for a Hyperabrupt device. This
feature of the Hyperabrupt variety can be particularly
important when assessing devices for battery-powered
applications, where the bias voltage range may be limited.
In this instance, the ZC930 series that feature a better than
2:1 tuning range for a 0 to 6V bias may be of particular
interest.
400
300
TYPICAL
200
100
The quality factor, Q, at a particular condition is a useful
parameter in assessing the performance of a device with
respect to tuned circuits, and the resulting loaded Q.
0
1
100
10
30
REVERSE VOLTAGE, VR (V)
AN85 A04a
Also of interest, with respect to stability, is the temperature coefficient of capacitance, as capacitance changes
with VR, and is shown for the three ranges in Figures A4a,
A4b and A4c respectively.
700
TEMP = 25°C
TYPICAL
600
RS (mΩ)
500
ZC830
AT 470MHz
400
300
ZC833
AT 300MHz
200
ZC836
AT 150MHz
100
0
1
10
REVERSE VOLTAGE, VR (V)
100
AN85 FA03
Figure A3. Typical RS vs VR Relationship
for ZC830 Series Diodes
700
TJ = 0°C TO 100°C
600
500
ppm/°C
The specified VR is very important in assessing this
parameter, because as well as the C-V dependence as
detailed previously, a significant part of the series resistance (RS), is due to the remaining undepleted epitaxial
layer, which is also dependant upon VR. This RS-VR
relationship is shown in Figure A3 for the ZC830, ZC833
and ZC836 Hyperabrupt devices, measured at frequencies
of 470MHz, 300MHz and 150MHz respectively, and also
serves to illustrate the excellent performance of Zetex
Variable Capacitance Diodes at VHF and UHF.
Figure A4a. Temperature Coefficient of Capacitance
vs VR for the ZC740 Series
400
300
TYPICAL
200
100
0
1
100
10
30
REVERSE VOLTAGE, VR (V)
AN85 A04a
Figure A4b. Temperature Coefficient of Capacitance
vs VR for the ZC830 Series
1400
TEMPERATURE COEFFICIENT (ppm/°C)
Zetex guarantees a minimum Q at test conditions of
50MHz, and a relatively low VR of 3 or 4V, and ranges 100
to 450 depending on device type.
TJ = 25°C TO 125°C
1200
1000
800
TYPICAL
600
400
200
0
0.1
1
10
REVERSE VOLTAGE, VR (V)
AN85 A04c
Figure A4c. Temperature Coefficient of Capacitance
vs VR for the ZC930 Series
AN85-11
Application Note 85
The reverse breakdown voltage, V(BR) also has a bearing
on device selection, as this parameter limits the maximum
VR that may be used when biasing for minimum capacitance. Zetex variable capacitance diodes typically possess
a V(BR) of 35V.
The maximum frequency of operation will depend on the
required capacitance and the series resistance (and hence
useful Q), that is possessed by a particular device type,
but also of consequence are the parasitic components
exhibited by the device package. These depend on the
size, material and construction of the package. For example, the Zetex SOT-23 package has a typical stray
capacitance of 0.08pF, and a total lead inductance of
2.8nH, while the E-line package shows less than 0.2pF
and 5nH respectively. These low values allow a wide
frequency application, for example, the ZC830 and ZC930
series, configured as series pairs are ideal for low cost
microwave designs extending to 2.5GHz and above.
APPENDIX B
PREAMPLIFIER AND OSCILLOSCOPE SELECTION
The low level measurements described require some form
of preamplification for the oscilloscope. Current generation oscilloscopes rarely have greater than 2mV/DIV sensitivity, although older instruments offer more capability.
Figure B1 lists representative preamplifiers and oscilloscope plug-ins suitable for noise measurement. These
units feature wideband, low noise performance. It is
particularly significant that many of these instruments are
no longer produced. This is in keeping with current instrumentation trends, which emphasize digital signal acquisition as opposed to analog measurement capability.
INSTRUMENT
TYPE
MANUFACTURER
Amplifier
Hewlett-Packard
The monitoring oscilloscope should have adequate bandwidth and exceptional trace clarity. In the latter regard high
quality analog oscilloscopes are unmatched. The exceptionally small spot size of these instruments is well-suited
to low level noise measurement.1 The digitizing uncertainties and raster scan limitations of DSOs impose display
resolution penalties. Many DSO displays will not even
register the small levels of switching-based noise.
Note 1: In our work we have found Tektronix types 454, 454A, 547 and
556 excellent choices. Their pristine trace presentation is ideal for
discerning small signals of interest against a noise floor limited
background.
MODEL
MAXIMUM
NUMBER BANDWIDTH SENSITIVITY/GAIN AVAILABILITY
COMMENTS
461A
150MHz
Gain = 100
Secondary Market
Differential Amplifier Preamble
1855
100MHz
Gain = 10
Current Production Stand-Alone, Settable Bandstops
Differential Amplifier Tektronix
1A7/1A7A
1MHz
10µV/DIV
Secondary Market
Requires 500 Series Mainframe,
Settable Bandstops
Differential Amplifier Tektronix
7A22
1MHz
10µV/DIV
Secondary Market
Requires 7000 Series Mainframe,
Settable Bandstops
Differential Amplifier Tektronix
5A22
1MHz
10µV/DIV
Secondary Market
Requires 5000 Series Mainframe,
Settable Bandstops
Differential Amplifier Tektronix
ADA-400A
1MHz
10µV/DIV
Current Production Stand-Alone with Optional Power
Supply, Settable Bandstops
1822
10MHz
Gain = 1000
Current Production Stand-Alone, Settable Bandstops
SR-560
1MHz
Gain = 50000
Current Production Stand-Alone, Settable Bandstops,
Battery or Line Operation
Differential Amplifier Preamble
Differential Amplifier Stanford Research
Systems
50Ω Input, Stand-Alone
Figure B1. Some Applicable High Sensitivity, Low Noise Amplifiers. Trade-Offs Include Bandwidth, Sensitivity and Availability
AN85-12
Application Note 85
APPENDIX C
PROBING AND CONNECTION TECHNIQUES FOR LOW LEVEL, WIDEBAND SIGNAL INTEGRITY1
The most carefully prepared breadboard cannot fulfill its
mission if signal connections introduce distortion. Connections to the circuit are crucial for accurate information
extraction. The low level, wideband measurements
demand care in routing signals to test instrumentation.
Pickup
Ground Loops
Poor Probing Technique
Figure C1 shows the effects of a ground loop between
pieces of line-powered test equipment. Small current flow
between test equipment’s nominally grounded chassis
creates 60Hz modulation in the measured circuit output.
This problem can be avoided by grounding all line powered test equipment at the same outlet strip or otherwise
ensuring that all chassis are at the same ground potential.
Similarly, any test arrangement that permits circuit current flow in chassis interconnects must be avoided.
Figure C3’s photograph shows a short ground strap affixed to a scope probe. The probe connects to a point
which provides a trigger signal for the oscilloscope. Circuit output noise is monitored on the oscilloscope via the
coaxial cable shown in the photo.
100µV/DIV
Figure C2 also shows 60Hz modulation of the noise
measurement. In this case, a 4-inch voltmeter probe at the
feedback input is the culprit. Minimize the number of test
connections to the circuit and keep leads short.
Note 1: Veterans of LTC Application Notes, a hardened crew, will recognize
this Appendix from AN70 (see Reference 2). Although that publication
concerned considerably more wideband noise measurement, the material
is directly applicable to this effort. As such, it is reproduced here for reader
convenience.
500µV/DIV
2ms/DIV
AN85 C01
Figure C1. Ground Loop Between Pieces of Test
Equipment Induces 60Hz Display Modulation
5ms/DIV
AN85 C02
Figure C2. 60Hz Pickup Due to Excessive
Probe Length at Feedback Node
AN85-13
Figure C3. Poor Probing Technique. Trigger Probe Ground Lead Can Cause Ground Loop-Induced Artifacts to Appear in Display
Application Note 85
AN85-14
Application Note 85
Figure C4 shows results. A ground loop on the board
between the probe ground strap and the ground referred
cable shield causes apparent excessive ripple in the display. Minimize the number of test connections to the
circuit and avoid ground loops.
Figure C10’s trace shows this to be true. The former
example’s aberrations and excessive noise have disappeared. The switching residuals are now faintly outlined in
the amplifier noise floor. Maintain coaxial connections in
the noise signal monitoring path.
Violating Coaxial Signal Transmission—Felony Case
Direct Connection Path
In Figure C5, the coaxial cable used to transmit the circuit
output noise to the amplifier-oscilloscope has been
replaced with a probe. A short ground strap is employed
as the probe’s return. The error inducing trigger channel
probe in the previous case has been eliminated; the ’scope
is triggered by a noninvasive, isolated probe.2 Figure C6
shows excessive display noise due to breakup of the
coaxial signal environment. The probe’s ground strap
violates coaxial transmission and the signal is corrupted
by RF. Maintain coaxial connections in the noise signal
monitoring path.
A good way to verify there are no cable-based errors is to
eliminate the cable. Figure C11’s approach eliminates all
cable between breadboard, amplifier and oscilloscope.
Figure C12’s presentation is indistinguishable from Figure
C10, indicating no cable-introduced infidelity. When
results seem optimal, design an experiment to test them.
When results seem poor, design an experiment to test
them. When results are as expected, design an experiment
to test them. When results are unexpected, design an
experiment to test them.
Test Lead Connections
Violating Coaxial Signal Transmission—
Misdemeanor Case
Figure C7’s probe connection also violates coaxial signal
flow, but to a less offensive extent. The probe’s ground
strap is eliminated, replaced by a tip grounding attachment. Figure C8 shows better results over the preceding
case, although signal corruption is still evident. Maintain
coaxial connections in the noise signal monitoring path.
Proper Coaxial Connection Path
In Figure C9, a coaxial cable transmits the noise signal to
the amplifier-oscilloscope combination. In theory, this
affords the highest integrity cable signal transmission.
In theory, attaching a voltmeter lead to the regulator’s
output should not introduce noise. Figure C13’s increased
noise reading contradicts the theory. The regulator’s output impedance, albeit low, is not zero, especially as
frequency scales up. The RF noise injected by the test lead
works against the finite output impedance, producing the
200µV of noise indicated in the figure. If a voltmeter lead
must be connected to the output during testing, it should
be done through a 10kΩ-10µF filter. Such a network
eliminates Figure C13’s problem while introducing minimal error in the monitoring DVM. Minimize the number of
test lead connections to the circuit while checking noise.
Prevent test leads from injecting RF into the test circuit.
Note 2: To be discussed. Read on.
100µV/DIV
5µs/DIV
AN85 C04
Figure C4. Apparent Excessive Ripple Results from Figure C3’s Probe Misuse.
Ground Loop on Board Introduces Serious Measurement Error
AN85-15
Application Note 85
Figure C5. Floating Trigger Probe Eliminates Ground Loop, But Output Probe
Ground Lead (Photo Upper Right) Violates Coaxial Signal Transmission
500µV/DIV
5µs/DIV
AN85 C06
Figure C6. Signal Corruption Due to Figure C5’s
Noncoaxial Probe Connection
AN85-16
Application Note 85
Figure C7. Probe with Tip Grounding Attachment Approximates Coaxial Connection
100µV/DIV
5µs/DIV
AN85 C08
Figure C8. Probe with Tip Grounding Attachment
Improves Results. Some Corruption is Still Evident
AN85-17
Application Note 85
Figure C9. Coaxial Connection Theoretically Affords Highest Fidelity Signal Transmission
100µV/DIV
5µs/DIV
AN85 C10
Figure C10. Life Agrees with Theory. Coaxial Signal
Transmission Maintains Signal Integrity. Switching
Residuals Are Faintly Outlined in Amplifier Noise
AN85-18
Application Note 85
Figure C11. Direct Connection to Equipment Eliminates Possible Cable-Termination
Parasitics, Providing Best Possible Signal Transmission
100µV/DIV
5µs/DIV
AN85 C12
Figure C12. Direct Connection to Equipment Provides
Identical Results to Cable-Termination Approach.
Cable and Termination Are Therefore Acceptable
AN85-19
Application Note 85
200µV/DIV
5µs/DIV
AN85 C13
Figure C13. Voltmeter Lead Attached to Regulator Output
Introduces RF Pickup, Multiplying apparent Noise Floor
Isolated Trigger Probe
The text associated with Figure C5 somewhat cryptically
alluded to an “isolated trigger probe.” Figure C14 reveals
this to be simply an RF choke terminated against ringing.
The choke picks up residual radiated field, generating an
isolated trigger signal. This arrangement furnishes a ’scope
trigger signal with essentially no measurement corruption. The probe’s physical form appears in Figure C15. For
good results, the termination should be adjusted for
minimum ringing while preserving the highest possible
amplitude output. Light compensatory damping produces
Figure C16’s output, which will cause poor ’scope triggering. Proper adjustment results in a more favorable output
(Figure C17), characterized by minimal ringing and welldefined edges.
Trigger Probe Amplifier
The field around the switching magnetics is small and may
not be adequate to reliably trigger some oscilloscopes. In
such cases, Figure C18’s trigger probe amplifier is useful.
It uses an adaptive triggering scheme to compensate for
variations in probe output amplitude. A stable 5V trigger
output is maintained over a 50:1 probe output range. A1,
operating at a gain of 100, provides wideband AC gain. The
output of this stage biases a 2-way peak detector (Q1
through Q4). The maximum peak is stored in Q2’s emitter
capacitor, while the minimum excursion is retained in Q4’s
emitter capacitor. The DC value of the midpoint of A1’s
AN85-20
output signal appears at the junction of the 500pF capacitor and the 3MΩ units. This point always sits midway
between the signal’s excursions, regardless of absolute
amplitude. This signal-adaptive voltage is buffered by A2
to set the trigger voltage at the LT1394’s positive input.
The LT1394’s negative input is biased directly from A1’s
output. The LT1394’s output, the circuit’s trigger output,
is unaffected by >50:1 signal amplitude variations. An
X100 analog output is available at A1.
Figure C19 shows the circuit’s digital output (Trace B)
responding to the amplified probe signal at A1 (Trace A).
Figure C20 is a typical noise testing setup. It includes the
breadboard, trigger probe, amplifier, oscilloscope and
coaxial components.
L1
PROBE
SHIELDED
CABLE
BNC CONNECTION
TO TERMINATION BOX
L1: J.W. MILLER #100267
TERMINATION BOX
1k DAMPING
ADJUST
4700pF
BNC
OUTPUT
AN70 FC14
Figure C14. Simple Trigger Probe Eliminates Board
Level Ground Loops. Termination Box Components
Damp L1’s Ringing Response
Figure C15. The Trigger Probe and Termination Box. Clip Lead Facilitates Mounting Probe, Is Electrically Neutral
Application Note 85
AN85-21
Application Note 85
10mV/DIV
10mV/DIV
10µs/DIV
10µs/DIV
AN85 C16
Figure C16. Misadjusted Termination Causes Inadequate
Damping. Unstable Oscilloscope Triggering May Result
AN85 C17
Figure C17. Properly Adjusted Termination
Minimizes Ringing with Small Amplitude Penalty
50Ω
ANALOG BNC OUTPUT
TO ’SCOPE TRIGGER INPUT
5V
2k
3
Q1
6
Q2
2
5V
4
+
3M
500pF
0.005µF
A1
LT1227
5V
+
0.005µF
–
2k
5
1
–
750Ω
13
1k
15
10Ω
3M
10
14
Q3
5V
12
A2
LT1006
Q4
11
470Ω
+
+
10µF
0.1µF
100µF
0.1µF
+
2k
0.1µF
470Ω
Q1, Q2, Q3, Q4 = CA3096 ARRAY: TIE SUBSTRATE (PIN 16) TO GROUND
= 1N4148
TRIGGER PROBE
AND TERMINATION BOX
(SEE FIGURE C14 FOR DETAILS)
Figure C18. Trigger Probe Amplifier Has Analog and Digital Outputs. Adaptive
Threshold Maintains Digital Output Over 50:1 Probe Signal Variations
A = 1V/DIV
AC COUPLED
B = 5V/DIV
10µs/DIV (UNCALIB)
AN85 C19
Figure C19. Trigger Probe Amplifier Analog (Trace A)
and Digital (Trace B) Outputs
AN85-22
–
LT1394
DIGITAL
TRIGGER
OUT BNC
TO ’SCOPE
AN85 C18
Figure C20. Typical Noise Test Setup Includes Trigger Probe, Amplifier, Oscilloscope and Coaxial Components
Application Note 85
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights.
AN85-23
Application Note 85
AN85-24
Linear Technology Corporation
an85f LT/TP 0800 4K • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408)432-1900 ● FAX: (408) 434-0507 ● www.linear-tech.com
 LINEAR TECHNOLOGY CORPORATION 2000