FEBRUARY 1997 VOLUME VII NUMBER 1
, LTC and LT are registered trademarks of Linear Technology Corporation. Adaptive Power, Burst Mode, C-Load,
LinearView, Micropower SwitcherCAD, PowerPath, SwitcherCAD and UltraFast are trademarks of Linear Technology
Corporation. Other product names may be trademarks of the companies that manufacture the products.
The New LT1425
Isolated Flyback Controller
by Kurk Matthews
Introduction
Low voltage circuitry, such as local
area networks (LAN), isolation ampli-
fiers and telephone interfaces,
frequently requires isolated power
supplies. The flyback converter is of-
ten the choice for these low power
supplies because of its simplicity, size
and low parts count. Unfortunately,
designers are forced to add opto-
couplers and references in order to
achieve the desired output regulation
and transient response.
The new LT1425 provides a one-
chip solution for these and other
applications. The LT1425 is a 275kHz
current mode controller with an inte-
gral 1.25A switch designed primarily
to provide well regulated, isolated
voltages from 3V–20V sources. The
LT1425 is available in a 16-pin SO.
Features include a new error amplifier
and load compensation circuitry that
eliminate the need for optocouplers
while maintaining output regulation
typically within a few percent.
Figure 1 shows a typical flyback
LAN supply using the LT1425. Figure
1 also includes details on an alter-
nate transformer for a complete
PCMCIA type II height solution. The
output voltage is within 1% of –9V for
load currents of 0mA–250mA. Input
current is limited to 0.35 amps in the
event the output is short circuited.
The output voltage droops only 300mV
during a 50mA to 250mA load tran-
sient (see Figure 2). The off-the-shelf
transformers provide 500V
AC
of isola-
tion. The high switching frequency
allows the use of small case size, low
cost, high value ceramic capacitors
on the input and output of the supply.
Isolated Feedback
The heart of the LT1425 is shown in
Figure 3. During S1’s off-time, the
voltage on the V
SW
pin increases to V
IN
+ (V
OUT
+ V
D
)/n, where n is the trans-
former turns ratio and V
D
is the output
diode voltage. Q1’s collector current
becomes I
CQ1
= (V
OUT
+ V
D
)/(n × R1).
R2 converts I
CQ1
into the input volt-
age for the transconductance feedback
amplifier. C1 on the V
C
pin then inte-
grates the feedback amplifier’s output
current. The voltage on the V
C
pin
sets the current mode trip point.
Although we now have a means for
generating a feedback voltage, a few
problems remain. The feedback volt-
age is not present during S1’s on-time
or when the secondary current de-
cays to zero, which is often the case
with a discontinuous flyback. To make
matters worse, T1’s leakage induc-
tance can cause large voltage spikes
at turn-off.
These issues are taken care of by
the error amplifier enable block, which
incorporates enable-delay, collapse-
detect and minimum-enable-time
circuitry. Enable delay waits approxi-
mately 200ns after the switch turns
off before enabling the feedback
amplifier, thus avoiding the leakage-
inductance spike. The collapse detect
continued on page 3
IN THIS ISSUE . . .
COVER ARTICLE
The New LT®1425
Isolated Flyback Controller ........ 1
Kurk Matthews
Issue Highlights ........................2
LTC in the News .........................2
DESIGN FEATURES
The LT1328: a Low Cost IrDA®
Receiver Solution for Data Rates
up to 4Mbps ...............................6
Alexander Strong
The LTC®1473 Dual PowerPath™
Switch Driver Simplifies Portable
Power Management Design ........8
Jaime Tseng
The LTC1560-1: a 1MHz/500kHz
Continuous-Time, Low Noise,
Elliptic Lowpass Filter ............ 11
Nello Sevastopoulos
The LTC1594 and LTC1598:
Micropower 4- and 8-Channel
12-Bit ADCs ............................. 14
Kevin R. Hoskins and Marco Pan
LTC1474 and LTC1475 High
Efficiency Switching Regulators
Draw Only 10µA Supply Current
................................................17
Greg Dittmer
DESIGN IDEAS .................. 21–32
(Complete list on page 21)
DESIGN INFORMATION
Introducing the LT2078/LT2079
and LT2178/LT2179 Single
Supply, Micropower, Precision
Amplifiers in Surface Mount
Packages
................................................33
Raj Ramchandani
LTC1387 Single 5V
RS232/RS485 Multiprotocol
Transceiver .............................34
Y.K. Sim
New Device Cameos.................. 37
Design Tools ............................39
Sales Offices ............................40
LINEAR TECHNOLOGY
LINEAR TECHNOLOGY
LINEAR TECHNOLOGY
Linear Technology Magazine • February 1997
2
EDITOR’S PAGE
Issue Highlights
To mark the new year, we have a
collection of exciting new parts from
the design gurus at LTC. This issue’s
lead article features the new LT1425
isolated flyback converter, which pro-
vides a one-chip solution for low
voltage circuitry, such as local area
networks, isolation amplifiers and
telephone interfaces. The LT1425 is a
275kHz current mode controller with
an integral 1.25A switch, designed to
provide well regulated, isolated volt-
ages from 3V–20V sources.
Other power products featured in
this issue include the LTC1474 and
LTC1475 ultralow quiescent current,
high efficiency step-down switching
regulators. These regulators draw only
10µA at no load and require only four
external components to make a com-
plete, high efficiency (up to 92%)
step-down regulator. Low component
count and the parts’ tiny MSOP pack-
ages provide a minimum-area solution
to meet the limited space require-
ments of portable applications.
Another boon to the designers of
portable, battery-powered equipment
is the LTC1473 dual PowerPath switch
driver, which simplifies the design of
circuitry for switching between two
batteries or a battery and an AC
adapter. Presently, switching between
power sources is implemented with
discrete components—regulators,
comparators, references, glue logic,
MOSFET switches and drivers. These
solutions are expensive and occupy a
lot of printed circuit board space. The
LTC1473 drives low loss N-channel
MOSFET switches that direct power
in the main power path of a single or
dual rechargeable battery system, the
type found in most notebook comput-
ers and other portable equipment.
In the filter department, this issue
introduces the LTC1560-1, a high
frequency, continuous-time, low noise
filter. This device is a single-ended
input and output, 5th order elliptic
lowpass filter with a pin-selectable
cutoff frequency of 1MHz or 500kHz.
It requires no external components or
clocks and provides better than 60dB
LTC in the News…
Results of LTC’s second fiscal quarter
underscore the company’s standing as
an industry leader. Net sales for the
second fiscal quarter of 1997, ended
December 29, 1996, were $90,080,000.
Although this was a decrease of 6% over
net sales of $96,017,000 for the second
quarter of the previous year, this actu-
ally represented phenomenally good
performance, as we will see in just a
moment.
LTC reported net income for the quar-
ter of $31,631,000 or $0.40 per share,
a decrease of 8% from the second quar-
ter of the previous year. Sequentially,
the results for the second quarter were
essentially flat as compared to net sales
and income for the quarter ended Sep-
tember 29, 1996 of $90,063,000 and
$31,358,000 or $0.40 per share, re-
spectively. A cash dividend of $0.05 will
be paid on February 12, 1997 to share-
holders of record on January 24, 1997.
According to Robert H. Swanson,
president and CEO, “Although we en-
tered the quarter with reduced backlog,
we were able to achieve flat sequential
sales and profits with our return on
sales continuing to lead the industry. In
addition, cash and short-term invest-
ments grew by approximately $20 mil-
lion in the quarter. Customers’ demand
picked up moderately throughout the
quarter and our shorter lead times en-
abled us to ship some of their demand
within the quarter. We believe our mar-
ket is improving and we are optimistic
about the future.”
It’s becoming known around the
nation’s regional stock exchanges that
LTC is a leading pace setter and vital
indicator of the economic condition of
the electronics industry. For many
months, the Bloomberg Silicon Valley
Index and the Dean Witter Silicon Val-
ley Stock Index have included LTC’s
business performance in their assess-
ment of the industry.
Now, the New York-based Reuters
America News Service reports that the
Philadelphia Stock Exchange has added
two chip companies—one of which is
LTC—and an equipment maker to its
Semiconductor Index to replace three
stocks the exchange has removed. Late
last month, the exchange added Linear
Technology Corp. (LLTC), Xilinx Inc.
(XLNX.O) and Lam Research Corp.
(LRCX.O). To us at LTC, this move is
further proof that even in the realm of
high finance, “it’s a linear world.”
of stopband attenuation and 75dB
SNR, with only 0.3dB passband ripple.
In the data conversion area, we
debut the LTC1594 and LTC1598,
micropower 12-bit ADCs, which fea-
ture a 4- or 8-channel multiplexer,
respectively. These devices include
an auto shutdown feature that re-
duces power dissipation when the
converter is inactive. Nominal power
dissipation with the converter clocked
at 320kHz is typically 1.6mW. Each
ADC includes a simple, efficient serial
interface that reduces interconnects
and, thereby, possible noise sources.
Reduced interconnections also reduce
board size and allow the use of pro-
cessors having fewer I/O pins, both of
which help reduce system costs.
For data communications, this is-
sue introduces the low cost LT1328
IrDA data receiver. This device con-
tains all the necessary circuitry to
convert current pulses from an exter-
nal photodiode to a digital TTL output
while rejecting unwanted lower fre-
quency interference. The LT1328 plus
six external components are all that
is required to make an IrDA-compat-
ible receiver. Power requirements for
the LT1328 are minimal: a single 5V
supply and 2mA of quiescent current.
This issue includes a varied selec-
tion of Design Ideas, including three
power supplies, a battery charger that
doubles as the main step-down con-
verter, a voltage controlled limiter for
video, a detector circuit for 470MHz
signals, and an evaluation of battery
life under a variety of load conditions.
Penultimately, we present Design
Information on the LT2078/LT2079
and LT2178/LT2179, improved
single-supply, precision surface
mount op amps, and the LT1387
single 5V multiprotocol transceiver.
We conclude with a selection of New
Device Cameos.
Linear Technology Magazine • February 1997
3
DESIGN FEATURES
–
+
–
+
1425_03.eps
V
IN
Q1 Q2 2.6V
R
FB
R1
V
SW
V
OUT
C1
R3
V
C
R
OCMP
R
CMPC
50k
2 A/V
S1
T1
1:N
COMP LOGIC/
DRIVER
R
REF
1.224V ERROR
AMP
ENABLE
R2
disables the feedback amplifier when
the R
REF
voltage falls below 80% of the
1.224V reference. This natural col-
lapse of the feedback voltage occurs
sometime during the off-time in the
discontinuous flyback mode (see Fig-
ure 4, Trace C) or when the switch
turns on in the continuous mode (see
Trace A). Finally, a 200ns minimum
enable time, which follows the enable
delay time, ensures that the error
amplifier can pump up the V
C
node
during start up and other conditions
when V
OUT
is low.
This unique feedback system pro-
duces controlled output voltages while
maintaining fast dynamic response
not found in similar isolated flyback
schemes. 200ns of leading edge, cur-
rent sense blanking is also included
to reject turn-on spikes.
Load Compensation
If the world were a perfect place, with
ideal transformers, diodes and ca-
pacitors, no additional compensation
would be required to maintain perfect
regulation. Unfortunately, as the load
current increases, the additional volt-
age drop due to secondary winding
resistance, the output diode and ca-
pacitor ESR results in decreased
output voltage. To compensate for
this change in output voltage, a cur-
rent is generated in Q2 (see Figure 3),
which is proportional to the average
primary current. Since primary cur-
rent changes with output load, the
effects of nonideal components are
minimized and regulation is possible
over a wide load range. R3 determines
the amount of load compensation.
Connecting R
CMPC
to ground defeats
the load compensation.
Figure 3. LT1425 isolated feedback block diagram
LT1425, continued from page 1
1425_01.eps
1
2
3
4
5
6
7
8
16
15
14
13
12
11
10
9
GND
N/C
R
FB
V
C
R
REF
SYNC
SGND
GND
3.01k
1%
R3
R1 R2
2
4
1
3
7
MBRS130LT3
T1
6
22.1k
1%
0.1µF
LT1425
47pF
C5
C6
C3
10µF
25V
C4
10µF
25V
1.8k
OUT
COM
–9V
1000pF
C1
10µF
25V
5V
INPUT
COM
C2
10µF
25V
0.1µF
100k
GND
SD
R
OCMP
R
CMPC
V
IN
V
SW
PGND
GND
C1, C2, C3, C4 = MARCON THCS50E1E106Z CERAMIC
CAPACITOR, SIZE 1812. (847) 696-2000
D1
D2
1TREMROFSNART
L
IRP
SNRUT OITARNOITALOSI EZIS
L(×W×)HI
T
U
O
YCNEICIFFE1D2D2R,1R6C,5C3R
ELAD
703A-1484-EPL63µH1:1:1CAV0057.01×5.11×mm3.6Am052%67DESUTONDESUTON74ΩFp033k3.31
SCINORTLIOC
38431-20XTC72µH1:1CAV00541×41×mm2.2Am002%078425N11LT0450RBM57ΩFp022k9.5
Figure 1. 5V to –9V/250mA isolated LAN supply
Figure 2. Transient response of LT1425 5V to
–9V converter
200mV/DIV
100mA/DIV
5ms/DIV
Linear Technology Magazine • February 1997
4
DESIGN FEATURES
of 10V–15V). The isolation voltage is
ultimately limited only by bobbin se-
lection and transformer construction.
The schematic shows details on build-
ing the transformer.
Figure 7 implements a 12V to
5V/1A step-down regulator with off-
the-shelf magnetics. The circuit uses
an external, cascoded 100V MOSFET
to extend the LT1425’s 35V maxi-
mum switch voltage limit. D1 and Q1
ensure the LT1425 does not start
until almost 9V, guaranteeing ad-
equate gate voltage for the MOSFET.
The MUR120 prevents the source from
rising above the gate at turn-off.
The circuit in Figure 8 achieves
even higher input voltages, this time
in the form of a –48V to 5V/2A iso-
lated telecom supply. The input
voltage is too high to directly run Q1
or the LT1425, so a bootstrap wind-
ing is used to provide feedback and
power for the IC after start-up. The
voltage to the V
IN
pin is controlled by
D1, D2, Q2, Q3 and associated com-
ponents, which form the necessary
start-up circuitry with hysteresis.
Nothing happens until C1 charges
through R1 to 15V. At that point, Q2
turns on Q3, pulling the shutdown
pin high. Q3, in turn, latches Q2 on,
setting the turn-off voltage to ap-
proximately 11V. Switching begins
1
2
3
4
8
7
6
5
TOP VIEW
LT1424
SD
V
C
SYNC
SGND
R
CMPC
V
IN
V
SW
PGND
1425_05.eps
+
+
+
1425_06.eps
GND
N/C
LT1425
MBRS1100T3
MBRS1100T3
45
6
7
T1*
3
2
18
R
FB
V
C
R
REF
SYNC
SGND
GND
GND
SD
R
OCMP
R
CMPC
PIN 3 TO 4, 7 TURNS BIFILAR 34AWG
*PHILIPS EFD-15-3F3 CORE
GAP FOR PRIMARY
L = 40µH
0.12 INCH MARGIN TAPE
PIN 7 TO 8, 28 TURNS 40AWG
PIN 5 TO 6, 28 TURNS 40AWG
PIN 1 TO 2, 7 TURNS BIFILAR 34AWG
3 LAYERS 2 MIL
POLYESTER FILM
V
IN
V
SW
PGND
GND
1
2
3
4
5
6
7
8
16
15
14
13
12
11
10
3.01k
1%
1N759
18.4k
0.1%
3k
+15V
–15V
OUT
COM
7.32k
1%
75
5V TO
15V
INPUT
COM
0.1µF
220pF
1µF
22µF
35V
15µF
35V
3k
15µF
35V
1000pF
0.1µF
130 330pF
9
MBR0540LT1
Figure 5. LT1424 pinout
Figure 6. Fully isolated ±15V, ±60mA supply
D: ISW = 0.2A/DIV
C: VSW = 20V/DIV
B: ISW = 1A/DIV
A: VSW = 20V/DIV
1µs/DIV
Figure 4. Switch voltage and current for
Figure 1’s circuit with outputs of –9V/250mA
and –9V/30mA
The LT1424
The LT1424, devoted to fixed output
voltage applications, is available in
an 8-pin SO package. The LT1424
retains the features of the LT1425
and incorporates the feedback, refer-
ence and load compensation resistors.
Figure 5 shows the LT1424 pinout.
Both the LT1424 and LT1425 include
shutdown and synchronization func-
tions. Consult the factory for further
information on the LT1424.
Typical Applications
Figure 6 shows a ±15V supply with
1.5kV of isolation. Output regulation
remains within ±3% over the entire
5V to 15V input voltage and ±60mA
output current range, even with one
output fully loaded and the other
unloaded (±1.5% with input voltages
and, before C1 has a chance to dis-
charge to 11V, the bootstrap winding
begins to supply power. If the output
is shorted, R2 prevents C1 from being
charged by the transformer’s leakage
energy, causing the supply to con-
tinually attempt to restart. This limits
input and output current during a
short circuit. Feedback voltage is fed
directly through a resistor divider to
the R
REF
pin. The sampling error am-
plifier still works, but the load
compensation circuitry is bypassed.
This results in a ±5% load regulation
over line and load. A dedicated feed-
back winding referencing the feedback
voltage to the V
IN
pin could be used to
include the load compensation func-
tion and improve regulation.
Conclusion
The LT1425 offers high performance
and accuracy without the additional
circuitry traditionally associated with
isolated DC to DC converters.
Linear Technology Magazine • February 1997
5
DESIGN FEATURES
++
+
220µF
10V
1425_07.eps
GND
N/C
LT1425
MBRS340T3
2
5
1
4
6
3
10
7
11
8
12
9
R
FB
V
C
R
REF
SYNC
SGND
GND
GND
SD
R
OCMP
R
CMPC
V
IN
V
SW
PGND
GND
1
2
3
4
5
6
7
8
16
15
14
13
12
11
10
3.01k
1%
25.5k
1%
9.3k
1%
MMFT1N10E
2.4k
12V
INPUT
COM
0.1µF
22µF
35V 220µF
10V 200Ω
5V
OUT
COM
COILTRONIX
VP1-0190
TURNS RATIO 1 : 1 : 1 : 1 : 1 : 1
12µH PER WINDING
407-241-7876
1000pF
1000pF
MUR120
Q1
2N3906
0.1µF
100Ω
10
1.8k
330pF
9
D1
1N755
7.5V
+
++
1425_08.eps
GND
N/C
BAV21
BAV21
MUR120
LT1425
5k
18
MBR745
10
47
8
T1*
3
2
1
R
FB
V
C
R
REF
SYNC
SGND
GND
GND
SD
R
OCMP
R
CMPC
PIN 3 TO 4, 15 TURNS BIFILAR 31AWG
*PHILIPS EFD-15-3F3 CORE
GAP FOR PRIMARY
L = 100µH
PIN 7 TO 8, 6 TURNS QUADFILAR 29AWG
PIN 5 TO 6, 15 TURNS BIFILAR 33AWG
PIN 1 TO 2, 15 TURNS BIFILAR 31AWG
1 LAYER 2 MIL
POLYESTER FILM
2 LAYERS 2 MIL
POLYESTER FILM
V
IN
V
SW
PGND
GND
1
2
3
4
5
6
7
8
16
T1
6
5
15
14
13
12
11
10
3.16k
1%
Q2
2N3906 Q3
2N3904
Q1
IRF610
D1
7.5V
1N755
D2
7.5V
1N755
30.1k
1%
R2
18
R1
24k 50Ω
1W
510
10k
2.4k
100k
INPUT
COM
–36V TO
–72V
3.3µF
150pF
0.1µF
0.1µFC1
27µF
35V
150µF
6.3V
150µF
6.3V
5V
OUT
COM
1000pF
470pF
9
Figure 7. 5V/1A step-down, isolated supply
Figure 8. 5V/2A telecommunications supply
Linear Technology Magazine • February 1997
6
DESIGN FEATURES
V
CC
(5V)
1328_01.eps
C4
0.1µFC5
10µF
HIGH – SIR
LOW – FIR AND 4PPM
IN
FILT
FILT LO
GND
LT1328
MODE
C3
1000pF
V
CC
DATA
V
BIAS
8
7
6
TTL DATA OUT
C1
330pF
LIGHT IN
D1
BPU22NF
TEMIC
C2
10nF
1328_02.eps
R
D3
10k
R
D1
100Ω
DRIVER
Q3
2N7002
TRANSMIT
INPUT
R
D2
6.8Ω
1/2W
Q4
2N7002
D2
HSDL-4220
V
CC
The LT1328: a Low Cost IrDA Receiver
Solution for Data Rates up to 4Mbps
by Alexander Strong
Introduction
The need for ever increasing data
rates required by a vast array of de-
vices, such as notebook computers,
printers, mobile phones, pagers, elec-
tronic cameras and modems, has been
satisfied by the technology of infrared
data transmission. The Infrared Data
Association (IrDA
®
) standard, which
covers data rates from 2400bps to
4Mbps, is the overwhelming choice
for infrared data transmission. The
LT1328 is a photodiode receiver that
supports IrDA data rates up to 4Mbs,
as well as other modulation methods,
such as Sharp ASK and TV remote
control.
The LT1328, in the MSOP package,
contains all the necessary circuitry to
convert current pulses from an exter-
nal photodiode to a digital TTL output
while rejecting unwanted lower fre-
quency interference. The LT1328 plus
six external components is all that is
required to make the IrDA-compat-
ible receiver shown in Figure 1. An
IrDA- compatible transmitter can also
be implemented with only six compo-
nents, as shown in Figure 2. Power
requirements for the LT1328 are mini-
mal: a single 5V supply and 2mA of
quiescent current.
LT1328
Functional Description
Figure 3 is a block diagram of the
LT1328. Photodiode current from D1
is transformed into a voltage by feed-
back resistor R
FB
. The DC level of the
preamp is held at V
BIAS
by the servo
action of the transconductance
amplifier’s g
m
. The servo action only
suppresses frequencies below the
R
g
m
/C
FILT
pole. This highpass filter-
ing attenuates interfering signals,
such as sunlight or incandescent or
fluorescent lamps, and is selectable
at pin 7 for low or high data rates. For
high data rates, pin 7 should be held
low. The highpass filter breakpoint is
set by the capacitor C1 at f = 25/(2
× R
g
m
× C), where R
g
m
= 60k. The
330pF capacitor (C1) sets a 200kHz
corner frequency and is used for data
rates above 115kbps. For low data
rates (115kbps and below), the ca-
pacitance at pin 2 is increased by
taking pin 7 to a TTL high. This
switches C2 in parallel with C1,
lowering the highpass filter break-
point. A 10nF cap (C2) produces a
6.6kHz corner. Signals processed by
the preamp/g
m
amplifier combina-
tion cause the comparator output to
swing low.
IrDA SIR
The LT1328 circuit in Figure 1 oper-
ates over the full 1cm to 1 meter range
of the IrDA standard at the stipulated
light levels. For IrDA data rates of
115kbs and below, a 1.6µs pulse width
is used for a zero and no pulse for a
one. Light levels are 40mW/sr (Watts
per steradian) to 500mW/sr. Figure 4
shows a scope photo for a transmitter
input (top trace) and the LT1328 out-
put (bottom trace). Note that the input
to the transmitter is inverted; that is,
transmitted light produces a high at
the input, which results in a zero at
the output of the transmitter. The
Mode pin (pin 7) should be high for
these data rates.
IrDA FIR
The second fastest tier of the IrDA
standard addresses 576kbps and
1.152Mbs data rates, with pulse
widths of 1/4 of the bit interval for
zero and no pulse for one. The
1.152Mbs rate, for example, uses a
pulse width of 217ns; the total bit
time is 870ns. Light levels are
100mW/sr to 500mW/sr over the 1cm
to 1 meter range. A photo of a trans-
mitted input and LT1328 output is
Figure 1. LT1328 IrDA receiver—typical application Figure 2. IrDA transmitter
Linear Technology Magazine • February 1997
7
DESIGN FEATURES
+
–
–
+
1
1328_03.eps
COMPARATOR
g
m
CELL
BIAS
V
BIAS
FILTER
PHOTODIODE
IN
FILTER LO
DATA OUT
V
CC
MODE
GND
R
GM
R
FB
R
IN
PREAMP
2
3
4
C1
330pF C2
10nF
8
C3
7
6
5
D1
shown in Figure 5. The LT1328 output
pulse width will be less than 800ns
wide over all of the above conditions
at 1.152Mbps. Pin 7 should be held
low for these data rates and above.
4ppm
The last IrDA encoding method is for
4Mbs and uses pulse position modu-
lation, thus its name: 4ppm. Two bits
are encoded by the location of a 125ns
wide pulse at one of the four positions
within a 500ns interval (2 bits ×
1/500ns = 4Mbps). Range and input
levels are the same as for 1.152Mbs.
Figure 6 shows the LT1328 reproduc-
tion of this modulation.
Conclusion
In summary, the LT1328 can be used
to build a low cost receiver compat-
ible with IrDA standards. Its ease of
use and flexibility also allow it to
provide solutions to numerous other
photodiode receiver applications. The
tiny MSOP package saves on PC board
area.
Figure 3. LT1328 block diagram IrDA is a registered trademark of the Infrared Data
Association
Authors can be contacted
at (408) 432-1900
Figure 4. IrDA 115kbs modulation Figure 5. IrDA 1.152Mbs modulation Figure 6. IrDA 4ppm modulation
TRANSMITTER
INPUT
LT1328 OUTPUT
2ns/DIV
TRANSMITTER
INPUT
LT1328 OUTPUT
200ns/DIV
TRANSMITTER
INPUT
LT1328 OUTPUT
200ns/DIV
Linear Technology Magazine • February 1997
8
DESIGN FEATURES
The LTC1473 Dual PowerPath Switch
Driver Simplifies Portable Power
Management Design by Jaime Tseng
Introduction
The LTC1473 is the latest addition to
Linear Technology’s new family of
power management controllers, which
simplify the design of circuitry for
switching between two batteries or a
battery and an AC adapter. Presently,
switching between power sources is
implemented with discrete compo-
nents—a mixture of regulators,
comparators, references, glue logic,
MOSFET switches and drivers. In-
variably, these solutions are expensive
and occupy a considerable amount of
printed circuit board space. Although
these circuits are frequently designed
in a hurry, the problems associated
with power path switching are often
subtle and daunting. For example,
switching from one battery to another
can produce huge inrush currents
between the batteries when their volt-
ages differ. In extreme cases, system
bypass capacitors can be destroyed if
tantalums are used. Slowing the
switch turn-on rate helps reduce the
inrush current, but may cause a pre-
cipitous drop in the system supply
voltage.
Solutions to these “real world” prob-
lems have been designed into our new
power path
switch driver. The
LTC1473 dual PowerPath™ switch
driver drives low loss N-channel MOS-
FET switches that direct power in the
main power path of a single or dual
rechargeable battery system, the type
found in most notebook computers
and other portable equipment.
Overview
The power management system in
Figure 1 shows the LTC1473 driving
two sets of back-to-back N-channel
MOSFET switches connecting the two
batteries to the system DC/DC regu-
lator. Each of the switches is controlled
by a TTL/CMOS compatible input
that interfaces directly with a power
management system microprocessor.
An internal boost regulator provides
the voltage to fully enhance the logic-
level N-channel MOSFET switches.
The LTC1473 uses a current sense
loop to limit current rushing in and
out of the batteries and the system
supply capacitor during switch-over
transitions or during a fault condi-
tion. A user programmable timer
monitors the time during which the
MOSFET switches are in current limit
and latches them off if the pro-
grammed time is exceeded. A unique
“2-diode logic mode” ensures system
start-up, regardless of which input
receives power first.
BAT1
BAT2
SWA1
SWA2
+
HIGH
EFFICIENCY
DC/DC
SWITCHING
REGULATOR
5V
3.3V
12V
C
IN
DCIN
LTC1473
POWER
MANAGEMENT
µP
SWB2
SWB1 R
SENSE
STEP-UP
SWITCHING
REGULATOR
1µF
50V
C1
GATE
DRIVER
GATE
DRIVER
1µF
50V
C2
V
GG
V
+
INRUSH
CURRENT
SENSING
AND LIMITING
C1
4700pF
C
TIMER
TIMER
1473_01.eps
IN1
IN2
DIODE
SW
L1
1mH
+
+
Si9926
Si9926
MB914LT1
MBRD340
Figure 1. Dual-battery PowerPath switch driver: V
GG
regulator, inrush limiting and switch-gate drivers
Linear Technology Magazine • February 1997
9
DESIGN FEATURES
BAT1
BAT2
SWA1
SWA2
+
HIGH
EFFICIENCY
DC/DC
SWITCHING
REGULATOR
5V
3.3V
1473_02.eps
12V
C
IN
DCIN
LTC1473
POWER
MANAGEMENT
µP
SWB2
SWB1
ON OFF
ON OFF
R
SENSE
MBRD340
Si9926
Si9926
Back-to-Back Switches
The back-to-back topology eliminates
the problems associated with the in-
herent body diodes in power MOSFET
switches and allows each switch pair
to block current flow in either direc-
tion when the two switches are turned
off. The low loss, N-channel switch
pairs are housed in 8-pin SO and
SSOP packaging and are available
from a number of manufacturers. The
Si9926DY, for example, houses two
20V MOSFETs rated at 0.03 with
V
GS
= 4.5V.
Inrush Current Limiting
The back-to-back topology also al-
lows for independent control of each
half of the switch pair, facilitating
bidirectional inrush current limiting.
The voltage across a single low value
resistor, R
SENSE
, is measured to de-
termine the instantaneous current
flowing through the two main switch
pairs, SWA1/B1 and SWA2/B2. The
inrush current is then controlled by
the gate drivers until the transition
from one power source to the other
has been completed. The current flow-
ing in and out of the two main power
sources and the DC/DC converter
input capacitor is dramatically
reduced.
Tantalum Capacitors
Tantalum capacitors, with their high
volumetric efficiency and low ESR,
are the dielectric of choice for low
impedance applications, such as fil-
tering the input of a switching
regulator. However, because these ca-
pacitors are exposed to uncontrolled
energy supplies, they are subject to
failures caused by high inrush cur-
rents unless current surges are
restricted. The inrush-current limit-
ing feature of the LTC1473 makes it
feasible to use low profile tantalum
surface mount capacitors in place of
bulkier electrolytic capacitors.
Built-In Step-Up Regulator
The gate drive for the two low loss N-
channel switches is supplied by a
micropower step-up regulator that
continuously generates 8.5V above
V+, up to 37V maximum. The V
GG
supply provides sufficient headroom
to ensure that the logic-level MOS-
FET switches are fully enhanced by
the gate drivers which, supply a regu-
lated 5.7V gate-to-source voltage, V
GS
,
when turned on.
The power for the micropower boost
regulator is taken from external di-
odes connected to each power source.
The highest voltage potential is di-
rected to V
+
, where L1, an inexpensive
1mH surface mount inductor, is con-
nected. An internal diode directs the
current from L1 to the V
GG
output
capacitor, C2.
Programmable Fault Timer
A fault-timer capacitor, C
TIMER
, is used
to program the time during which the
MOSFET switches are allowed to be
in current limit continuously. In the
event of a fault condition, the MOS-
FET current is limited by the inrush
current-limit loop. A MOSFET switch
operating in current limit is in a high
dissipation mode and can fail cata-
strophically if this condition is not
promptly terminated.
The fault-time delay is programmed
with an external capacitor connected
between the TIMER pin and ground.
At the instant the MOSFET switch
enters current limit, a 5µA current
source starts charging C
TIMER
through
the TIMER pin. When the voltage
across C
TIMER
reaches 1.2V, an inter-
nal latch is set and the MOSFET
switch is turned off. To reset the
latch, the gate-drive input of the
MOSFET switch is deselected.
The “2-Diode Mode”
Under normal operating conditions,
both halves of each switch pair are
turned on and off simultaneously.
For example, when the input power
source is switched from BAT1 to BAT2,
both gates of switch pair SWA1/B1
are turned off and both gates of switch
pair SWA2/B2 are turned on. The
back-to-back body diodes in switch
pair SWA1/B1 block current flow into
or out of the BAT1 input connector.
In the “2-diode mode,” only the
first half of each power path switch
pair, for example, SWA1 and SWA2, is
turned on, and the second half, that
is, SWB1 and SWB2, is turned off.
These two switch pairs now simply
act as two diodes connected to the
two main input power sources, as
illustrated in Figure 2. The power
path diode with the highest input
voltage passes current to the input of
the DC/DC converter to ensure that
the power management microproces-
sor is powered, even under start-up
Figure 2. LTC1473 dual PowerPath switch driver in “2-diode mode”
Linear Technology Magazine • February 1997
10
DESIGN FEATURES
or abnormal operating conditions.
After “good” power is reconnected to
one of the main inputs, the LTC1473
can be instructed to drive the appro-
priate switch pair on fully as the other
switch is turned off, restoring normal
operation.
Typical Application
A typical dual-battery system is shown
in Figure 3. The LTC1473 accepts
commands from a power manage-
ment microprocessor to select the
SAB1
GB1
SENSE+
SENSE-
GA2
SAB2
GB2
IN1
IN2
DIODE
TIMER
V
+
V
GG
SW
GND
LTC1473GA1
R
SENSE
0.04Ω
+
POWER
MANAGEMENT
µP
SUPPLY
MONITOR
BAT1
DCIN
BAT2
C
OUT
INPUT OF SYSTEM
HIGH EFFICIENCY DC/DC
SWITCHING REGULATOR
(LTC1435,ETC)
C
TIMER
4700PF 1µF
1µF
1mH
Si9926
Si9926
1473_03.eps
MBRD340
MMBD2823LT1
MMBD2823LT1
MMBD914LT1
+
+
appropriate battery. The micropro-
cessor monitors the presence of
batteries and the AC adapter through
a supply monitor block, or, in the case
of some battery packs, through a
thermistor sensor. This block com-
prises a resistor divider and a
comparator for each supply. If the AC
adapter is present, the two switches
are turned off by the microprocessor
and the power is delivered to the
input of the system DC/DC switching
regulator via a Schottky diode.
Conclusion
The LTC1473 dual PowerPath switch
driver eases the design of the front
end of the power management sys-
tem. Designed to drive low cost
N-channel MOSFET switches and
packed with numerous protection fea-
tures in a narrow, 16-lead SSOP
package, the LTC1473 solves the
problems of cost, space and reliability
for power management system
designers.
Figure 3. Dual-battery power-management system
Authors can be contacted
at (408) 432-1900
Linear Technology Magazine • February 1997
11
DESIGN FEATURES
The LTC1560-1: a 1MHz/500kHz
Continuous-Time, Low Noise,
Elliptic Lowpass Filter by Nello Sevastopoulos
Introduction
The LTC1560-1 is a high frequency,
continuous-time, low noise filter. It is
a single-ended input, single-ended
output, 5th order elliptic lowpass fil-
ter with a pin-selectable cutoff
frequency (f
C
) of 1MHz or 500kHz.
Several features distinguish the
LTC1560-1 from other commercially
available high frequency, continuous-
time monolithic filters:
❏Fifth order 1MHz or 500kHz
elliptic response in an SO-8
package
❏No external components or
clocks required
❏Better than 60dB stopband
attenuation
❏75dB signal-to-noise ratio (SNR)
❏0.3dB passband ripple
The LTC1560-1 delivers accurate
fixed cutoff frequencies of 500kHz
and 1MHz without the need for inter-
nal or external clocks. Through a
simple mask change, other fre-
quencies from 450kHz to 1.3MHz can
be produced upon demand. The
LTC1560-1’s extremely small size
makes it suitable for compact designs
(see Figure1) and for a variety of ap-
plications, including communication
filters, antialiasing filters and smooth-
ing or reconstruction filters.
DC Performance and
Power Shutdown
The LTC1560-1 operates with ±5V
supplies and has a power shutdown
mode. The typical DC output swing of
the filter is from –3V to 3.5V. The
output DC offset of the filter is typi-
cally ±200mV. The operating power
supply range is ±4V to ±6V.
AC Performance
Frequency Response
The LTC1560-1 offers a pin-select-
able cutoff frequency of either 500kHz
(Figure 2; pin 5 tied to V
+
) or 1MHz
(pin 5 tied to V
–
). The detailed pass-
band frequency response of the 1MHz
filter is shown in Figure 3. In the
1MHz mode, the passband is flat up
to 0.55 × f
C
with a typical ripple of
±0.2dB, increasing to ±0.3dB up to
0.9 × f
C
. The typical gain at f
C
is
–0.6dB. Referring to Figure 4, note
that the transition band has a gain of
–22dB at 1.44 × f
C
rolling off to –47dB
1
2
3
4
8
7
6
5
VOUT
SD
V+
0.5FC/FC
LTC1560-1
GND
VIN
GND
V–
1560_01.eps
1
2
3
4
8
7
6
5
VOUT
5V
–5V, 1MHz
5V, 500kHz
0.1µF
(OR 5V)
0.01µF
0.01µF0.1µF
LTC1560-1
VIN
–5V
1560_02.eps
FREQUENCY (MHz)
–0.6
0
–0.1
–0.2
–0.3
–0.4
–0.5
0.6
0.5
0.4
0.3
0.2
0.1
GAIN (dB)
1.00.90.80.70.6
1560_03.eps
0.1 0.50.40.30.2
FREQUENCY (MHz)
–90
–40
–50
–60
–70
–80
10
0
–10
–20
–30
GAIN (dB)
10
1560_04.eps
0.1 1
f
C
= 500kHz
f
C
= 1MHz
Figure 1. LTC1560-1 in an SO-8 package Figure 2. 1MHz or 500kHz elliptic lowpass
filter with no external components Figure 4. Gain vs frequency of the 1MHz and
500kHz filters
Figure 3. Expanded passband ripple for the
1MHz filter
The LTC1560-1’s extremely
small size makes it well
suited for compact designs
and a variety of applications,
including communication
filters, antialiasing filters
and smoothing or
reconstruction filters.
The LTC1560-1 provides a power
shutdown option that significantly
reduces current consumption when
the device is not being used. The filter
operation could be controlled by a
TTL input together with an inverter
applied to the SD pin (pin 7). A logic
high input turns the device on for
normal operation, whereas a logic low
puts the filter into its sleep mode, in
which it dissipates only 5mW of power.
(Leaving pin 7 open yields the default
mode of normal operation.)
Linear Technology Magazine • February 1997
12
DESIGN FEATURES
at 2 × f
C
. The stopband attenuation is
63dB starting from 2.43 × f
C
and
remains at least 60dB for input
frequencies up to 10MHz. When pro-
grammed for f
C
= 500kHz, the
frequency response remains the same,
with the exception of the gain at f
C
,
which is typically –1.3dB. Figure 4
compares the gain responses of the
1MHz and 500kHz filters.
Noise and
Distortion Performance
The LTC1560-1 architecture offers
not only low wide band noise but also
low total harmonic distortion (THD).
The combination of low noise and low
distortion means a wide dynamic
range. With a 1V
RMS
input signal, the
signal-to-noise ratio (SNR) is 69dB
and the THD + Noise is –63dB (0.07%).
The maximum SNR of 75dB is
achieved with a 2.1V
RMS
input signal.
This results in –46dB (0.5%) THD.
For the 500kHz device, the noise per-
formance is even better, with 77dB
SNR at a 1V
RMS
input.
–
+
1
2
3
4
8
7
6
5
5V
3
1k
2
4
V
OUT
7
LT1360
15V
–15V
8
–5V, 1MHz
5V, 500kHz
0.1µF
(OR 5V)
0.01µF
0.01µF
0.1µF
0.1µF
0.1µF
LTC1560-1
V
IN
–5V
1560_05.eps
–
+
–15V
15V
0.1µF
0.1µF
1
2
3
4
8
7
6
5
5V
3
1k
2
4
VOUT
7
LT1360 8
0.1µF
(OR 5V)
0.01µF
0.01µF
8.1k
0.1µF
LTC1560-1
VIN
300pF
–5V
1560_06.eps
300pF
To achieve the full high frequency
performance from the filter, a small
resistor (about 200 ) should be added
at the output of the device to isolate
any capacitive load greater than 20pF.
Figure 5 shows a typical application
circuit to be used for any AC
performance measurements of the
LTC1560-1. Any high speed, high
slew-rate operational amplifier such
as the LT1360 can serve as the buffer.
To correctly evaluate the high fre-
quency distortion performance of the
LTC1560-1 requires a very low dis-
tortion input signal, either from a
very high quality signal generator or,
if such a source is not available, from
a source that has been filtered to
control its harmonic content.
Applications and
Experimental Results
The LTC1560-1 can be used not only
as a single device (as shown in Fig-
ures 2 and 5) but also as part of a
more complete frequency-shaping
system. Two representative examples
follow.
Highpass-Lowpass Filter
As a typical application in communi-
cation systems, where there is a need
to reject DC and some low frequency
signals, a 2nd order RC highpass
network can be inserted in front of the
LTC1560-1 to obtain a highpass-low-
pass response. Figures 6 and 7 depict
the network and its measured fre-
quency response, respectively. Notice
that the second resistor in the high-
pass filter is the input resistance of
the LTC1560-1, which is about 8.1k.
Delay-Equalized Elliptic Filter
Although elliptic filters offer high Q
and a sharp transition band, they
lack a constant group delay in the
passband, which implies more ring-
ing in the time-domain step response.
In order to minimize the delay ripple
in the passband of the LTC1560-1, an
allpass filter (delay equalizer) is cas-
caded with the LTC1560-1, as shown
in Figure 8. Figures 9 and 10 illus-
trate the eye diagrams before and
after the equalization, respectively.
An eye diagram is a qualitative
representation of the time-domain
response of a digital communication
system. It shows how susceptible the
system is to intersymbol interference
(ISI). Intersymbol interference is
caused by erroneous decisions in the
receiver due to pulse overlapping and
decaying oscillations of a previous
symbol. A pseudorandom 2-level se-
quence has been used as the input of
the LTC1560-1 to generate these eye
diagrams. The larger eye opening in
Figure 5. A typical circuit for evaluating the full performance of the LTC1560-1
Figure 6. A highpass-lowpass filter
Figure 7. Measured frequency response of
Figure 6’s circuit
Linear Technology Magazine • February 1997
13
DESIGN FEATURES
–
+
–
+
1
2
3
4
8
7
6
5
5V
2
6.49k
6.65k
49.9Ω
22pF 0.1µF
0.1µF
22pF
9.75k
20k
40.2k
3V
OUT
1/2 LT1364 16
5
4
8
5V
1/2 LT1364
–15V
7
0.1µF
(OR 5V)
0.01µF
0.01µF0.1µF
LTC1560-1
V
IN
–5V
1560_08.eps
Figure 10, an indication of the equal-
ization effect, leads to reduced ISI.
Note that in Figure 8, the equalizer
section has a gain of 2 for driving and
back-terminating 50 cable and load.
For a simple unterminated gain-of-1
equalizer, the 40.2k resistor changes
to 20k and the 49.9 r esistor is re-
Figure 8. Augmenting the LTC1560-1 for improved delay flatness
Figure 9. 2-level eye diagram of the LTC1560-1 before equalization Figure 10. 2-level eye diagram of the equalized filter
for
the latest information
on LTC products,
visit
www.linear-tech.com
Mojitaba Atarodi contributed significant portions
of this article.
moved from the circuit. The 22pF
capacitors are 1% or 2% dipped silver
mica or COG ceramic.
Conclusions
The LTC1560-1 is a 5th order elliptic
lowpass filter that features a 10-bit
gain linearity at signal ranges up to
1MHz. Being small and user friendly,
the LTC1560-1 is suitable for any
compact design. It is a monolithic
replacement for larger, more expen-
sive and less accurate solutions in
communications, data acquisitions,
medical instrumentation and other
applications.
Linear Technology Magazine • February 1997
14
DESIGN FEATURES
The LTC1594 and LTC1598:
Micropower 4- and 8-Channel
12-Bit ADCs by Kevin R. Hoskins and Marco Pan
Introduction
Data acquisition applications that
require low power dissipation fall into
two general areas: products that re-
quire highly efficient power use, such
as battery-powered portable test
equipment and remotely located data
logging equipment, and products that
either operate in high temperature
environments or must not contribute
to increasing ambient temperature.
To help meet these requirements, Lin-
ear Technology has introduced the
LTC1594 and LTC1598.
Micropower ADCs
in Small Packages
The LTC1594 and LTC1598 are
micropower 12-bit ADCs that feature
a 4- and 8-channel multiplexer, re-
spectively. The LTC1594 is available
in a 16-pin SO package and the
LTC1598 is available in a 24-pin SSOP
package. Each ADC includes a simple,
efficient serial interface that reduces
interconnects and, thereby, possible
sources of corrupting digital noise.
Reduced interconnections also reduce
board size and allow the use of pro-
cessors having fewer I/O pins, both of
which help reduce system costs. Small
packages also shorten the distance
between the ADC and its supply and
voltage reference bypass components.
This reduces lead inductance and
allows bypass components to operate
as efficiently as possible.
Conserve Power with
Auto Shutdown Operation
The LTC1594 and LTC1598 include
an auto shutdown feature that re-
duces power dissipation when the
converter is inactive (whenever the
CS signal is a logic high). Nominal
power dissipation while either con-
verter is clocked at 320kHz is typically
1.6mW. The curve in Figure 1 indi-
cates the amount of current drawn by
this MUXed 12-bit ADC family for
sample rates up to 16.8ksps. As an
example, when converting at 4ksps,
the dissipation is just 450µW and
270µW for the 5V and 3V parts,
respectively.
Supply Flexibility:
2.7V or 5V
To increase applications flexibility,
the LTC1594 and LTC1598 are also
available as 3V parts (LTC1594L and
LTC1598L), which are tested for 2.7V
operation. The LTC1594L and
LTC1598L typically draw 160µA at
maximum conversion rate, one-half
of the supply current drawn by the 5V
parts. Nominal power dissipation
while either converter is clocked at
200kHz (10.5ksps) is typically 800µW.
SAMPLE FREQUENCY (kHz)
0.1
1
SUPPLY CURRENT (µA)
10
100
1000
1 10 100
1598_01.eps
T
A
= 25°C
V
CC
= 5V
V
REF
= 5V
f
CLK
= 320kHz
1
2
3
4
5
6
7
8
9
10
11
12
24
23
22
21
20
19
18
17
16
15
14
13
CH5
CH6
CH7
GND
CLK
CS MUX
D
IN
COM
GND
CS ADC
D
OUT
NC
CH4
CH3
CH2
CH1
CH0
V
CC
MUXOUT
ADCIN
V
REF
V
CC
CLK
NC
LTC1598
ANALOG INPUTS
0V TO 5V
RANGE
R4, 7.5k R2, 7.5k
1µF
5V
1598_02.eps
DATA IN
CHIP SELECT
CLOCK
DATA OUT
–
+
1µF
C6
0.015µF
C4
0.03µF
C2
0.1µF
R1, 7.5k R3, 7.5k
C3
0.03µF
C5
0.015µF
–
+
C1
0.1µF
5V
1/2
LT1368
1/2
LT1368
Figure 1. Supply current vs sample rate
Figure 2. A simple data acquisition system takes advantage of the LTC1598’s MUXOUT/ADCIN pins to filter analog signals prior to ADC conversion.
Linear Technology Magazine • February 1997
15
DESIGN FEATURES
Good DC Performance
The DC specs include excellent dif-
ferential nonlinearity (DNL) of
±3/4LSB, as required by pen-screen
and other monitoring applications.
No missing codes are guaranteed over
temperature.
Versatile, Flexible Serial I/O
The serial interface found on the
LTC1594 and LTC1598 is designed
for ease of use, flexibility, minimal
interconnections and I/O compatibil-
ity with QSPI, SPI, MICROWIRE™
and other serial interfaces. The MUX
and the ADC have separate chip se-
lect (CS) and serial clock inputs, which
adds versatility. The remaining serial
interface signals are data input (D
IN
)
and data output (D
OUT
). The maxi-
mum serial clock frequencies are
320kHz and 200kHz for the 5V and
3V parts, respectively.
Latch-up Proof MUX Inputs
The LTC1594’s and LTC1598’s input
MUXes are designed to handle input
voltages that exceed the nominal in-
put range, GND to the supply voltage,
without latch-up. Although an over-
driven, unselected channel may
corrupt a selected, correctly driven
channel, no latch-up occurs and cor-
rect conversion results resume when
the offending input voltage is removed.
The MUX inputs remain latch-up proof
for input currents up to ±200mA over
temperature.
Individual ADC
and MUX Chip Selects
Enhance Flexibility
The LTC1594 and LTC1598 feature
separate chip selects for ADC and
MUX. This allows the user to select a
particular channel once for multiple
conversions. This has the following
benefits: first, it eliminates the over-
head of sending D
IN
word for the same
channel each time for each conver-
sion; second, it avoids possible
glitches that may occur if a slow-
settling antialiasing filter is used; and
third, it sets the gain once for mul-
tiple conversions if the MUXOUT/
ADCIN loop is used to create a pro-
grammable gain amplifier (PGA).
MUXOUT/ADCIN
Loop Economizes
Signal Conditioning
The MUXOUT and ADCIN pins form a
very flexible external loop that allows
PGA and/or processing analog input
signals prior to conversion. This loop
is also a cost effective way to perform
the conditioning, because only one
circuit is needed instead of one for
each channel. Figure 2 shows the
loop being used to antialias filter sev-
eral analog inputs. The output signal
of the selected MUX channel, present
on the MUXOUT pin, is applied to R1
of the Sallen-Key filter. The filter band
limits the analog signal and its out-
put is applied to ADCIN. The LT1368
rail-to-rail op amps used in the filter
will, when lightly loaded as in this
application, swing to within 8mV of
the positive supply voltage. Since only
one circuit is used for all channels,
each channel sees the same filter
characteristics.
1598_03.eps
CH0
CH1
CH2
CH3
CH4
CH5
CH6
CH7
20
21
22
23
24
1
2
3
64R
32R
16R
8R
4R
2R
R
R
+
–
8 COM
18 MUXOUT
GND
4, 9
10
6
5, 14
11
7
CS ADC
CS MUX
CLK
DOUT
DIN
12
13
NC
NC
12-BIT
SAMPLING
ADC
8-CHANNEL
MUX
1
2
3
4
5
6
7
8
16
15
14
13
12
11
10
9
LTC1391
5V
1µF
ADCIN
17 16 15, 19 1µF
0.1µF
5V
1µF
5V
VREF VCC
–
+
CH0
CH1
CH2
CH3
CH4
CH5
CH6
CH7
V+
D
V–
DOUT
DIN
CS
CLK
GND
1/2 LT1368
LTC1598
µP/µC
Figure 3. Using the MUXOUT/ADCIN loop of the LTC1598 to form a PGA with eight gains in a noninverting configuration
MICROWIRE is a trademark of National Semiconductor
Corp.
Linear Technology Magazine • February 1997
16
DESIGN FEATURES
Using MUXOUT/
ADCIN Loop as PGA
Figure 3 shows the LTC1598’s
MUXOUT/ADCIN loop and an LT1368
being used to create a single-channel
PGA with eight noninverting gains.
Combined with the LTC1391, as
shown in Figure 3, the system can
expand to eight channels and eight
gains for each channel. Using the
LTC1594, the PGA is reduced to four
gains. The output of the LT1368 drives
the ADCIN and the resistor ladder.
The resistors above the selected MUX
channel form the feedback for the
LT1368. The loop gain for this ampli-
fier is (R
S
1/R
S
2) + 1. R
S
1 is the
summation of the resistors above the
selected MUX channel and R
S
2 is the
summation of the resistors below the
selected MUX channel. If CH0 is se-
lected, the loop gain is 1 since R
S
1 is
0. Table 1 shows the gain for each
MUX channel. The LT1368 dual rail-
to-rail op amp is designed to operate
with 0.1µF load capacitors. These
capacitors provide frequency compen-
sation for the amplifiers, help reduce
the amplifiers’ output impedance and
improve supply rejection at high fre-
quencies. Because the LT1368’s I
B
is
low, the R
ON
of the selected channel
will not affect the loop gain given by
the formula above. In the case of the
inverting configuration of Figure 4,
the selected channel’s R
ON
will be
added to the resistor that sets the
loop gain.
8-Channel, Differential,
12-Bit A/D System Using
the LTC1391 and LTC1598
The LTC1598 can be combined with
the LTC1391 8-channel, serial-inter-
face analog multiplexer to create a
differential A/D system. Figure 5
shows the complete 8-channel, dif-
ferential A/D circuit. The system uses
the LTC1598’s MUX as the nonin-
verting input multiplexer and the
LTC1391 as inverting input multi-
plexer. The LTC1598’s MUXOUT
drives the ADCIN directly. The
inverting multiplexer’s output is ap-
plied to the LTC1598’s COM input.
The LTC1598 and LTC1391 share the
CS, D
IN
, and CLK control signals.
1598_04.eps
CH0
CH1
CH2
CH3
CH4
CH5
CH6
CH7
20
21
22
23
24
1
2
3
128R
64R
32R
16R
8R
4R
2R
R
+
–
8 COM GND
4, 9
10
6
5, 14
7
11
CS ADC
CS MUX
CLK
D
IN
D
OUT
12
13
NC
NC
12-BIT
SAMPLING
ADC
ADCINMUXOUT
18 17 16 15, 19 1µF
0.1µF
5V
5V
V
REF
V
CC
–
+
1/2 LT1368
128R
LTC1598
1598_05.eps
CH0
CH1
CH2
CH3
CH4
CH5
CH6
CH7
20
21
22
23
24
1
2
3
+
–
8-CHANNEL
MUX
8 COM GND
4, 9
10
6
5, 14
7
11
CS ADC
CS MUX
CLK
D
IN
D
OUT
12
13
NC
NC
12-BIT
SAMPLING
ADC
ADCINMUXOUT
18 17 16 15, 19 1µF
5V
V
REF
V
CC
1
2
3
4
5
6
7
8
16
15
14
13
12
11
10
9
LTC1391
CH0
CH7
D
IN
CLK
CS
D
OUT
5V
CH0
CH1
CH2
CH3
CH4
CH5
CH6
CH7
V+
D
V–
D
OUT
D
IN
CS
CLK
GND
LTC1598
Figure 4. Using the MUXOUT/ADCIN loop of the LTC1598 to form a PGA with
eight inverting gains
Figure 5. Using the LTC1598 and LTC1391 as an 8-channel, differential 12-bit ADC system:
opening the indicated connection and shorting the dashed connection daisy-chains the
external and internal MUXes, increasing channel-selection flexibility.
continued on page 20
XUM
lennahC
gnitrevninoN
niaG
gnitrevnI
niaG
011–
122–
244–
388–
46161–
52323–
64646–
7821821–
Table 1. PGA gain for each MUX channel of
Figures 3 and 4
Linear Technology Magazine • February 1997
17
DESIGN FEATURES
–
+
–
+
–
+
+
+
VFB
5Ω
RSENSE
(OPTIONAL)
LBI
1µA
RUN
LBOUT
LB
V
C
1SHOT
VFB
IN
1.23V
REFERENCE
ON
LBI
GND
READY
1.23V
1474_01.eps
5µS
ON
ON
100mV VIN
VIN
VOUT
SENSE
SW
1×25×
CONNECTION NOT PRESENT IN LTC1474
CONNECTION PRESENT IN LTC1474 ONLY
OUT
LTC1474 and LTC1475 High Efficiency
Switching Regulators Draw Only
10µA Supply Current by Greg Dittmer
Introduction
Maximizing battery life, one of the key
design requirements for all battery-
powered products, is now easier with
Linear Technology’s new family of
ultralow quiescent current, high
efficiency step-down regulator ICs,
the LTC1474 and LTC1475. The
LTC1474/LTC1475 are step-down
regulators with on-chip P-channel
MOSFET power switches. These regu-
lators draw only 10µA supply current
at no load while maintaining the out-
put voltage. With the on-chip switch
(1.3 at V
IN
= 10V), only four external
components are necessary to make a
complete, high efficiency (up to 92%)
step-down regulator. Low component
count and the LTC1474/LTC1475’s
tiny MSOP packages provide a mini-
mum-area solution to meet the limited
space requirements of portable appli-
cations. Wide supply voltage range
(3V–18V) and 100% duty cycle capa-
bility for low dropout allow maximum
energy to be extracted from the bat-
tery, making the LTC1474/LTC1475
ideal for moderate current (up to
300mA) battery-powered applications.
The peak inductor current is pro-
grammable via an optional current
sense resistor to allow the design to
be optimized for a particular applica-
tion and to provide short-circuit pro-
tection and excellent start-up
behavior. Other features include Burst
Mode™ operation to maintain high
efficiency over almost four decades of
load current, an on-chip low-battery
comparator and a shutdown mode to
further reduce supply current to 6µA.
The LTC1475 provides on/off control
with push-button switches for use in
handheld products.
The LTC1474/LTC1475 are avail-
able in adjustable output voltage
versions, in 8-pin MSOP and SO
packages.
Figure 1. LTC1474/LTC1475 functional block diagram
Linear Technology Magazine • February 1997
18
DESIGN FEATURES
1474_02.eps
MODE
RUN
ONE-SHOT
1.23V REFERENCE
INDUCTOR
CURRENT
CURRENT
COMPARATOR
VOLTAGE
COMPARATOR
LOW-BATTERY
COMPARATOR
SHUTDOWNSLEEP5µS OFF-TIMEON
OFFOFFOFFON (100µA)
OFFOFFON (10µA)ON (5µA)
OFFON (5µA)
ON (4µA)
ON (1µA)
High Performance on a
Microampere Budget
The functional block diagram, shown
in Figure 1, provides a study in power
management. LTC1474/LTC1475
control the output voltage by charg-
ing the output capacitor in short burst
cycles using Burst Mode operation.
The peak current in each burst cycle
(up to 400mA) is set by the external
sense resistor. As the load increases,
the frequency of the burst cycles in-
creases (up to a maximum of 170kHz)
to maintain the charge in the output
capacitor. The burst cycle begins when
the output voltage falls below the
lower threshold of the voltage com-
parator (V). The P-channel power
switch turns on to ramp the inductor
current up until either the current
comparator (C) trips on peak current
or the voltage comparator trips on the
upper voltage threshold. At this time
the one-shot is triggered and begins
the 5µs off-time period, during which
the switch is turned off and inductor
current ramps down. If, at the end of
the off-time, the output voltage is
below the upper voltage comparator
threshold, the switch is turned on
again to begin another cycle. If the
upper voltage threshold is exceeded,
however, the switch remains off and
the output capacitor supplies the load
current. The switch remains off until
the load current discharges the out-
put capacitor below the lower voltage
threshold.
The ultralow supply current and
very high efficiency at light loads are
achieved by powering only those func-
tions that are necessary at any given
time. Figure 2 is a summary of the
current used by each of the functions
in each of the different operating
modes. During sleep mode, when the
output capacitor is supplying the load,
only the 1.23V reference, the voltage
comparator and low-battery compara-
tor are on; together they draw only
10µA of supply current to perform
their functions. These three functions
are on at all times except during
shutdown. During shutdown, the volt-
age comparator is turned off to save
an additional 5µA. The current com-
parator, which, as a result of its speed
requirement necessarily draws more
current, is only turned on during the
switch on-time, when it is needed to
monitor the switch current. When the
current or voltage comparator trips,
the current comparator is turned off
and the one-shot timer is triggered,
drawing 10µA during its 5µs time-
out period. When the one-shot times
out it turns off, reducing the supply
current to the 10µA needed for the
voltage comparator, reference and low-
battery comparator, until a new burst
cycle begins.
In Control of
Inductor Current
Excessive peak inductor current can
be a liability. Lower peak current
offers the advantages of smaller volt-
age ripple (∆V = I
PEAK
× ESR), lower
noise and less stress on alkaline bat-
teries and other circuit components.
Also, lower peaks allow the use of
inductors with smaller physical size.
The LTC1474/LTC1475 provide flex-
ibility by allowing the peak switch/
inductor current to be programmed
with an optional sense resistor to
provide just enough to meet the load
requirement. Without a sense resis-
tor (that is, with pins 6 and 7 shorted)
the current limit defaults to its maxi-
mum of 400mA. Using the default
current limit eliminates the need for a
sense resistor and associated de-
coupling capacitor.
A sense MOSFET (a portion of the
main power MOSFET) is used to di-
vert a sample (about 5%) of the switch
current through the internal 5 sense
resistor. The internal current com-
parator monitors the voltage drop
across the series combination of the
internal and external sense resistors
and trips when this voltage drop ex-
ceeds 100mV. This results in a peak
current of I
PEAK
= 0.1/(0.25 + R
SENSE
)
+ 0.2 × (V
IN
– V
OUT
)/L. The second
term in the above equation is the
result of overshoot of the peak cur-
rent due to delays in the current
comparator and must be taken into
account at lower inductances and
higher supply voltages to guarantee
that maximum current ratings of the
inductor and switch are not exceeded.
Note that worst case will occur during
a short circuit, when V
OUT
= 0.
3.3V/200mA
Step-Down Regulator
A typical application circuit using the
LTC1474 is shown in Figure 3. This
circuit supplies a 200mA load at 3.3V
with an input supply range of 4V–18V
(3.3V at no load). The 0.1 sense
resistor reduces the peak current to
about 285mA, which is the minimum
level necessary to meet the 200mA
load current requirement with a
Figure 2. Supply current breakdown during each operational mode
Linear Technology Magazine • February 1997
19
DESIGN FEATURES
100µH inductor. The peak can be
reduced further if a higher value in-
ductor is used. Since the output
capacitor dominates the output volt-
age ripple, an AVX TPS series low ESR
(150m ) output capacitor is used to
provide a good compromise between
size and low ESR. With this capacitor
the output ripple is less than 50mV.
Efficiency Considerations
The efficiency curves for the 3.3V/
200mA regulator at various supply
voltages are shown in Figure 4. Note
the flatness of the curves over the
upper three decades of load current
and that the efficiency remains high
down to extremely light loads. Effi-
ciency at light loads depends on low
quiescent current. The curves are flat
because all significant sources of loss
except for the 10µA standby cur-
rent—I
2
R losses in the switch, catch
diode losses, gate charge losses to
turn on the switch and burst cycle DC
supply current losses—are identical
during each burst cycle. The only
variable is the rate at which the burst
cycles occur. Since burst frequency is
proportional to load, the loss as a
percentage of load remains relatively
constant. The efficiency drops off as
the load decreases below about 1mA
because the non-load-dependent
10µA standby current loss then con-
stitutes a more significant percentage
of the output power. This loss is pro-
portional to V
IN
and thus its effect is
more pronounced at higher V
IN
.
Care must be used in selecting the
catch diode to maximize both low and
high current efficiency. Low reverse
leakage current is critical for maxi-
mizing low current efficiency because
the leakage can potentially approach
the magnitude of the LTC1474/
LTC1475 supply current. Low for-
ward drop is critical for high current
efficiency because loss is proportional
to forward drop. These are conflicting
parameters, but the MBR0530 0.5A
Schottky diode used in the Figure 3 is
a good compromise. Lower induc-
tances also help by minimizing DCR
without increasing the inductor size.
However, lower inductances also re-
duce the maximum available output
power for a given I
PEAK
due to the fixed
5µs off-time and may also increase
the peak current overshoot due to
high di/dt (see formula for I
PEAK
).
LTC1475 Push-Button
On/Off Operation
The LTC1475 provides the option of
push-button control of run and shut-
down modes for handheld products.
In contrast to the LTC1474’s run/
shutdown mode, which is controlled
by a voltage level at the RUN pin
(ground = shutdown, open/high =
run), the LTC1475 run/shutdown
mode is controlled by an internal S/R
flip-flop that is set (run mode) by a
momentary ground at the RUN pin
and reset (shutdown mode) by a mo-
mentary ground at the LBI pin (see
Figure 5). This provides simple on/off
control with two push-button
switches. The simplest implementa-
tion of this function is shown in Figure
6, with normally open push-button
switches connected to the RUN and
LBI pins. Note that because the switch
on LBI is normally open, it doesn’t
+
10pF
1.69M
1M
100k
1474_03.eps
RUN
V
IN
SENSE
SW
V
FB
LBO
0.1µF10µF
25V
1000pF
LBI
LTC1474
LBI LBO
MBR0530
GND
8
7
6
5
1
V
OUT
3.3V/200mA V
IN
4V-18V
RUN
D:
L:
C
OUT
:
C
IN
:
MBR0530
SUMIDA CDRH74
TPSC107006R0150
THC50EIE106Z
2
3
4
0.1Ω
100µF
6.3V
L
100µH
LOAD CURRENT (mA)
50
60
70
80
90
100
EFFICIENCY (%)
200
1474_04.eps
0.02 0.2 2 20
L= 100 µH
V
OUT
= 3.3V
R
SENSE
= 0.1 Ω
V
IN
= 5V V
IN
= 10V
V
IN
= 15V
LBI
RUN
MODE RUN SHUTDOWN RUN
MODE RUN SHUTDOWN RUN
RUN
LTC1474
LTC1475
RUN OVERRIDES SHUTDOWN
WHILE RUN IS LOW
+
100k
10µF
1474_05.eps
V
IN
SENSE
SW
OFF
V
FB
V
FB
V
OUT
V
FB
LBO
LTC1475
V
BATT
V
BATT
GND
8
7
6
5
1
2
3
4
ON RUN
LBI/SD
1M 2.2M
100µH
100µF
Figure 3. LTC1474 3.3V/200mA step-down regulator Figure 4. Efficiency vs load for Figure 3’s
circuit
Figure 5. Comparison of RUN/SHUTDOWN
operation for the LTC1474 and LTC1475 Figure 6. LTC1475 step-down regulator with push-button on/off control
Linear Technology Magazine • February 1997
20
DESIGN FEATURES
affect the normal operation of this
input to the low-battery comparator.
With a resistor divider network con-
nected to the LBI to monitor the input
supply voltage level, the voltage at
this pin will normally be above the
low-battery trip threshold of 1.23V.
When this pin is pulled below 0.7V by
depressing the switch, the internal
flip-flop is reset to invoke shutdown.
Figure 7 shows an example of push-
button on/off control of a LTC1475
microcontroller application with a
single push button. The push button
is connected to the microcontroller as
a discrete input so that the
microcontroller can monitor the state
of the push button. The LTC1475 LBI
pin is connected to one of the
microcontroller’s open-drain discrete
outputs so that it can force the
LTC1475 off when it detects a
depressed push button. Because the
LTC1475 supplies power to
the microcontroller, once the micro-
controller is off, it can no longer turn
the LTC1475 back on. However, since
the push button is also connected
directly to the RUN pin, the LTC1475
can be turned back on directly from
the push button without the micro-
controller. The LTC1475 then powers
up the microcontroller. The discrete
inputs of most microcontrollers have
a reverse biased diode between the
input and supply; thus a blocking
diode with less than 1µA leakage is
necessary to prevent the powered
down microcontroller from pulling
down on the RUN pin.
Conclusion
The LTC1474 and LTC1475 ultralow
quiescent current step-down regula-
tor ICs provide a perfect solution for
low to moderate current (up to 300mA)
battery-powered applications where
high efficiency and maximizing bat-
tery life are critical. The 10µA no-load
supply current requirement ensures
that little battery energy is wasted on
the regulator. The internal P-channel
power switch, MSOP package and the
need for as few as four additional
components result in a very compact
solution, and the current program-
mability and wide supply-voltage
range provide the flexibility neces-
sary to optimize the design for a variety
of applications.
+
100k
100µF
100µH
10µF
1M 2.2M
1474_06.eps
V
IN
SENSE
SW
V
FB
V
OUT
V
FB
V
CC
LBO
LTC1475
V
BATT
V
BATT
GND
8
7
6
5
1
2
3
4
ON/OFF
MMBD914LT1
0.1µF
µC
RUN
LBI/SD
V
FB
Figure 7. A single push-button controls on/off for the LTC1475 regulator and microcontroller.
This arrangement simultaneously
selects the same channel on each
multiplexer and maximizes the
system’s throughput. The dotted-line
connection daisy-chains the MUXes
of the LTC1391 and LTC1598 to-
gether. This configuration provides
the flexibility to select any channel
in the noninverting input MUX with
respect to any channel in the invert-
ing input MUX. This allows any
combination of signals applied to the
inverting and noninverting MUX in-
puts to be routed to the ADC for
conversion.
Conclusion
With their serial interfaces, small
packages, and auto shutdown, the
LTC1594(L) and LTC1598(L) achieve
very low power consumption while
occupying very little circuit board
area. Their outstanding DC specifica-
tions make them the choice for
applications that benefit from low
power, battery conserving operation,
multichannel inputs and space and
component saving signal condition-
ing loop.
LTC1594/LTC1598, continued from page 16
Linear Technology Magazine • February 1997
21
DESIGN IDEAS
–
+
DI1440_01.EPS
CMOS
ONE-SHOT
(CD4047)
LTC1440
9V
DC
2X9.1MΩ
27kΩ
27kΩ
FB
λ/4
λ/2.5
D1
1N5711
DETECTOR
Z
0
= 50Ω
D2
1N5711
100pF
REFERENCE
100pF
Q
Q
Biased Detector Yields High Sensitivity
with Ultralow Power Consumption
RF ID tags, circuits that detect a
“wake-up” call and return a burst of
data, must operate on very low quies-
cent current for weeks or months, yet
have enough battery power in reserve
to answer an incoming call. For small-
est size, most operate in the ultrahigh
frequency range, where the design of
a micropower receiver circuit is prob-
lematic. Familiar techniques, such as
direct conversion, super regeneration
or superheterodyne, consume far too
much supply current for long battery
life. A better method involves a
technique borrowed from simple field-
strength meters: a tuned circuit and
a diode detector.
Figure 1 shows the complete cir-
cuit, which was tested at 470MHz.
This circuit contains a couple of im-
provements over the standard
L/C-with-whip field-strength meter.
Tuned circuits aren’t easily con-
structed or controlled at UHF, so a
transmission line is used to match
the detector diode (1N5711) to a 6"
whip antenna. The 0.4-wavelength
section presents an efficient, low im-
pedance match to the base of the
quarter-wave whip, but transforms
the received energy to a relatively
high voltage at the diode for good
sensitivity.
Biasing the detector diode improves
the sensitivity by an additional 10dB.
The forward threshold is reduced to
essentially zero, so a very small volt-
age can generate a meaningful output
change. The detector diode’s bias point
is monitored by an LTC1440 ultralow
power comparator, and by a second
diode, which serves as a reference.
When a signal at the resonant fre-
quency of the antenna is received,
Schottky diode D1 rectifies the
incoming carrier and creates a nega-
tive-going DC bias shift at the
noninverting input of the compara-
tor. Note that the bias shift is sensed
at the base of the antenna where the
impedance is low, rather than at the
Schottky where the impedance is high.
This introduces less disturbance into
the tuned antenna and transmission-
line system. The falling edge of the
comparator triggers a one-shot, which
temporarily enables answer-back and
other pulsed functions.
Total current consumption is
approximately 5µA. Monolithic one-
shots draw significant load current,
but the venerable ‘4047 is about the
best in this respect. Alternatively, a
discrete one-shot constructed from a
quad NAND gate draws negligible
power.
Sensitivity is excellent. The fin-
ished circuit can detect 200mW
radiated from a reference dipole at
100'. Range, of course, depends on
operating frequency, antenna orien-
tation and surrounding obstacles; in
the clear, a more reasonable distance,
such as 10', can be covered at 470MHz
with only a few milliwatts.
All selectivity is provided by the
antenna itself. Add a quarter-wave
stub (shorted with a capacitor) to the
base of the antenna for better selec-
tivity and improved rejection of low
frequency signals.
Figure 1. Micropower field detector for use at 470MHz
by Mitchell Lee
DESIGN IDEAS
Biased Detector Yields High
Sensitivity with Ultralow Power
Consumption .......................... 21
Mitchell Lee
LT1256 Voltage-Controlled
Amplitude Limiter .................. 22
Frank Cox
New IC Features Reduce EMI from
Switching Regulator Circuits
................................................23
John Seago
Dual Output Voltage Regulator
................................................26
Peter Guan
Free Digital Panel Meters from the
Oppressive Yoke of Batteries
................................................27
Mitchell Lee
Battery Charger IC Can Also Serve
as Main Step-Down Converter
................................................28
Arie Ravid
Combine a Switching Regulator
and an UltraFast™ Linear
Regulator for a High Performance
3.3V Supply
................................................29
Craig Varga
What Efficiency Curves
Don’t Tell................................. 30
San-Hwa Chee
Linear Technology Magazine • February 1997
22
DESIGN IDEAS
LT1256 Voltage-Controlled
Amplitude Limiter by Frank Cox
Amplitude-limiting circuits are use-
ful where a signal should not exceed
a predetermined maximum ampli-
tude, such as when feeding an A/D or
a modulator. A clipper, which com-
pletely removes the signal above a
certain level, is useful for many appli-
cations, but there are times when it is
not desirable to lose information. For
instance, when video signals have
amplitude peaks that exceed the
dynamic range of following processing
stages, simply clipping the peaks at
the maximum level will result in the
loss of all detail in the areas where
clipping takes place. Often these well
illuminated areas are the primary
subject of the scene. Because these
peaks usually correspond to the
highest level of luminosity, they are
referred to as “highlights.” One way to
preserve some of the detail in the
highlights is to automatically reduce
the gain (compress) at high signal
levels.
The circuit in Figure 1 is a voltage-
controlled breakpoint amplifier that
can be used for highlight compres-
sion. When the input signal reaches a
predetermined level (the breakpoint),
the amplifier gain is reduced. As both
the breakpoint and the gain for sig-
nals greater than the breakpoint are
voltage programmable, this circuit is
useful for systems that adapt to chang-
ing signal levels. Adaptive highlight
compression finds use in CCD video
cameras, which have a very large
dynamic range. Although this circuit
was developed for video signals, it can
be used to adaptively compress any
signal within the 40MHz bandwidth
of the LT1256.
The LT1256 video fader is con-
nected to mix proportional amounts
of input signal and clipped signal to
provide a voltage-controlled variable
gain. The clipped signal is provided
by a discrete circuit consisting of
three transistors. Q1 acts as an emit-
ter follower until the input voltage
exceeds the voltage on the base of Q2
(the breakpoint voltage or V
BP
). When
the input voltage is greater than V
BP
,
Q1 is off and Q2 clamps the emitters
of the two transistors to V
BP
plus a
V
BE
. Q3, an NPN emitter follower,
buffers the output and drops the volt-
age a V
BE
and thus the DC level of the
input signal is preserved to the extent
allowed by the V
BE
matching and tem-
perature tracking of the transistors
used. The breakpoint voltage at the
base of Q2 must remain constant
when this transistor is turning on or
the signal will be distorted. The
LT1363 maintains a low output
impedance well beyond video frequen-
cies and makes an excellent buffer.
Figure 2 is a multiple-exposure
photograph of a single line of mono-
chrome video, showing four different
levels of compression ranging from
fully limited signal to unprocessed
input signal. The breakpoint is set to
40% of the peak amplitude to clearly
show the effect of the circuit; nor-
mally only the top 10% of video would
be compressed.
–
+
–
+
+
–
75Ω
VIDEO
IN
VIDEO
OUT
2k
1.5k
1.5k
LT1256
LT1363
1.5k
Q1 Q2
Q3
–5V
100Ω
5V
75Ω
–5V
5V
100Ω
510Ω1.5k
2k
BREAK POINT
VOLTAGE
100k
LT1004-2.5
TO V
FS
LT1256, PIN 12
TO V
CONTROL
LT1256, PIN 3
10k
5V
Q1, Q2 =2N4957
Q3 =2N2857
Figure 1. Voltage-controlled amplitude limiter
Figure 2. Multiple-exposure photograph of a
single line of monochrome video, showing
four different levels of compression
Linear Technology Magazine • February 1997
23
DESIGN IDEAS
New IC Features Reduce EMI from
Switching Regulator Circuits by John Seago
One disadvantage of using a switch-
ing regulator is that it generates
electronic noise, known as EMI (elec-
tromagnetic interference). This noise
can be conducted or radiated, and it
can affect other circuits in your prod-
uct or interfere with the operation of
nearby products. The LTC1436-PLL,
LTC1437, LTC1439 and LTC1539
have features that can be used to
suppress this interference.
Frequently, EMI problems don’t
show up until the integration phase
of product development. By using this
EMI suppression capability, a resis-
tor- or capacitor-value change may
be all that is required to solve an
interference problem. The LTC1436-
PLL shown in the circuit of Figure 1
produces a switched 5V, 3A output
and a 3.3V, 0.1A linear output. The
circuit is configured to provide either
switch-frequency synchronization or
switch-frequency modulation. Also,
transistor Q3 ensures constant fre-
quency at very low output current
levels, thus eliminating audio frequen-
cies and maintaining high efficiency
using the internal Adaptive Power™
circuitry.
Switch-Frequency
Synchronization
Switching regulator noise results from
switching high currents on and off.
This creates high energy levels at the
switching frequency and all of its
harmonics. A common EMI-control
technique is to synchronize the
switching frequency to an external
clock so that all harmonic frequencies
can be controlled. The LTC1436-PLL
uses a phase-locked loop for syn-
chronization to avoid the loss of slope
compensation common to other syn-
chronizing techniques. In addition,
the input to the VCO in the phase-
locked loop is available at the PLL LPF
(phase-locked loop lowpass filter) pin
so, that a lowpass filter can be used to
control how fast the loop acquires
lock.
Switch-Frequency Modulation
Access to the VCO input also makes it
possible to modulate the regulator’s
switching frequency. Through fre-
quency modulation, the peak energy
of the fundamental is spread over the
frequency range of modulation, thus
decreasing the peak energy level at
any one frequency. This frequency
spreading action increases with each
harmonic, so that the second har-
monic has twice the bandwidth and
the third harmonic has three times
the bandwidth until all the harmon-
ics blend together, decreasing the
signal strength at all frequencies. This
can be seen in the spectrum analyzer
plots shown in Figures 2, 3 and 4.
1
2
3
4
5
6
7
8
9
10
11
12
24
23
22
21
20
19
18
17
16
15
14
13
PLL LPF
C
OSC
RUN/SS
I
TH
SFB
SGND
V
PROG
V
OSENSE
SENSE
–
SENSE
+
AUXON
AUXFB
PLLIN
POR
BOOST
TGL
SW
TGS
V
IN
INTV
CC
BG
PGND
EXTV
CC
AUXDR
DI1436_01.eps
5V
3A
POR
3.3V
0.1A
GND
Q3
LTC1436-PLL
R3
,
10k
R6
47k
5.5V TO
24V R7
10Ω
R4
,
100Ω
R2, 10k
MOD
MOD
PLL
PLL
0.01µF
C3, 0.1µF
C8
0.1µF
R11
47k
R10
35.7k
C15
3.3µF
C11, C12: KEMET T495X226M035AS
C13, C14: AVX TPSD107M010R0065
L1: SUMIDA CDRH125-10
Q1 + Q2: SILICONIX Si4936DY (DUAL FET)
Q3: INTERNATIONAL RECTIFIER IRLML2803
R8: IRC LR2010-01-R033-J
* SEE FIGURE 6
C9
4.7µF
C10
0.1µF
Q2
Q1
D1
MBRS0530 D2
MBRS130L
C4
330pF
C2, 47pF
C5, 47pF
C7, 0.001µF
R5
100Ω
INTV
CC
C6
100pF
+
C13, C14
100µF
10V
×2
+
C12
22µF
35V
+
L1
10µH
R9
20k
R8
0.033Ω
C11
22µF
35V
+
+
Q4
MMBT2907ALT1
C1
SWITCH-
FREQUENCY
MODULATOR*
Figure 1. 2-output LTC1436-PLL test circuit
Linear Technology Magazine • February 1997
24
DESIGN IDEAS
Figure 2 shows the full load output
noise level from the circuit of Figure
1, before and after switch-frequency
modulation. The black trace shows
the normal output noise from 1kHz to
1MHz with the VCO at minimum fre-
quency, whereas the colored trace
shows output noise after modulation
around the center frequency. The
228kHz unmodulated switch-fre-
quency output noise decreased more
than 30dB through modulation
between 270kHz and 370kHz. Fig-
ures 3 and 4 show a 10dB to 15dB
attenuation in full-load output volt-
age noise from 1MHz to 30MHz after
modulation.
The VCO in the LTC1436-PLL has
an input range from 0V to 2.4V. As
shown in Figure 5, the switch fre-
quency can be modulated at least
±30% around the center frequency f
O
.
The ideal modulating signal varies an
equal amount above and below the
center frequency voltage of 1.2V, with
a constant slope. The reference cir-
cuit of Figure 6 develops a 100Hz
sawtooth voltage from 0.9V to 1.5V
that modulates the LTC1436-PLL in
Figure 1 to generate the plots shown
in Figures 2, 3 and 4. Modulator
circuit complexity is largely deter-
mined by functional requirements.
For most applications, a precision
modulating signal is not required,
because high order harmonics blend
together. Consequently, modulating
frequency, slope and peak-to-peak
voltage are not critical.
Audio Frequency Suppression
The Adaptive Power feature of the
LTC1436-PLL significantly reduces
audio frequency generation, while
maintaining good efficiency under
very light load conditions. Figure 7
shows the audio frequencies gener-
ated by the highly efficient cycle
skipping mode of the LTC1436-PLL.
Figure 8 shows the decrease in au-
dio frequencies resulting from
Adaptive Power operation. Figure 9
shows efficiency curves of both the
cycle skipping and Adaptive Power
modes along with the traditional,
forced continuous mode of operation.
Figure 2. Output noise before and after switch-frequency modulation
Figure 3. Output high frequency noise before switch-frequency modulation
Figure 4. Output high frequency noise after switch-frequency modulation
Linear Technology Magazine • February 1997
25
DESIGN IDEAS
Cycle skipping is the most efficient
mode during light-load operation,
where the output capacitor supplies
load current most of the time and is
replenished by bursts of energy at a
rate determined by the load. When
load current is low enough, the burst
rate falls into the audio-frequency
range, which can cause problems.
With the addition of Q3, an inexpen-
sive SOT-23 size MOSFET, the
Adaptive Power circuitry inside the
LTC1436-PLL takes control during
light load conditions, turning off high
current MOSFETs Q1 and Q2. Q3
and D2 are then used in a conven-
tional constant frequency buck mode,
eliminating the power loss caused by
charging and discharging the large
input capacitance of both power
MOSFETs.
The conventional way of avoiding
audio-frequency interference is the
forced current mode, where both high
current MOSFETs continue to oper-
ate at full frequency and normal duty
V
PLL LPF
(V)
0.7f
0
f
0
1.3f
0
FREQUENCY
2.5
DI1436_05.eps
0 2.01.51.00.5
C
OSC
= 47pF
C
OSC
= 100pF
–
+
DI1436_06.eps
+V
CC
DISCH
THRESH
CONT
GND
TRIG
OUT
RESET
1
2
3
4
0.1µF
TLC555
LTC1436-PLL
PIN 17
(5V)
LTC1436-PLL
PIN 6
(GND)
1.5V
0.9V ~10ms
1.2M
220Ω
0.1µF
2N3904
100k
150k
510k
LT1077
LTC1436-PLL
PIN 1
(MOD)
8
7
6
5
0V
OUTPUT CURRENT
50
100
90
80
70
60
EFFICIENCY (%)
10A1mA 10mA 1A100mA
(3)
(2)
(1)
10V IN
5V OUT
1. CYCLE SKIPPING OPERATION:
VARIABLE FREQUENCY
COMPONENTS AT LOWER
OUTPUT CURRENTS
2. Adaptive Power MODE:
CONSTANT FREQUENCY WITH
AUTOMATIC SWITCHOVER TO
SMALL MOSFET Q3
3. FORCED CONTINUOUS OPERATION:
CONSTANT FREQUENCY USING
LARGE MOSFETS Q1 AND Q2
cycle under all load conditions. This
causes the peak-to-peak inductor
current to flow, even under no load
conditions. The synchronous buck
topology allows the top switch, Q1, to
put current into the output capacitor,
followed by the bottom switch, Q2,
taking current out of the output ca-
pacitor while regulating the output
voltage under no-load conditions.
Although constant frequency is main-
tained, high current I
2
R losses and
high gate charge losses continue
under light load conditions. LTC1436-
PLL features forced-current operation
to provide the fast transient response
required for high di/dt loads like the
Intel Pentium
®
processor.
Cycle skipping, Adaptive Power and
forced current operation are all avail-
able on the LTC1436-PLL, so that the
best operating mode can be selected
for each application.
Conclusion
The family of LTC1436-PLL parts of-
fers very effective EMI suppression
features. Reviewing the spectrum
analyzer plots in Figures 2, 3 and 4
shows that the output voltage noise
amplitude can be significantly re-
duced at frequencies to 30MHz with
switch-frequency modulation. The
Adaptive Power mode provides high
efficiency, constant-frequency opera-
tion at very low output currents and
avoids audio frequency operation.
Figure 5. Operating frequency vs V
PLLPF
Figure 6. Switch-frequency modulator
Figure 7. Audio frequencies in output noise
during cycle-skipping operation
Figure 8. Output noise with Adaptive Power
mode operation
Figure 9. Efficiency curves for light load currents
Pentium is a registered trademark of Intel Corp.
10Hz 10kHz
–20dBm
DI1436_08.eps
–120dBm
–100dBm
–80dBm
–60dBm
–40dBm
20kHz
10V
IN
5V
OUT
AT 3mA
BW = 100Hz
10Hz 10kHz
–20dBm
–40dBm
–60dBm
–80dBm
–100dBm
DI1436_07.eps
–120dBm 20kHz
10V
IN
5V
OUT
AT 3mA
BW = 100Hz
Linear Technology Magazine • February 1997
26
DESIGN IDEAS
Dual-Output Voltage Regulator
by Peter Guan
DI1263_01.eps
TDRIVE
PWR V
IN
PINV
BINH
*COILTRONICS CTX0212801
LTC1266-3.3
1000pF
V
IN
C
T
I
TH
SENSE–
BDRIVE
PGND
LB
OUT
LB
IN
SGND
SHDN
NC
SENSE+
1
2
3
4
5
6
7
8
C
T
180pF
C
C
3300pF
1µF
C2 = 0.47µF
C3 = 10µF
C4 = 10µF
C1 = 0.47µF
R
SENSE
0.02Ω
R
C
470Ω
V
OUT
= 3.3V/5A
V
OUT
= 12V/60mA
V
CC
16 Si9410DY D1
MBRS140T3
C
IN
100µF
20V
× 2
C
OUT
220µF
10V
× 2
L*
5µH
Si9410DY
15
14
13
12
11
10
9
C1–
C1+
C2–
C2+
LTC1263
V
CC
5V
FROM µP
GND
V
OUT
V
CC
1
2
3
4
8
7
6
5
SHDN
The LTC1266-3.3 and LTC1263 are
perfect complements for one another.
The combination of these two parts
provides two regulated outputs of
3.3V/5A and 12V/60mA from an in-
put range of 4.75V to 5.5V. These two
outputs are perfect for notebook and
palmtop computers with micropro-
cessors that burn several amps of
current from a regulated 3.3V sup-
ply, flash memories that consume
milliamps of current from a regulated
12V supply and interface and logic
components that still run off the 5V
supply. In fact, this quick and easy
combination may well be the aspirin
for many of the headaches caused by
the rigorous power supply demands
in today’s electronics.
The LTC1263, using only four ex-
ternal components (two 0.47µF charge
capacitors, one 10µF bypass capaci-
tor and a 10µF output capacitor),
generates the regulated 12V/60mA
output from a 5V input using a charge
pump tripler. During every period of
the 300kHz oscillator, the two charge
capacitors are first charged to V
CC
and then stacked in series, with the
bottom plate of the bottom capacitor
shorted to V
CC
and the top plate of the
top capacitor connected to the output
capacitor. As a result, the output
capacitor is slowly charged up from
5V to 12V. The 12V output is regu-
lated by a gated oscillator scheme
that turns the charge pump on when
V
OUT
is below 12V and turns it off
when it exceeds 12V.
The LTC1266-3.3 then uses the 5V
input along with the 12V output from
the LTC1263 and various external
components, including bypass capaci-
tors, sense resistors and Schottky
diodes, to switch two external N-chan-
nel MOSFETs and a 5µH inductor to
charge and regulate the 3.3V/5A out-
put. The charging scheme for this
part, however, is very different from
that of the LTC1263. The LTC1266-
3.3 first charges the output capacitor
by turning on the top N-channel
MOSFET, allowing current to flow
from the 5V input supply and through
the inductor. By monitoring the
Figure 1. 5V to 3.3V/5A and 12V/60mA supply
continued on page 32
Linear Technology Magazine • February 1997
27
DESIGN IDEAS
+
+
+
+
+
+
+
DIDPM_01.eps
V
IN
LT1303
SHDNONOFF
10µF
25V
1.8VDC–
6VDC
10µF
25V
10µF
25V
FB
PGNDGND
SW
R2
1.2k
R1
8.2k
MBR0520L
MBR0520L
Q1
2N3906
10µF
25V
10µF
25V
10.7µH
COILTRONICS
VP1-0190
DIGITAL
PANEL
METERS
10µF
25V
5 × MBR0520L
10µF
25V
Free Digital Panel Meters from the
Oppressive Yoke of Batteries by Mitchell Lee
Digital panel meters (DPMs) have
dropped in price to well under $10 for
3-1/2 digit models, even in single-
piece quantities. These make excellent
displays for many instruments, but
suffer from one major flaw: they re-
quire a floating power supply, usually
in the form of a 9V battery. This
renders inexpensive meters useless
for most applications because no one
wants multiple 9V batteries in their
product.
The circuit shown in Figure 1 pow-
ers up to five meters from a single
1.8V to 6V source. The source need
not be floating, yet all five outputs are
fully floating, isolated and indepen-
dent in every respect. The circuit
consists of an LT1303 micropower,
high efficiency DC/DC converter driv-
ing a 5-output flyback converter. An
off-the-shelf surface mount coil,
Coiltronics’ Versa-Pac™ VP1-0190, is
used as the transformer. This device
is hipot tested to 500V
RMS
—more than
adequate for most applications.
Feedback is extracted from the
primary by Q1, which samples the
flyback pedestal during the switch off
time. Typical DPMs draw approxi-
mately 1mA supply current. The
primary is also loaded with 1mA for
optimum regulation and ripple. Pri-
mary snubbing components, a
necessity in most flyback circuits, are
obviated by the primary feedback rec-
tifier and smoothing capacitor.
Although this circuit has been set up
for 9V output (9.3V, to be exact), some
DPMs need 5V or 7V. Use a 4.3k or
6.2k r esistor in place of R1 for these
voltages. The output voltage is set by
R1 = (VOUT – 0.7)/1mA.
Do not attempt to regulate the out-
put beyond 10V or you will exceed the
maximum switch rating of the LT1303.
The LT1111 is better suited for higher
voltage applications.
Output ripple measures 200mV
P–P
and can be proportionately reduced
by increasing the output capacitance.
If more ripple is acceptable, the out-
put capacitors can be reduced in
value. A shutdown feature is avail-
able on the LT1303, useful where a
“sleep” function is included to save
power.
With each output loaded at 1mA,
the input current is 16.5mA on a 5V
supply. This figure rises to about
45mA on a 1.8V (2-cell) input. If the
system is battery operated and if the
battery voltage does not exceed 7V,
operate the circuit directly from the
battery for best efficiency. In line-
operated equipment, use a regulated
5VDC or 3.3VDC supply.
Figure 1. LT1303 flyback regulator provides fully floating and isolated 9V supplies to
five independent digital panel meters. Substitute 4.3k for R1 if 5V meters are used.
Versa-Pac is a trademark of Coiltronics, Inc.
Linear Technology Magazine • February 1997
28
DESIGN IDEAS
Battery Charger IC Can Also Serve
as Main Step-Down Converter by Arie Ravid
1
2
3
4
5
6
7
8
16
15
14
13
12
11
10
9
GND
V
CC1
V
CC2
PROG
V
C
BAT
GND
GND
GND
SW
BOOST
GND
OVP
SENSE
GND
GND
U1
LTC1510CS16
C9*
0.1µF
CR7*
1N914
CR6*
1N914
CR1
1N5819
V
IN
V
IN
V
IN
R9
100k
Q4
VN2222
CHARGE/TRICKLE
R8
16.2k
R7*R6
300Ω
R5
1k
R4
4.99k
BAT1
C5
1µF
C4
0.1µF
Q3
VN2222
C3
22µF
25V
CR3 1N5819
C2†
10µF
Q1*
MPS3906
R3
1.21K
CR5 1N5819
Q2*
Si9433
R2*
1M
R1
100k
SYSTEM
ON/OFF
SWITCH
C1
0.22µF
L1**
33µH
L2
2.2mH
L3
10mH
CR4
1N5817
SYSTEM
LOAD
C7
100µF
C6
100µFU2
LT1300CS8
C8*
0.1µF
V
IN
SW
SELECT SENSE
PGND GND
SHDN I
LIM
CR2
1N914
+
+
67
24
81
35
+
NC NC
*SEE TEXT
**COILTRONICS CTX33-2
†TOKIN OR MARCOM CERAMIC SURFACE MOUNT
Using a power adapter with the
highest feasible output voltage is at-
tractive to portable system designers
for a couple of reasons. Lower current
is required to maintain the same sys-
tem power, which translates into a
smaller cable and input connector. If
the adapter output voltage is consid-
erably higher than the battery voltage,
the adapter output voltage does not
need to be regulated or well filtered,
resulting in lower adapter cost.
A portable system with a high out-
put-voltage adapter, however, requires
that the system’s DC-to-DC converter
functions over a very wide range of
input voltage: from fully discharged
battery voltage to the highest adapter
output voltage.
This problem can be resolved by
using the LT1510 as both the battery
charger and the main step-down con-
verter, as shown in Figure 1. An
important feature of the circuit in
Figure 1 is the glitch-free transfer
from AC operation to battery opera-
tion and back.
The LT1510 battery charger IC is
capable of charge current up to 1.5A
and output (battery) voltage up to
20V. High efficiency and small induc-
tor size are achieved by a saturating
switch running at 200kHz. The
LT1510 is capable of charging lithium-
ion and sealed-lead-acid batteries in
the constant-voltage/constant-
current configuration, and nickel-
cadmium and nickel-metal-
hydride batteries in the constant-
current configuration. The LT1510
contains an internal switch and cur-
rent sense resistor. All the designer
needs to do in order to program the
current and voltage is select the cur-
rent-programming resistor and the
voltage-divider resistors.
In the circuit shown in Figure 1,
the system’s DC-to-DC converter is
connected to the SENSE pin. This
way, the internal sense resistor is
bypassed for the system load but is
active in regulating the charge cur-
rent. The sum of the charge current
and system current should not ex-
ceed the maximum output current
allowed (limited by thermal consider-
ations or peak switch current). Since
the DC-to-DC converter circuit has a
large input capacitor, it cannot be
connected directly to the SENSE pin.
This is because the internal sense
resistor between SENSE and BAT pins
will see a large capacitance across it,
which will cause instability. A 2.2mH
inductor, such as the DT1608C-222
by Coilcraft (L2), is used to isolate the
input capacitance of the DC-to-DC
converter. CR5 limits the transient
current through the LT1510’s inter-
nal sense resistor when the system is
operating on battery and turned on.
Q2 (Si9433) is required if the series
resistance of 0.2 between the BA T
pin and SENSE pin is too high. The
Si9433’s on resistance is 0.075 . The
Figure 1. LT1510 battery charger/main step-down converter provides glitch-free transfer between AC and battery operation.
continued on page 36
Linear Technology Magazine • February 1997
29
DESIGN IDEAS
Combine a Switching Regulator
and an UltraFast Linear Regulator
for a High Performance 3.3V Supply
by Craig Varga
Introduction
It is becoming increasingly necessary
to provide low voltage power to micro-
processor loads at very high current
levels. Many processors also exhibit
high speed load transients. The Pen-
tium
®
Pro processor from Intel exhibits
both of these requirements. This
processor requires 3.3V ±5% at
approximately 14A peak (9A average)
and is capable of making the transi-
tion from a low power state to full load
in several clock cycles. Generally,
switching regulators are used to sup-
ply such high power devices, because
of the unacceptable power losses
associated with linear regulators.
Unfortunately, switching regulators
exhibit much slower transient re-
sponse than linear regulators. This
greatly increases the output capaci-
tor requirements for switchers.
Circuit Operation
The circuit shown in Figure 1 takes
advantage of a new, ultrahigh speed
linear regulator combined with a
switching regulator to get the best of
both worlds. An LTC1435 synchro-
nous buck regulator is combined with
an LT1575 linear regulator to gener-
ate a 3.3V output from a 12V input
with an overall conversion efficiency
of approximately 72%. The output is
capable of current slew rates of
approximately 20A per microsecond.
+
+ + +
DI1575_01.eps
TG
SW
BOOST
INTV
CC
BG
S
+
S
–
EXTV
CC
C
OSC
RUN/SS
I
TH
SFB
SGND
V
OS
9
1
2
3
4
5
6
16
14
15
12
11
8
7
13
10 C4, 4.7µFC5
0.1µF
D2
MBRS330T3
R8
15K
R3
100 R4
100
C18
1000µF
10V
C20
1000µF
10V
C19
1000µF
10V
R6
7.5mΩ
L1
4µH
C2, 1000pF
V
IN
U2
LTC1435
IPOS
INEG
GATE
COMP
S/D
V
IN
GND
FB
C21, 10pF
C22
1000pF
R2
1.21k
1%
C1, 470pF
R9
2k
Q1
IRLZ44
R1
2.1k, 1% VCORE
3.3V
1
2
3
4
8
7
6
5
U1
LT1575
PGND
D1, CMDSH-3 Q3
Q2
C16
1µF
C14, 150µF, 16V
C15
1µF
C17
1µF
12V
C11
150µF
16V
C12
150µF
16V
C13
150µF
16V
C3, 0.1µF
C9
1500pF
R5
16.5k
C10, 1000pF
C8, 68pF
C7, 0.1µF
R7
35.7k
+
C23
1µF
C6
0.1µF
12V
40 × 1µF
X7R
CERAMIC
0805 CASE
+
+
L1=COILTRONICS CTX01-13199-X2
Q2, Q3 =SILICONIX SUD50N03-10
Figure 1. 12V to 3.3V/9A (14A peak) hybrid regulator
continued on page 36
Pentium is a registered trademark of Intel Corp.
Linear Technology Magazine • February 1997
30
DESIGN IDEAS
What Efficiency Curves Don’t Tell
Introduction
In switching regulators’ data sheets,
there are always efficiency curves that
show how efficient the regulators are
in transforming one voltage to an-
other. Although these curves are
useful in comparing one regulator to
another, they don’t allow a system
designer to determine accurately how
long batteries will last before they
need to be replaced or recharged when
they are used as the power source.
This complication arises because the
type of batteries used to power the
system and the regulator load char-
acteristic strongly affect the lifetime
of the batteries.
In this article, battery lifetime
curves are obtained for the LTC1174
and the LTC1433.
A Short Introduction to the
LTC1174 and LTC1433
The LTC1174 uses a constant off-
time architecture to switch its internal
P-channel power MOSFET. The in-
put-to-output voltage ratio sets the
on time and requires the inductor
current to reach a preset limit. Even
at low load current, the LTC1174 still
requires the inductor current to reach
the preset limit before it initiates the
off-time cycle. Burst Mode operation
of the LTC1174 enhances efficiency
throughout the load-current range
by switching only the required num-
ber of cycles to bring the output into
regulation and then stopping switch-
ing (going into sleep mode). When the
output voltage has dropped slightly,
the switching sequence resumes. By
doing this, switching losses are re-
duced and are minimized when the
load current is low, because the sleep
duration is long.
The LTC1433 is a constant-fre-
quency, current mode, monolithic
switching regulator in which the in-
ductor peak current varies according
to the load current. In place of Burst
Mode operation, the LTC1433 has an
Adaptive Power output stage to en-
hance its efficiency at low load current.
Under low load conditions, the
LTC1433 uses only a fraction of its
power MOSFET, effectively reducing
switching losses without introducing
low frequency noise components.
For more information on both parts,
consult the data sheets.
The Setup
The circuits in Figures 1a, 1b and 1c
were used to obtain the lifetime data.
All outputs were set at 3.3V and the
power was supplied by either four AA
alkaline (Eveready No. EN91) or four
AA NiCd (Eveready No. CH15) cells or
a single 9V alkaline (Eveready No.
EN22) battery. A current-sink load
was set up to either draw a constant
400mA or provide a load-step charac-
teristic. The load stepping operated at
0.05Hz, going from 10mA to 410mA
with a duty cycle of 10%, providing an
average load current of 50mA.
In Figure 1b, the LTC1433 was set
up to optimize low load current effi-
ciency by configuring the Adaptive
Power output stage with separate in-
ductors for low and high current
operation.
Efficiency curves for each circuit
are shown in Figure 2a and 2b. Fig-
ures 3 through 8 show the battery
voltage and regulator output voltage
versus time for various battery and
load combinations.
4-Cell to 3.3V Configuration
Figures 3 and 4 were obtained with a
load current of 400mA. For Figure 3,
the input power to the regulator was
provided by four AA alkaline batter-
ies, whereas four AA NiCds were used
in Figure 4. The alkaline batteries
lasted longer than the NiCds, due to
by San-Hwa Chee
DI_EFF_01a.eps
P
WR
V
IN
PGND
SV
IN
C
OSC
POR
I
TH
V
OSENSE
V
PROG
16
15
14
13
12
11
10
9
LTC1433
D1
MBRM5819
C6
100µF
10V
V
OUT
V
IN
L1
22µH
C7
0.1µF
1
2
3
4
5
6
7
8
SSW
NC
BSW
NC
SGND
RUNSS
LB0
LB1
+
C3
33µF, 20V
C4
0.1µF
+
R1
5.1k
C5
47pF
C1
6800pF
C2
680pF
L1 = SUMIDA CD54-220
DI_EFF_01b.eps
P
WR
V
IN
PGND
SV
IN
C
OSC
POR
I
TH
V
OSENSE
V
PROG
16
15
14
13
12
11
10
9
LTC1433
MBRM520LT1
MBRM5819
C6
100µF
10V
V
OUT
V
IN
L1
L2
C7
0.1µF
1
2
3
4
5
6
7
8
SSW
NC
BSW
NC
SGND
RUNSS
LB0
LB1
+
C3
22µF, 20V
C4
0.1µF
+
R1
5.1k
C5
47pF
C1
6800pF
C2
680pF
100µH
22µH
L1 = SUMIDA CD54-101
L2 = SUMIDA CD54-220
Figure 1a. LTC1433 single-inductor configuration Figure 1b. LTC1433 dual-inductor configuration
Linear Technology Magazine • February 1997
31
DESIGN IDEAS
their higher energy capacity. From
Figure 4, it is apparent when the NiCd
gives up, from the cliff-like shape of
the output voltage.
For Figures 5 and 6, a step load
was applied to the regulators instead
of a DC load. Figure 5 and 6 are the
data obtained for alkaline and NiCd
AA cells, respectively. With the aver-
age load one-eighth of the previous
experiment, it would be expected that
the lifetime of the alkaline batteries
would be eight times longer or ap-
DI_EFF_01c.eps
SHDN
V
OUT
SW
8
1
5
LTC1174-3.3
GND
V
IN
4
6
D1
MBR0520LT1
C1
100µF
10V
C3
0.1µF
C2
22µF
50V
V
IN
V
OUT
3
2
7
I
BIN
LB
OUT
I
PGM
+
L1
68µH
+
L1 = SUMIDA CDRH74-680
INPUT VOLTAGE (V)
75
85
80
100
95
90
EFFICIENCY (%)
9
DI_EFF_02a.eps
48765
FIGURE 1A
FIGURE 1B
FIGURE 1C
INPUT VOLTAGE (V)
75
85
80
100
95
90
EFFICIENCY (%)
9
DI_EFF_02b.eps
48765
FIGURE 1A
FIGURE 1B
FIGURE 1C
TIME (HOURS)
0
1
2
3
4
5
6
BATTERY AND OUTPUT VOLTAGE (V)
2.5
DI_EFF_03.eps
0 0.5 1.0 1.5 2.0
LTC1433 WITH DUAL INDUCTORS
LTC1433 WITH SINGLE INDUCTOR
LTC1174HV
OUTPUT
VOLTAGE
BATTERY
VOLTAGE
TIME (HOURS)
0
1
2
3
4
5
6
BATTERY AND OUTPUT VOLTAGE (V)
2.5
DI_EFF_04.eps
0 0.5 1.0 1.5 2.0
LTC1433 WITH DUAL INDUCTORS
LTC1433 WITH SINGLE INDUCTOR
LTC1174HV
OUTPUT
VOLTAGE
BATTERY
VOLTAGE
proximately 18 hours, but Figure 5
shows a significantly better result.
The main reason for this improve-
ment has to do with the internal
resistance of the alkaline cell. At high
constant DC load current, heat is
dissipated by the internal resistance
of the alkaline batteries. The internal
resistance increases as the batteries
voltage decreases, and hence causes
more heat to be dissipated, thus low-
ering the lifetime.
For the NiCd battery, internal re-
sistance is low and remains relatively
constant over its life span. Therefore,
the lifetime of the NiCd batteries for
the load step case comes out to be
approximately the expected eight
times that of a constant DC load
current.
The above result indicates that if
the load is intermittent in nature, the
user can operate the device much
longer if the power is provided by
TIME (HOURS)
0
1
2
3
4
5
6
BATTERY AND OUTPUT VOLTAGE (V)
60
DI_EFF_05.eps
0 1020304050
LTC1433 WITH DUAL INDUCTORS
LTC1433 WITH SINGLE INDUCTOR
LTC1174HV
OUTPUT
VOLTAGE
BATTERY
VOLTAGE
TIME (HOURS)
0
1
2
3
4
5
6
BATTERY AND OUTPUT VOLTAGE (V)
20
DI_EFF_06.eps
02468 1214161810
LTC1433 WITH DUAL INDUCTORS
LTC1433 WITH SINGLE INDUCTOR
LTC1174HV
OUTPUT
VOLTAGE
BATTERY
VOLTAGE
Figure 1c. LTC1174 test circuit Figure 2a. Efficiency curves for Figure 1’s
circuits, I
LOAD
= 400mA Figure 2b. Efficiency curves for Figure 1’s
circuits, I
LOAD
= 10mA
Figure 3. Lifetime at I
LOAD
= 400mA—four AA alkaline batteries Figure 4. Lifetime at I
LOAD
= 400mA—four AA NiCd batteries
Figure 5. Lifetime with load step from 10mA to 410mA, 10% duty
cycle, T
PERIOD
= 20s—four AA alkaline batteries Figure 6. Lifetime with load step from 10mA to 410mA, 10% duty
cycle, T
PERIOD
= 20s—four AA NiCd batteries
Linear Technology Magazine • February 1997
32
DESIGN IDEAS
alkaline batteries. Again, the NiCd
exhibits a sudden “death” at the end
of its life, whereas the alkaline shows
a much gentler decay. The gentle
sloping of the output voltage of Figure
5 towards the end of the battery life
can be attributed to the on-resistance
of the switch when the regulator is in
dropout.
For the above load characteristic,
where the load is light most of the
time, making full use of the Adaptive
Power mode of the LTC1433 by means
of the dual inductor configuration
helps to squeeze an additional 1.5
hours of life compared to the single
inductor LTC1433 configuration.
Another important point to note is
that although the efficiency for the
LTC1174 is better than that of the
single inductor configuration of the
LTC1433 at 10mA load current, the
LTC1433 lasted 2.9 hours longer than
TIME (HOURS)
0
1
3
2
4
6
5
7
9
8
BATTERY AND OUTPUT VOLTAGE (V)
2.5
DI_EFF_07.eps
0 0.5 1.0 1.5 2.0
LTC1433 WITH DUAL INDUCTORS
LTC1433 WITH SINGLE INDUCTOR
LTC1174HV
OUTPUT
VOLTAGE
BATTERY
VOLTAGE
TIME (HOURS)
0
1
2
3
4
5
6
7
8
9
BATTERY AND OUTPUT VOLTAGE (V)
20
DI_EFF_08.eps
02468 1214161810
LTC1433 WITH DUAL INDUCTORS
LTC1433 WITH SINGLE INDUCTOR
LTC1174HV
OUTPUT
VOLTAGE
BATTERY
VOLTAGE
the LTC1174 in Figure 5. The reason
for this is that the LTC1174 inductor’s
current always ramps up to the pre-
set value of 600mA whether the load
current is at 10mA or at 410mA. This
high peak inductor current, combined
with the high internal resistance of
the alkaline AA cells, shortens the
lifetime. Figure 6 shows that the use
time is about the same for the
LTC1174 and the LTC1433 because
of the low, constant internal resis-
tance of the NiCd batteries.
9V-to-3.3V
The lifetime graphs are shown in Fig-
ures 7 and 8. Comparing the data
between the 9V and the AA alkaline
cells, the lifetime of the AA cells is
about 2.5 times longer. This is be-
cause the energy capacity of the 9V
alkaline is much smaller than that of
the AA cells. In addition, the internal
resistance of the 9V alkaline is much
higher than the AA cells, causing
more energy to be dissipated as heat.
For the load step case, the battery
lasted 13.8 times longer than a con-
stant 400mA load. The dual inductor
configuration of the LTC1433 lasted
about an hour longer than the single
inductor one.
Conclusion
Although a switching regulator can
be highly efficient, its architecture,
the type of load it is driving and its
power source can have a significant
effect on how long batteries will last.
For a load that varies from low load to
heavy load at low duty cycle, it is
worthwhile to consider powering your
system with alkaline batteries, be-
cause they last longer. For a constant
heavy load, NiCd and alkaline come
out to be about the same but NiCds,
of course, can be recharged.
Figure 7. Lifetime at I
LOAD
= 400mA—one 9V alkaline battery Figure 8. Lifetime with load step from 10mA to 410mA—one 9V
alkaline battery (10% duty cycle, T
PERIOD
= 20s)
amount of current flow in the induc-
tor with a sense resistor, the 3.3V
output is regulated by turning on and
off the top and bottom N-channel
MOSFETs to charge and discharge
the output capacitor.
If we replaced the top external N-
channel MOSFET with a P-channel,
the LTC1266-3.3 could generate the
same 3.3V/5A output without the
help of the LTC1263. But, since N-
channel MOSFETs have lower gate
capacitance and lower R
DS(ON)
, their
higher efficiency at high currents more
than compensates for the extra com-
plexity in bringing in another higher
input voltage, especially if that sec-
ond input voltage is readily available.
Since both of these devices are very
stingy on quiescent current, their
combination is also very gentle to the
main power supply, especially if that
power supply is a battery. In standby
mode, the LTC1263 and the LTC1266-
3.3 have a total quiescent current of
about 500µA. To conserve even more
current, both of these parts can be
put into shutdown mode by floating
their shutdown pins or pulling them
high. The total shutdown current is
less than 40µA. When loaded, the
LTC1263 has a 76% efficiency,
whereas the LTC1266-3.3 can squeeze
out more than 90%. Together, with a
60mA load at the 12V output and a 5A
load at the 3.3V output, the overall
efficiency is 87%.
The LTC1266-3.3 is available in the
16-pin SO package and the LTC1263
is available in the 8-pin SO package.
Together, these two parts provide an
easy and efficient solution for multiple
power supply demands.
Dual-Output, continued from page 26
Linear Technology Magazine • February 1997
33
DESIGN INFORMATION
Introducing the LT2078/LT2079
and LT2178/LT2179 Single Supply,
Micropower, Precision Amplifiers in
Surface Mount Packages by Raj Ramchandani
Introduction
Circuit designers seldom have an
opportunity to revisit a product as
successful as the LT1078/LT1079
and LT1178/LT1179 dual and quad
micropower precision op amps. In the
last decade, these amplifiers have
become true industry standards, with
outstanding DC precision and only
55µA and 21µA of supply current per
op amp, respectively. A look at the
data sheet shows that the LT1078
and LT1178 have much better offset
voltage and offset voltage drift in the
dual in-line package (DIP) than in the
small outline surface mount package
(SO) (see Table 1). Since the introduc-
tion of these parts, the demand for
surface mount packages has grown
dramatically; today, the majority of
ICs sold are in surface mount pack-
ages. The new LT2078 and LT2178
deliver the precision performance of
the LT1078 and LT1178 in SO pack-
ages without changing any of the
other characteristics that made these
parts so popular.
Package Limitations
of Precision Specs
An inherent problem with precision
ICs is that as circuit design and
process innovations improve the per-
formance, packaging issues can
become the major limitation in achiev-
ing precision specifications. Typically,
the best precision is in metal-can
packages; this is because there is
very little mechanical stress on the
die. Plastic packages exert stress on
the top and sides of the die as the
mold compound cools, causing
changes in the offset voltage. A solu-
tion that has been used for many
years is to put a jelly-like coating all
over the die before molding; this keeps
the plastic (and its stress) off the die.
This works well in the DIP package
but in the small SO package there is
not enough room for this coating.
Optimizing Performance
in Surface Mount
A new coating with much lower vis-
cosity before curing was developed so
that a thin (about 50 micron) coat
would cover the top of the die. The
coating runs to the edge of the die,
where it stops due to capillary action.
This coating is cured to a jelly-like
consistency before the plastic is
molded, keeping the stress off the top
of the die. A new dispensing system
was developed to control the quantity
of “thin coat” on each die, since it
must be controlled more accurately
than the old DIP coating. Unfortu-
nately, the sides of the die in the SO
package are still stressed by the mold-
ing compound, although several new
molding compounds have become
available in the last few years that
exert less stress on the die, making
this problem less severe.
We designed a new die in order to
take full advantage of these new sur-
face mount packaging technologies.
The circuit design and process used
for the LT2078 and LT2178 are the
same as their predecessors; only the
die has been changed, resulting in
identical AC performance. The mask
continued on page 36
retemaraP
8S8701TL )8-OScitsalp( 8SC8702TL )8-0Scitsalp( 8SCA8702TL )8-OScitsalp(
VmumixaM
SO
081 µV021µV07µV
VmumixaM
SO
tfirD5.3µC˚/V5.2µC˚/V8.1µC˚/V
S9701TL
)61-OScitsalp( C9702TL
)41-OScitsalp( CA9702TL
)41-OScitsalp(
VmumixaM
SO
003µV051µV001µV
VmumixaM
SO
tfirD0.4µC˚/V5.3µC˚/V0.3µC˚/V
retemaraP
8SA8711TL )8-OScitsalp( 8SC8712TL )8-OScitsalp( 8SCA8712TL )41-OScitsalp(
VmumixaM
SO
081 µV0 21 µV07µV
VmumixaM
SO
tfirD5.3µC˚/V5.2µC˚/V8.1µC˚/V
S9711TL
)61-OScitsalp( SC9712TL
)41-OScitsalp( SCA9712TL
)41-OScitsalp(
VmumixaM
SO
006µV051µV001µV
VmumixaM
SO
tfirD5.4µC˚/V5.3µC˚/V0.3µC˚/V
Table 1. LT1078/LT1079 and LT2078/LT2079 offset voltage performance comparison
Table 2. LT1178/LT1179 and LT2178/LT2179 offset voltage performance comparison
Linear Technology Magazine • February 1997
34
DESIGN INFORMATION
LTC1387 Single 5V RS232/RS485
Multiprotocol Transceiver by Y.K. Sim
Introduction
The LTC1387 is a new addition to
Linear Technology’s family of multi-
protocol transceivers. It is a single 5V
supply, logic-configurable, single-port
RS232 or RS485 transceiver. This
part is targeted at handheld comput-
ers or point-of-sale terminals and
features software-controlled multipro-
tocol operation with an emphasis on
flexibility and minimum pin count.
Positioning and Key Features
The LTC1387 complements the dual-
port LTC1334 by providing a single
port in a smaller 20-pin SO or SSOP
package. The LTC1387 offers a flex-
ible combination of two RS232 drivers,
two RS232 receivers, an RS485 driver,
an RS485 receiver and an onboard
charge pump to generate boosted volt-
ages for true RS232 levels from a
single 5V supply. The RS232 trans-
ceivers and RS485 transceiver are
designed to share the same port I/O
pins for both single-ended and differ-
ential signal communication modes.
The RS232 transceiver supports both
RS232 and EIA562 standards,
whereas the RS485 transceiver
supports both RS485 and RS422
standards. Both half-duplex and full-
duplex communication are supported.
A logic input selects between RS485
and RS232 modes. Three additional
control inputs allow the LTC1387 to
be reconfigured easily via software to
adapt to various communication
needs, including a one-signal line
1387_01.eps
LTC1387 CONTROLLER
DX1
VCC
120Ω
ARA
RB
DY
DZ
B
Y
Z
A
B
RS485
RS485
RS232
INTERFACE
RXEN
DXEN
MODE
RA
RB
DY
DZ/SLEW
ON
RXEN
DXEN
485/232
RS232 RS232 RS485 RS485 SHUTDOWN
TRANSMIT MODE RECEIVE MODE TRANSMIT MODE RECEIVE MODE MODE
RXEN = 0 RXEN = 1 RXEN = 0 RXEN = 1 RXEN = 0
DXEN = 1 DXEN = 0 DXEN = 1 DXEN = 0 DXEN = 0
MODE = 0 MODE = 0 MODE = 1 MODE = 1 MODE =X
1387_02.eps
LTC1387 CONTROLLER
DX1
RX
V
CC
120Ω
ARA
RB
DY
DZ
B
Y
Z
A
B
RS485
RS485
RS232
RS232
INTERFACE
RXEN
DXEN
MODE
RA
RB
DY
DZ/SLEW
ON
RXEN
DXEN
485/232
RS232 RS485 RS485 SHUTDOWN
MODE TRANSMIT MODE RECEIVE MODE MODE
RXEN = 1 RXEN = 0 RXEN =1 RXEN = 0
DXEN = 0 DXEN = 1 DXEN =0 DXEN = 0
MODE = 0 MODE = 1 MODE = 1 MODE = 0
Figure 1. Half-duplex RS232, half-duplex RS485
Figure 2. Full-duplex RS232, half-duplex RS485
Linear Technology Magazine • February 1997
35
DESIGN INFORMATION
RS232 I/O mode (see function tables
in figures). Four examples of inter-
face port connections are shown in
Figures 1–4.
A SLEW input pin, active in RS485
mode, changes the driver transition
between normal and slow slew-rate
modes. In normal RS485 slew mode,
the twisted pair cable must be termi-
nated at both ends to minimized signal
reflection. In slow-slew mode, the
maximum signal bandwidth is re-
duced, minimizing EMI and signal
reflection problems. Slow-slew-rate
systems can often use improperly ter-
minated or even unterminated cables
with acceptable results. If cable ter-
mination is required, external
termination resistors can be con-
nected through switches or relays.
The LTC1387 features micropower
shutdown mode, loopback mode for
self-test, high data rates (120kbaud
for RS232 and 5Mbaud for RS485)
and 7kV ESD protection at the driver
outputs and receiver inputs.
Conclusion
The LTC1387 is ideal for point-of-sale
terminals, computers, multiplexers,
networks or peripherals that need to
adapt on the fly to various I/O con-
figuration requirements without any
hardware adjustments. The LTC1387,
along with the rest of the LTC multi-
protocol interface line, makes
dedicated single-protocol communi-
cation ports obsolete.
1387_03.eps
RX1
LTC1387 CONTROLLER
DX1
V
CC
120Ω
120Ω
ARA
RB
DY
DZ
B
Y
Z
A
B
Y
Z
RS485
RS485
RS485
RS485
RS232
INTERFACE
RXD
RS232
RXEN
DXEN
MODE
RA
RB
DY
DZ/SLEW
ON
RXEN
DXEN
485/232
RS232 MODE RS485 MODE SHUTDOWN MODE
RXEN = 1 RXEN = 1 RXEN = 0
DXEN = 1 DXEN = 1 DXEN = 0
MODE = 0 MODE =1 MODE = X
1387_04.eps
RX1
LTC1387 CONTROLLER
RX2
DX1
120Ω
120Ω
ARA
RB
DY
DZ
B
Y
Z
A
B
Y
Z
RS485
RS485
RS485
RS485
RS232
INTERFACE
RXD
CTS
TXD
RTS
RS232
RS232
RS232
DX2/SLEW
ON
RXEN
DXEN
MODE
RA
RB
DY
DZ/SLEW
ON
RXEN
DXEN
485/232
TERMINATE
RS232 MODE RS485 MODE SHUTDOWN MODE
ON = 1 ON = 1 ON = 0
RXEN = 1 RXEN = 1 RXEN = 0
DXEN = 1 DXEN = 1 DXEN = 0
MODE = 0 MODE =1 MODE = X
Figure 3. Full-duplex RS232 (1-channel), full-duplex RS422
Figure 4. Full-duplex RS232 (2-channel), full-duplex RS485 with slew and termination control
Linear Technology Magazine • February 1997
36
design (layout) of the new ICs care-
fully placed the input transistors in
the area of the die where the package-
induced stress is most uniform.
Further, the input transistors are
“cross-coupled” to cancel out any
nonuniform stresses. The wafer level
trimming was tightened so that as-
sembled parts have less offset
variation. Postpackage trimming was
The LT1575 uses an IRLZ44 MOS-
FET as the pass transistor, allowing
the dropout voltage to be less than
550mV. Setting the switching supply’s
output to only 700mV above the out-
put of the linear regulator ensures
output regulation. The switcher is
therefore set up to deliver 4.0V at 14A
from the 12V supply. Conversion
efficiency of the switcher is around
90% (depending on load), whereas
the LT1575’s efficiency is 82.5% (see
LOAD CURRENT (A)
50
90
80
70
60
100
EFFICIENCY (%)
14
DI1575_02.eps
024681012
SWITCHER EFFICIENCY
TOTAL EFFICIENCY
Figure 2). The 12V input current is
only about 5.5A. At an average cur-
rent of 9A, the power dissipation in
the linear pass transistor is only 6.3W.
A small stamped aluminum heat sink
is adequate.
Figure 3 shows the transient re-
sponse to a 10A load step with a rise
time of approximately 50ns. The only
output capacitance is 40 1µF ceramic
capacitors. No additional bulk ca-
pacitance is required at the
processor. The circuit eliminates ap-
proximately a dozen low ESR tantalum
capacitors at the load, which would
be required without the linear post-
regulator. The switching supply’s
output is decoupled with three alu-
minum electrolytic capacitors.
Because the transient response at
this point is much less critical than at
the load, the long-term degradation
of the aluminum capacitors will not
be as detrimental to the circuit’s per-
formance as it would be if they were
used for load decoupling.
Conclusion
By combining a high efficiency switch-
ing regulator and an UltraFast™ linear
regulator, it is possible to achieve
reasonable efficiencies with superior
transient dynamics. Power dissipa-
tion can be held down to easily
manageable levels while eliminating
the need for very large amounts of
bulk decoupling capacitance.
Figure 2. Efficiency of Figure 1’s circuit Figure 3. Transient response of Figure 1’s
circuit to a 10A load step
optimized for the new SO packages.
(Postpackage trimming is done by
taking an input pin above the supply
pin to forward bias a diode and “zap”
a trim Zener.)
The result is that the LT2078/
LT2079 and LT2178/LT2179 are the
best single supply, precision op amps
available in the standard-pinout
surface mount packages. Table 1 com-
pares the dual LT2078 and quad
LT2079 to their predecessors, the
LT1078/LT1079, whereas Table 2
compares the LT2178/LT2179 to the
LT1178/LT1179 in surface mount
packages. These new parts are avail-
able in the SO-8 and SO-14 packages
for operation over commercial,
industrial and extended temperature
ranges.
3.3V Supply, continued from page 29
LT2078/LT2079, continued from page 33
charge pump comprising C8, C9, CR6,
CR7 and R2 biases the gate of Q2. Q1
and R1 turn Q2 off on AC operation
(V
IN
active). R7 programs the trickle-
charge current (maximum value is
about 100k) and the equivalent value
of R7 and R8 programs the charge
current. The Charge input must be
pulled low at the end of the charge.
The charger in Figure 1 is con-
nected to a 2-cell NiCd battery, BAT1.
The system switching regulator is
LT1300 (U2) based and powers a 5V/
250mA load. The efficiency, h, of the
complete system is defined as:
LT1300 Output Power + Battery Charger Power
LT1510 Input Power
h =
The efficiency plot is shown in
Figure 2. For the purpose of measure-
ment, the battery voltage is 3.2V and
the charge current is 0.3A.
INPUT VOLTAGE (V)
67.5
68.0
68.5
69.0
69.5
70.0
70.5
71.0
71.5
72.0
72.5
EFFICIENCY (%)
28
DI1510_02.eps
82313 18
Figure 2. System efficiency vs input voltage
Battery Charger, continued from page 28
CONTINUATIONS
200µs/DIV
50mV/DIV
Linear Technology Magazine • February 1997
37
NEW DEVICE CAMEOS
New Device Cameos
LT1118 Adjustable
Sink/Source Regulator
The LT1118 adjustable regulator joins
the LT1118-2.5, LT1118-2.85 and
LT1118-5 fixed-output versions of the
sink/source regulator. The output
voltage is programmed by customer
selected feedback resistors to provide
any output voltage between 2.0V and
V
IN
– 1.0V, for V
IN
up to 15V. The
regulator maintains regulation for
load currents between 800mA sourced
into the load to 400mA sunk from the
load.
The adjustable regulator is espe-
cially useful for data bus terminations,
similar to the use of the 2.85V fixed
version in SCSI applications.
A fused-lead SO-8 package pro-
vides a low thermal resistance to PC
board traces. In most applications,
no further heat sinking is required for
the regulator.
A Shutdown pin places the output
in a high impedance state, effectively
disconnecting the load from the regu-
lator. Fault tolerance is provided by
current limiting of both sunk and
sourced output current in addition to
on-chip thermal shutdown.
LT1141A 3-Driver,
5-Receiver RS232 Transceiver
Meets IEC-1000-4-2 ESD
Protection Standards
The LT1141A 3-driver, 5-receiver
RS232 transceiver is the latest Linear
Technology RS232 transceiver to be
upgraded to pass the IEC-1000-4-2
level 4 ESD test. The chip is internally
protected against ±15kV air-gap or
±8kV contact-mode discharges. The
IEC-1000-4-2 test, formerly known
as IEC-801-2, must be passed by all
equipment sold in Europe. The chip
also passes up to ±15kV ESD as tested
by MIL-STD-883, Method 3015. The
on-chip protection of the LT1141A
frees the user from the cost and board
area required by external transient-
suppression devices that are usually
required to successfully meet the IEC
ESD protection requirements.
The enhanced ESD protection has
been achieved without compromising
the electrical performance of the de-
vice. Present LT1141A users will see
no change in electrical performance.
The 3-driver, 5-receiver device retains
all of the electrical performance fea-
tures which make it popular. The
enhanced ESD protection devices do
not degrade operation at rates of up to
120kbaud with full 2500pF loads or
to 250kbaud with 1000pF loads.
The LT1141A is available in 24-pin
DIP, SO and SSOP packages.
LT1180A/LT1181A
2-Driver, 2-Receiver
RS232 Transceivers
Meet IEC-1000-4-2
ESD Protection Standards
The LT1180A and LT1181A, Linear
Technology’s popular 2-driver, 2-re-
ceiver RS232 transceivers, have been
upgraded to meet the IEC-1000-4-2
level 4 ESD standards. The circuits
are internally protected against ±15kV
air-gap or ±8kV contact-mode dis-
charges. The IEC-1000-4-2 test,
formerly known as IEC-801-2, must
be passed by all equipment sold in
Europe. The chip also passes up to
±15kV ESD as tested by MIL-STD-
883 Method 3015. The on-chip
protection of the LT1181A frees the
user from the cost and board area
required by external transient-sup-
pression devices that are usually
required to successfully meet the IEC
ESD protection requirements.
Enhanced ESD protection has been
achieved without compromising the
electrical performance of the devices.
Present LT1180A/LT1181A users will
see no change in electrical perfor-
mance. The devices retain all of the
electrical performance features that
make them popular. The enhanced
ESD protection devices do not de-
grade operation at rates of up to
120kbaud with full 2500pF loads or
to 250kbaud with 1000pF loads.
The LT1181A is available in 16-pin
DIP, SW and SO packages. The
LT1180A, which includes a shutdown
control, is available in 18-pin DIP and
SW packages.
LTC1438-ADJ:
High Efficiency, Dual,
Adjustable Output Voltage
Synchronous Switching
Power Supply Controller for
Portable Applications
The LTC1438-ADJ is a dual, adjust-
able output voltage, synchronous
step-down switching regulator con-
troller that drives external N-channel
power MOSFETs in a fixed frequency
architecture.
The LTC1438-ADJ differs from the
LTC1438 in its ability to set both
controller output voltages using ex-
ternal resistive dividers, for output
voltages as low as 1.2V. External-
feedback voltage setting provides
remote sensing of each output volt-
age at the load—often required in
higher current applications.
A 1% voltage reference and load
regulation of ±0.8% are guaranteed
over the full temperature range, elimi-
nating output voltage adjustment in
most applications. The operating cur-
rent levels are user-programmable
via external current sense resistors.
Wide input supply range allows op-
eration from 3.5V to 30V (36V
maximum).
A secondary feedback input can be
used in conjunction with a flyback
winding on the first controller to gen-
erate a third output voltage that can
supply power regardless of the load
Linear Technology Magazine • February 1997
38
NEW DEVICE CAMEOS
on the first controller’s primary wind-
ing. This feedback forces continuous
operation on the first controller using
a simple voltage mode loop. The input
can also be used as a logic input to
force continuous operation, thereby
suppressing Burst Mode operation
on the first controller.
A hysteretic comparator, which has
its inverting input tied to the internal
1.19V reference, is included. The out-
put is an open-drain type and can be
pulled up to any available supply of
up to 10V. A power-on reset timer
(POR) generates a logic-low output
signal during controller start-up,
which persists for 65,536 clock cycles
after the output reaches 7.5% of the
regulated output voltage.
The part is available in a 28-lead
plastic SSOP package.
LTC1605 Single 5V 100ksps
Sampling 16-Bit ADC
The LTC1605 is a complete 100ksps
sampling 16-bit ADC that operates
on a single 5V supply and typically
dissipates 55mW. Its input range is
an industrial standard ±10V. This
gives the user a large input LSB size
of 305µV, which can help ease noise
requirements for the input condition-
ing circuitry. The input signal is
captured by an onboard sample-and-
hold and digitized by a differential,
switched capacitor SAR ADC. The
LTC1605 achieves 16-bit performance
without the autocalibration overhead
required with other types of ADCs.
Maximum DC specifications include
±2.0LSB INL and 16 bits with no
missing codes guaranteed over tem-
perature. The part has an internal
2.5V bandgap reference. An external
reference can also be used.
The ADC has a microprocessor-
compatible 16-bit parallel output port
that can provide data as a 16-bit word
or as two bytes. The LTC1605 is easily
connected to FIFOs, DSPs and micro-
processors using its convert start
input and data ready signal (BUSY).
LT1039A RS232 Transceiver
Meets IEC-1000-4-2 ESD
Protection Standards
The popular LT1039 3-driver 3-
receiver RS232 transceiver has been
upgraded to pass the IEC-1000-4-2
level 4 ESD test. The chip is internally
For further infor mation on any
of the devices mentioned in this
issue of Linear Technology, use
the reader service car d or call
the LTC literatur e service
number:
1-800-4-LINEAR
Ask for the pertinent data sheets
and Application Notes.
protected against ±15kV air-gap or
±8kV contact-mode discharges. The
IEC-1000-4-2 test, formerly known
as IEC-801-2, must be passed by all
equipment sold in Europe. LT1039A’s
on-chip protection eliminates the cost
and board area required by external
transient-suppression devices, which
are usually needed to successfully
meet the IEC ESD protection
requirements.
The enhanced ESD protection is
achieved without compromising the
electrical performance of the device.
Present LT1039 users will see no
change in electrical performance. The
3-driver, 3-receiver device retains all
of the electrical performance features
that make it popular. Operation to
120kbaud with full 2500pF loads,
and up to 250kbaud with 1000pF
loads, is not degraded by the en-
hanced ESD protection devices.
The LT1039A is available in 16-pin
and 18-pin DIP and SO packages.
The 18-pin versions include ON-OFF
control and a BIAS pin to power one
receiver when the device is shut
down.
for
the latest information
on LTC products,
visit
www.linear-tech.com
Linear Technology Magazine • February 1997
39
Applications on Disk
Noise Disk — This IBM-PC (or compatible) program
allows the user to calculate circuit noise using LTC op
amps, determine the best LTC op amp for a low noise
application, display the noise data for LTC op amps,
calculate resistor noise and calculate noise using specs
for any op amp. Available at no charge.
SPICE Macromodel Disk — This IBM-PC (or compat-
ible) high density diskette contains the library of LTC
op amp SPICE macromodels. The models can be used
with any version of SPICE for general analog circuit
simulations. The diskette also contains working circuit
examples using the models and a demonstration copy
of PSPICE™ by MicroSim. Available at no charge.
SwitcherCAD™ — The SwitcherCAD program is a pow-
erful PC software tool that aids in the design and
optimization of switching regulators. The program can
cut days off the design cycle by selecting topologies,
calculating operating points and specifying compo-
nent values and manufacturer’s part numbers. 144
page manual included. $20.00
SwitcherCAD supports the following parts: LT1070
series: LT1070, LT1071, LT1072, LT1074 and LT1076.
LT1082. LT1170 series: LT1170, LT1171, LT1172 and
LT1176. It also supports: LT1268, LT1269 and LT1507.
LT1270 series: LT1270 and LT1271. LT1371 series:
LT1371, LT1372, LT1373, LT1375, LT1376 and
LT1377.
Micropower SwitcherCAD™ — The MicropowerSCAD
program is a powerful tool for designing DC/DC con-
verters based on Linear Technology’s micropower
switching regulator ICs. Given basic design param-
eters, MicropowerSCAD selects a circuit topology and
offers you a selection of appropriate Linear Technology
switching regulator ICs. MicropowerSCAD also per-
forms circuit simulations to select the other components
which surround the DC/DC converter. In the case of a
battery supply, MicropowerSCAD can perform a bat-
tery life simulation. 44 page manual included. $20.00
MicropowerSCAD supports the following LTC micro-
power DC/DC converters: LT1073, LT1107, LT1108,
LT1109, LT1109A, LT1110, LT1111, LT1173, LTC1174,
LT1300, LT1301 and LT1303.
Technical Books
1990 Linear Databook, Vol I —This 1440 page collec-
tion of data sheets covers op amps, voltage regulators,
references, comparators, filters, PWMs, data conver-
sion and interface products (bipolar and CMOS), in
both commercial and military grades. The catalog
features well over 300 devices. $10.00
1992 Linear Databook, Vol II — This 1248 page supple-
ment to the 1990 Linear Databook is a collection of all
products introduced in 1991 and 1992. The catalog
contains full data sheets for over 140 devices. The
1992 Linear Databook, Vol II is a companion to the
1990 Linear Databook, which should not be discarded.
$10.00
1994 Linear Databook, Vol III —This 1826 page
supplement to the 1990 and 1992 Linear Databooks is
a collection of all products introduced since 1992. A
total of 152 product data sheets are included with
updated selection guides. The 1994 Linear Databook
Vol III is a companion to the 1990 and 1992 Linear
Databooks, which should not be discarded. $10.00
1995 Linear Databook, Vol IV —This 1152 page
supplement to the 1990, 1992 and 1994 Linear Da-
tabooks is a collection of all products introduced since
1994. A total of 80 product data sheets are included
with updated selection guides. The 1995 Linear Data-
book Vol IV is a companion to the 1990, 1992 and 1994
Linear Databooks, which should not be discarded.
$10.00
1996 Linear Databook, Vol V —This 1152 page supple-
ment to the 1990, 1992, 1994 and 1995 Linear
Databooks is a collection of all products introduced
since 1995. A total of 65 product data sheets are
included with updated selection guides. The 1996
Linear Databook Vol V is a companion to the 1990,
1992, 1994 and 1995 Linear Databooks, which should
not be discarded. $10.00
1990 Linear Applications Handbook, Volume I —
928 pages full of application ideas covered in depth by
40 Application Notes and 33 Design Notes. This cata-
log covers a broad range of “real world” linear circuitry.
In addition to detailed, systems-oriented circuits, this
handbook contains broad tutorial content together
with liberal use of schematics and scope photography.
A special feature in this edition includes a 22-page
section on SPICE macromodels. $20.00
1993 Linear Applications Handbook, Volume II —
Continues the stream of “real world” linear circuitry
initiated by the 1990 Handbook. Similar in scope to the
1990 edition, the new book covers Application Notes
40 through 54 and Design Notes 33 through 69.
References and articles from non-LTC publications
that we have found useful are also included. $20.00
1997 Linear Applications Handbook, Volume III —
This 976 page handbook maintains the practical outlook
and tutorial nature of previous efforts, while broaden-
ing topic selection. This new book includes Application
Notes 55 through 69 and Design Notes 70 through
144. Subjects include switching regulators, measure-
ment and control circuits, filters, video designs,
interface, data converters, power products, battery
chargers and CCFL inverters. An extensive subject
index references circuits in LTC data sheets, design
notes, application notes and
Linear Technology
maga-
zines. $20.00
Interface Product Handbook — This 424 page hand-
book features LTC’s complete line of line driver and
receiver products for RS232, RS485, RS423, RS422,
V.35 and AppleTalk
®
applications. Linear’s particular
expertise in this area involves low power consumption,
high numbers of drivers and receivers in one package,
mixed RS232 and RS485 devices, 10kV ESD protec-
tion of RS232 devices and surface mount packages.
Available at no charge
Power Solutions Brochure — This 84 page collection
of circuits contains real-life solutions for common
power supply design problems. There are over 88
circuits, including descriptions, graphs and perfor-
mance specifications. Topics covered include battery
chargers, PCMCIA power management, microproces-
sor power supplies, portable equipment power supplies,
micropower DC/DC, step-up and step-down switching
regulators, off-line switching regulators, linear regula-
tors and switched capacitor conversion.
Available at no charge.
High Speed Amplifier Solutions Brochure —
This 72 page collection of circuits contains real-life
solutions for problems that require high speed
amplifiers. There are 82 circuits including descrip-
tions, graphs and performance specifications. Topics
covered include basic amplifiers, video-related appli-
cations circuits, instrumentation, DAC and photodiode
amplifiers, filters, variable gain, oscillators and current
sources and other unusual application circuits.
Available at no charge
Data Conversion Solutions Brochure — This 52 page
collection of data conversion circuits, products and
selection guides serves as excellent reference for the
data acquisition system designer. Over 60 products
are showcased, solving problems in low power, small
size and high performance data conversion applica-
tions—with performance graphs and specifications.
Topics covered include ADCs, DACs, voltage refer-
ences and analog multiplexers. A complete glossary
defines data conversion specifications; a list of se-
lected application and design notes is also included.
Available at no charge
Telecommunications Solutions Brochure — This 72
page collection of circuits, new products and selection
guides covers a wide variety of products targeted for
the telecommunications industry. Circuits solving real
life problems are shown for central office switching,
cellular phone, base station and other telecom applica-
tions. New products introduced include high speed
amplifiers, A/D converters, power products, interface
transceivers and filters. Reference material includes a
telecommunications glossary, serial interface stan-
dards, protocol information and a complete list of key
application notes and design notes.
Available at no charge
continued on page 40
DESIGN TOOLS
DESIGN TOOLS
Acrobat is a trademark of Adobe Systems, Inc. AppleTalk
is a registered trademark of Apple Computer, Inc. PSPICE™
is a trademark of MicroSim Corp.
Information furnished by Linear Technology Corporation
is believed to be accurate and reliable. However, Linear
Technology makes no representation that the circuits
described herein will not infringe on existing patent rights.
Linear Technology Magazine • February 1997
© 1997 Linear Technology Corporation/Printed in U.S.A/
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Handbook collection (Volumes I and II). Our extensive
collection of Design Notes and the complete collection
of
Linear Technology
magazine are also included.
A powerful search engine built into the LinearView CD-
ROM enables you to select parts by various criteria,
such as device parameters, keywords or part numbers.
All product categories are represented: data conver-
sion, references, amplifiers, power products, filters
and interface circuits. Up-to-date versions of Linear
Technology’s software design tools, SwitcherCAD,
FilterCAD, Noise Disk and Spice Macromodel library,
are also included. Everything you need to know about
Linear Technology’s products and applications is readily
accessible via LinearView. Available at no charge.
World Wide Web Site
Linear Technology Corporation’s customers can now
quickly and conveniently find and retrieve the latest
technical information covering the Company’s prod-
ucts on LTC’s new internet web site. Located at
www.linear-tech.com, this site allows anyone with
internet access and a web browser to search through
all of LTC’s technical publications, including data sheets,
application notes, design notes,
Linear Technology
magazine issues and other LTC publications, to find
information on LTC parts and applications circuits.
Other areas within the site include help, news and
information about Linear Technology and its sales
offices. The site includes a map that eases navigation
through the different information areas.
Other web sites usually require the visitor to download
large document files to see if they contain the desired
information. This is cumbersome and inconvenient. To
save you time and ensure that you receive the correct
information the first time, the first page of each data
sheet, application note and
Linear Technology
maga-
zine is recreated in a fast, download-friendly format.
This allows you to determine whether the document is
what you need, before downloading the entire file.
The site is searchable. Among the possible search
criteria are part numbers, function, topics and applica-
tions. The search is performed on a user-defined
combination of data sheets, application notes, design
notes and
Linear Technology
magazine articles. Any
data sheet, application note, design note or magazine
article can be downloaded or faxed back. (Files are
downloaded in Adobe Acrobat™ PDF format; you will
need a copy of Acrobat Reader to view or print them.
The site includes a link from which you can download
this program.)
DESIGN TOOLS, continued from page 39
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