V08N1 - FEBRUARY

LINEAR TECHNOLOGY
FEBRUARY 1998
IN THIS ISSUE…
COVER ARTICLE
Universal Continuous-Time Filter
Challenges Discrete Designs .......... 1
Max Hauser
Issue Highlights ............................ 2
LTC® in the News ........................... 2
DESIGN FEATURES
An SMBus-Controlled 10-Bit, Current
Output, 50µ A, Full-Scale DAC ........ 6
Ricky Chow
Micropower 600kHz Fixed-Frequency
DC/DC Converters Step Up from a
1-Cell or 2-Cell Battery .................. 8
Steve Pietkiewicz
New 333ksps, 16-Bit ADC Offers 90dB
SINAD and –100dB THD .............. 11
Marco Pan
Ultralow Power 14-Bit ADC Samples
at 200ksps .................................. 14
Dave Thomas
A 10MB/s Multiple-Protocol Chip Set
Supports Net1 and Net2 Standards
................................................... 17
David Soo
DESIGN IDEAS
High Clock-to-Center Frequency Ratio
LTC1068-200 Extends Capabilities of
Switched Capacitor Highpass Filter
................................................... 23
Frank Cox
LT1533 Ultralow Noise Switching
Regulator for High Voltage or
High Current Applications .......... 24
Jim Williams
A Complete Battery Backup Solution
Using a Rechargeable NiCd Cell .. 26
L.Y. Lin and S.H. Lim
Zero-Bias Detector Yields High
Sensitivity with Nanopower
Consumption ............................... 28
Mitchell Lee
DESIGN INFORMATION
Micropower Octal 10-Bit DAC
Conserves Board Space with SO-8
Footprint ..................................... 29
Kevin R. Hoskins
Tiny MSOP Dual Switch Driver is
SMBus Controlled ........................ 31
Peter Guan
New Device Cameos ..................... 34
Design Tools ................................ 35
Sales Offices ............................... 36
VOLUME VIII NUMBER 1
Universal Continuous-Time
Filter Challenges
Discrete Designs by Max Hauser
The LTC1562 is the first in a new
family of tunable, DC-accurate, continuous-time filter products featuring
very low noise and distortion. It contains four independent 2nd order,
3-terminal filter blocks that are resistor programmable for lowpass or
bandpass filtering functions up to
150kHz, and has a complete PC board
footprint smaller than a dime. Moreover, the part can deliver arbitrary
continuous-time pole-zero responses,
including highpass, notch and elliptic, if one or more programming
resistors are replaced with capacitors. The center frequency (f0) of the
LTC1562 is internally trimmed, with
an absolute accuracy of 0.5%, and
can be adjusted independently in each
2nd order section from 10kHz to
150kHz by an external resistor. Other
features include:
❏ Rail-to-rail inputs and outputs
❏ Wideband signal-to-noise ratio
(SNR) of 103dB
❏ Total harmonic distortion (THD)
of –96dB at 20kHz, –80dB at
100kHz
❏ Built-in multiple-input summing
and gain features; capable of
118dB dynamic range
❏ Single- or dual-supply operation,
4.75V to 10.5V total
❏ “Zero-power” shutdown mode
under logic control
❏ No clocks, PLLs, DSP or tuning
cycles required
The LTC1562, in the SSOP package,
provides eight poles of programmable
continuous-time filtering in a total
surface mount board area (including
the programming resistors) of 0.24
square inches (155 mm2 )—smaller
than a U.S. 10-cent coin. This filter
can also replace op amp–R-C active
filter circuits and LC filters in applications requiring compactness,
flexibility, high dynamic range or fewer
precision components.
What’s Inside?
As shown in Figure 1, the LTC1562
includes four identical 3-terminal
blocks. Each contains active circuitry,
precision capacitors and precision
resistors, forming a flexible 2nd order
filter core. These blocks are designed
to make filters as easy to configure as
op amps. The 3-terminal arrangement minimizes the number of
external parts necessary for a complete 2nd order filter with arbitrarily
programmable f0, Q and gain. Figure
2 shows the contents of one block,
along with three external resistors,
forming a complete lowpass/bandpass filter (the most basic application
of the LTC1562). In Figure 2, a lowpass response appears between the
VIN source and the LP output pin, and
simultaneously a bandpass response
is available at the BP output pin. Both
outputs have rail-to-rail capability
for the maximum possible signal
swing, and hence, maximum signalto-noise ratio (SNR).
continued on page 3
, LTC and LT are registered trademarks of Linear Technology Corporation. Adaptive Power, Burst Mode, C-Load,
FilterCAD, Linear View, Micropower SwitcherCAD, Operational Filter and SwitcherCAD are trademarks of Linear
Technology Corporation. Other product names may be trademarks of the companies that manufacture the products.
EDITOR’S PAGE
Issue Highlights
LTC in the News…
LTC Reports
Another Strong Quarter
Our cover article for this issue introduces a new filter product, the
LTC1562. The LTC1562 is the first in
a new family of tunable, DC-accurate,
continuous-time filter products featuring very low noise and distortion. It
contains four independent 2nd order,
3-terminal filter blocks that are resistor programmable for lowpass or
bandpass filtering functions up to
150kHz, and has a complete PC board
footprint smaller than a dime.
Data converters are strongly represented in this issue, with a new DAC
and several new ADCs:
The LTC1427-50 is a 10-bit, current-source-output DAC with an
SMBus interface. This device provides
precision, full-scale current of 50µA
±1.5% at room temperature (±3% over
temperature), wide output voltage DC
compliance (from –15V to [VCC – 1.3V])
and guaranteed monotonicity over a
wide supply-voltage range. It is an
ideal part for applications in contrast/brightness control or voltage
adjustment in feedback loops.
We also introduce the LTC1604, a
fast, high performance 16-bit sampling ADC in a tiny 36-pin SSOP
package. This device runs at 333ksps
and delivers excellent DC and AC
performance. It operates on ±5V supplies and typically draws only 220mW.
It is a complete differential, high speed,
low power, 16-bit sampling ADC that
requires no external components. The
LTC1604 also provides two powershutdown modes, NAP and SLEEP, to
reduce power consumption during
inactive periods. It not only offers the
performance of the best hybrids but
also provides low power, small size,
an easy-to-use interface and the low
cost of a monolithic part.
A new, versatile 14-bit ADC, the
LTC1418, can digitize at 200ksps
while consuming only 15mW from a
single 5V supply. The LTC1418 is
designed to be easy to use and adaptable, requiring little or no support
circuitry in a wide variety of applica2
tions. It features 0.25LSB INL max
and 1LSB DNL max, parallel and serial data output modes and NAP and
SLEEP power-shutdown modes.
In the power conversion arena, we
debut two new micropower DC/DC
converters designed to provide power
from a single-cell or higher input voltage, the LT1308 and the LT1317. The
LT1308 is intended for generating
power on the order of 2W–5W, for RF
power amplifiers in GSM or DECT
terminals or for digital-camera power
supplies. The LT1317, intended for
lower power requirements, operates
from an input voltage as low as 1.5V.
It can generate 100mW to 2W of power.
Both devices feature Burst Mode™
operation for high efficiency at light
loads. Both devices switch at 600kHz;
this high frequency keeps associated
power components small and flat.
On the interface front, we present
a new multiprotocol chip set that is
guaranteed to be Net1 and Net2 compliant. The LTC1543/LTC1544/
LTC1344A chip set creates a complete software-selectable serial
interface using an inexpensive DB25 connector. The LTC1543 is a
dedicated data/clock chip and the
LTC1544 is a control-signal chip. The
chip set supports the V.28 (RS232),
V.35, V.36, RS449, EIA-530, EIA-530A
and X.21 protocols in either DTE or
DCE mode.
In the Design Ideas section, we
feature a 1kHz, 8th order Butterworth highpass filter, power gain
stages to extend the output-power
capability of the LT1533 ultralow noise
switching regulator, a nanopower
zero-bias detector and a complete battery backup solution based on a single
NiCd cell and the LT1558 batterybackup controller.
We conclude with Design Information on the LTC1660 10-bit octal DAC
and the LTC1632 SMBus switch controller and a pair of New Device
Cameos.
“Demand for our products remained
strong and well diversified across
end markets,” said Robert Swanson,
president and CEO of Linear Technology Corporation. “We had another
strong quarter, achieving record levels for sales and profits. The turmoil
in the Asian financial markets did
not have a material impact on our
business in this quarter, although
we continue to closely monitor this
geographical area for its impact in
the future.”
Douglas Lee, an analyst at
NationsBanc Montgomery Securities
in San Francisco, predicts that Linear Technology will “see a sequential
sales growth of about 7% for the
March quarter.” This was reported
in the January 19, 1998 issue of
Electronic Buyers’ News.
Net sales for the second quarter
ended December 28, 1997 were
$117,004,000, an increase of 30%
over net sales of $90,080,000 for the
second quarter of the previous year.
The Company also reported
net income for the quarter of
$43,582,000, an increase of 38%
over the $31,631,000 reported for
the second quarter of last year.
Diluted earnings per share (EPS)
were $0.55 compared to $0.40 for
the similar quarter last year. This is
the first quarter that earnings per
share (EPS) are reported in compliance with the new Financial
Accounting Standards Board pronouncement No. 128. Diluted EPS is
analogous to the methodology the
Company used in the past in reporting EPS.
During the quarter, Linear Technology purchased 1,002,500 shares
of its stock for $56.4 million, $5.9
million of which was paid after quarter end. A cash dividend of $0.40 will
be paid on February 11, 1998 to
shareholders of record on January
23, 1998
Linear Technology Magazine • February 1998
DESIGN FEATURES
INV
V+
BP
LP
INV
BP
LP
*R1 AND C ARE PRECISION
INTERNAL COMPONENTS
1
sR1C*
V+
SHUTDOWN
SWITCH
V–
A
C
B
–
2ND ORDER SECTIONS
SHUTDOWN
SWITCH
SHDN
AGND
D
+
C
LP
V–
INV
INV
BP
LP
INV
BP
BP
RQ
R2
LP
1562 F01
RIN
1562 F02
+
–
Figure 1. LTC1562 block diagram
VIN
LTC1562, continued from page 1
The LTC1562 is versatile; it is not
limited to the lowpass/bandpass filter of Figure 2. Cascading multiple
sections, of course, yields higherorder filters (Figure 3a). A highpass
response results if the external input
resistor (RIN of Figure 2) is replaced by
a capacitor, CIN, which sets only gain,
not critical frequencies (Figure 3b).
Responses with arbitrary zeroes (for
example, elliptic or notch responses)
are implemented with feedforward
connections with multiple 2nd order
blocks, as shown in the application
circuit in Figure 8. Moreover, the virtual-ground INV input gives each
2nd-order section the built-in capability for analog operations such as
gain (preamplification), summing and
weighting of multiple inputs, or
accepting current or charge signals
directly. These flexible 3-terminal
elements are Operational Filter™
blocks.
Although the LTC1562 is offered in
a 20-pin SSOP package, the LTC1562
is a 16-pin circuit; the extra pins are
connected to the die substrate and
should be returned to the negative
power supply. In single-supply appli-
Figure 2. Single 2nd order section, illustrating connection
with external resistors R2, RIN and RQ
cations, these extra V– pins should be
connected directly to a PC board’s
ground plane for the best grounding
and shielding of the filter. 16-pin plastic DIP packaging is also available
(consult the factory).
DC Performance
and Power Shutdown
The LTC1562 operates from single or
dual supply voltages, nominally 5V to
10V total. It generates an internal
half-supply reference point (the AGND
pin), establishing a reference voltage
for the inputs and outputs in
single-supply applications. In these
applications, the AGND pin should be
bypassed with a capacitor to the
ground plane (at V–); the pin can be
connected directly to ground when a
split supply is used. The DC offset
voltage from the filter input to the LP
output for a typical 2nd order section
(unity DC gain) is typically 5mV. Both
outputs swing to within approximately
100mV of each supply rail with loads
of 5kΩ and 30pF.
VIN
To save power in a “sleep” situation, a logic high input on the SHDN
pin will put the LTC1562 into its
shutdown mode, in which the chip’s
power supply current is reduced to
only junction leakage (typically 2µA
from a single 5V supply). The shutdown pin is designed to accept CMOS
levels with 5V swing, for example, 0V
and 5V logic levels when the LTC1562
is powered from either a single 5V or
a split ±5V supply. Note that in the
LTC1562, unlike some other products, a small bias current source
(approximately 2µA) at the SHDN pin
causes the chip to default to the shutdown state if this pin is left open.
Therefore, the user must remember
to connect the SHDN pin to a logic low
for normal operation if the shutdown
feature is not used. (This default-toshutdown convention saves system
power in the shutdown state, since it
eliminates even the microampere current that would otherwise flow from
the driving logic to the bias-current
source.)
VIN
CIN
VOUT
INV
BP
LP
2ND ORDER
INV
BP
LP
2ND ORDER
Figure 3a. Two 2nd order sections cascaded for higher order response
Linear Technology Magazine • February 1998
VOUT
INV
BP
LP
2ND ORDER
Figure 3b. 2nd order section configured for
highpass output
3
DESIGN FEATURES
1
RQ1, 5.62k
R21, 10k
2
3
4
5V
0.1µF
5
R23, 10k
RIN3
10k
VIN1
6
7
RQ3, 5.62k
8
INV B
INV C
BP B
BP C
LP B
LP C
V–
V + LTC1562
SHDN
AGND
LP A
LP D
BP A
BP D
INV D
INV A
0
16
–10
15 RQ2, 13k
–20
14 R22, 10k
GAIN (dB)
VIN2
10
RIN2, 10k
RIN1
10k
VOUT2
–5V
13
0.1µF
12
–40
–50
VOUT1
11
–30
10 R24, 10k
–60
RQ4, 13k
–70
9
–80
10k
RIN4, 10k
1562 TA01
100k
FREQUENCY (Hz)
1M
1562 TA02
Figure 4. Dual, matched 4th order 100kHz Butterworth lowpass filter
Frequency Responses
Lowpass filters with standard all-pole
responses (Butterworth, Chebyshev,
Bessel, Gaussian and so on) of up to
8th order (eight poles) can be realized
with LTC1562 sections connected as
in Figures 2 and 3a; practical
examples appear later in this article.
Resistor ratios program the standard
filter parameters f0, Q and gain;
required values of these filter parameters can be found from tables or from
software such as FilterCAD™ for Windows®, available free from LTC.
The “LP” and “BP” outputs of each
2nd order section, although named
after their functions in Figure 2, can
display other responses than lowpass
and bandpass, respectively, if the
external components are not all
resistors. The highpass configuration
of Figure 3b has a passband gain set
by the ratio CIN/C, where C is an
internal 160pF capacitor in the
LTC1562. The two resistors in Figure
3b control f0 and Q, as in the other
modes.
The LTC1562 is the first
truly compact universal
active filter, yet it offers
instrumentation-grade
performance rivaling much
larger discrete-component
designs.
Bandpass applications can use the
LTC1562 in either of two ways. In the
basic configuration, with the only
external components being resistors
(Figure 2), the BP output has a bandpass response from VIN. With an input
capacitor, as in Figure 3b, the BP
output has a highpass response as
noted above and the LP pin shows a
bandpass response.
The f 0 range is approximately
10kHz–150kHz, limited mainly by the
magnitudes of the external resistors
required. At high f0 these resistors fall
below 5k, heavily loading the outputs
of the LTC1562 and leading to increased THD and other effects. A lower
Figure 5. Frequency response of Figure 4’s
circuit
f0 limit of 10kHz reflects an arbitrary
resistor magnitude limit of 1 Megohm.
The LTC1562’s MOS input circuitry
can accommodate higher resistor values than this, but junction leakage
current from the input-protection circuitry may cause DC errors.
Design formulas and further details
on frequency-response programming
appear in the LTC1562 data sheet.
Low Noise and Distortion
The active (that is, amplifier) circuitry
in the LTC1562 was designed expressly for filtering. Because of this,
filter noise is due primarily to the
circuit resistors rather than to the
amplifiers. The amplifiers also exhibit
exceptional linearity, even at high
frequencies (patents pending). The
noise and distortion performance for
filters built with the LTC1562 compares favorably with filters using
expensive, high performance, off-theshelf op amps that demand many
more external parts and far more
board area (we know, because we’ve
10
TO CIN3
CIN1
150pF
RQ1, 10.2k
2
R21, 35.7k
3
4
5V
0.1µF
5
6
CIN3
150pF
FROM
HP C
R23, 107k
RQ3, 54.9k
7
8
INV B
INV C
BP B
BP C
LP C
LP B
V + LTC1562
–10
15
RQ2, 22.1k
14
R22, 66.5k
13
V–
SHDN
AGND
LP A
LP D
BP A
BP D
INV A
INV D
12
CIN2
150pF
–5V
0.1µF
–20
–30
–40
–50
–60
11
10
R24, 127k
9
RQ4, 98.9k
CIN4
150pF
–70
–80
–90
VOUT
1562 TA08
Figure 6. 8th order Chebyshev highpass filter with 0.05dB ripple (fCUTOFF = 30kHz)
4
0
16
GAIN (dB)
1
CIN
1k
10k
100k
FREQUENCY (Hz)
1M
1562 TA09
Figure 7. Frequency response of Figure 6’s
circuit
Linear Technology Magazine • February 1998
DESIGN FEATURES
10
RFF1, 10k
CIN1, 87pF
RIN1, 19.6k
RQ1, 13k
2
R21, 8.87k
3
4
5V
0.1µF
5
6
R23, 8.87k
RIN3, 69.8k
7
RQ3, 28k
8
–10
INV C
INV B
BP C
BP B
LP C
LP B
SHDN
AGND
LP A
LP D
BP D
INV D
INV A
CIN3, 47pF
–20
15
RQ2, 8.87k
14
R22, 12.1k
13
V–
V + LTC1562
BP A
16
12
GAIN (dB)
1
VIN
0
RIN2, 8.06k
–5V
–30
–40
–50
–60
0.1µF
–70
11
10
R24, 17.8k
9
RQ4, 6.98k
–80
–90
RIN4, 7.32k
1k
10k
100k
FREQUENCY (Hz)
1M
1562 TA04
Figure 9. Frequency response of Figure 8’s
circuit.
VOUT
RFF2, 17.8k
1562 TA03
ALL RESISTORS = 1% METAL FILM
Figure 8. 8th order 100kHz elliptic lowpass filter
built them). The details of this performance depend on Q and other
parameters and are reported for specific application examples below. As
with other low distortion circuits,
accurately measuring distortion performance requires both an input
signal and distortion-analyzing equipment with adequately low distortion
floors.
Low level signals can exploit a low
noise preamplification feature in the
LTC1562. A 2nd order section operated with unity gain, Q = 1 and f0 =
100kHz shows a typical output noise
of 24µVRMS, which gives a 103dB SNR
with full-scale output from a 10V
total supply. However, reducing the
value of RIN in Figure 2 increases the
gain without a proportional increase
in the output noise (unlike many active
filters). A gain of 100 (40dB) with the
same Q and f0 gives a measured output
RIN1A
6.19k
CIN1
680pF
RQ1, 10k
2
R21, 10k
3
4
0.1µF
5
R23, 10k
RIN3B
3.83k
VIN3
The practical circuit in Figure 4 is a
dual lowpass filter with a Butterworth (maximally-flat-passband)
frequency response. Each half gives a
DC-accurate, unity-passband-gain
lowpass response with rail-to-rail
input and output. With a 10V total
power supply, the measured output
noise for one filter is 36µVRMS in a
200kHz bandwidth, and the largeVOUT2
1
5V
RIN3A
6.19k
Dual 4th Order 100kHz
Butterworth Lowpass Filter
VOUT1
RIN1B
3.83k
VIN1
noise of 449µVRMS or an input-referred noise of 4.5µVRMS—a 78dB
output SNR with an input that is
40dB down. Thus, the same circuit
can handle a wide range of input
levels with high SNR by changing (or
switching) the input resistor. In the
example just cited, the ratio of maximum input signal to minimum input
noise, by changing RIN, is 118dB.
6
7
RQ3, 10k
CIN3
680PF
8
INV B
INV C
BP B
BP C
LP B
LP C
V + LTC1562
AGND
LP A
LP D
BP A
BP D
INV A
VOUT3
15
14
13
V–
SHDN
INV D
RIN2B
3.83k
16
12
RQ2, 10k
RIN2A
6.19k
VIN2
–5V
0.1µF
11
10
R24, 10k
9
RQ4, 10k
RIN4B
3.83k
VOUT4
RIN4A
6.19k
VIN4
CIN4
680pF
1562 TA07
ALL RESISTORS = 1% METAL FILM
Figure 10. Quad 3-pole 100kHz Butterworth lowpass filter
Linear Technology Magazine • February 1998
8th Order 30kHz
Chebyshev Highpass Filter
Figure 6 shows a straightforward use
of the highpass configuration in Figure 3b with some practical values.
Each of the four cascaded 2nd order
sections has an external capacitor in
the input path, as in Figure 3b. The
resistors in Figure 6 set the f0 and Q
values of the four sections to realize a
Chebyshev (equiripple-passband)
response with 0.05dB ripple and a
30kHz highpass corner. Figure 7
shows the frequency response. Total
output noise for this circuit is
40µVRMS.
8th Order 100kHz
Elliptic Lowpass Filter
CIN2
680pF
R22, 10k
signal output SNR is 100dB. Measured THD at 1VRMS input is –83.5dB
at 50kHz and –80dB at 100kHz. Figure 5 shows the frequency response
of one filter.
Figure 8 illustrates how sharp-cutoff
filtering can exploit the Operational
Filter capabilities of the LTC1562. In
this design, two external capacitors
are added and the virtual-ground
inputs of the LTC1562 sum parallel
paths to obtain two notches in the
stopband of a lowpass filter, as plotted in Figure 9. This response falls
80dB in one octave; the total output
noise is 46µVRMS and the Signal/
continued on page 32
5
DESIGN FEATURES
An SMBus-Controlled 10-Bit, Current
Output, 50µA Full-Scale DAC by Ricky Chow
6
precision full-scale current is trimmed
to ±1.5% at room temperature and
±2.5% over the commercial temperature range.
There are two ways to shut down
the LTC1427 (see Figure 2). A logic
low at the SHDN pin or a logic high at
bit 7 of the command byte sent
through the SMBus interface will put
the LTC1427 into shutdown mode. In
shutdown mode, the digital data is
retained internally and the supply
current drops to only 12µA typically.
SMBus WRITE BYTE PROTOCOL, WITH SMBus ADDRESS = 0101111B,
COMMAND BYTE = 0XXXXX11B AND DATA BYTE = 11111111B, AD1 = 0, AD0 =1
SDA
COMMAND BYTE
0
1
0
1
1
1
1
1
2
3
4
5
6
7
8
X
X
X
X
X
DATA BYTE
1
1
1
1
1
1
1
1
1
1
ACK
SMBus ADDRESS
ACK
The LTC1427-50 communicates with
external circuitry using the standard
2-wire I2C or SMBus interface. The
operating sequence (Figure 1) shows
the signals on the SMBus. The two
bus lines, SDA and SCL, must be high
when the bus is not in use. External
pull-up resistors are required on these
lines. The LTC1427-50 is a receiveonly (slave) device; the system master
must apply the Write Byte protocol
(Figure 1) to communicate with the
LTC1427-50.
The master places the LTC142750 in a START condition and transmits
a 7-bit address. The write bit is then
made 0. The LTC1427-50 acknowledges and the master transmits the
command byte. The LTC1427 again
acknowledges and latches the active
bits of the command byte into register
A (see the block diagram in Figure 2)
at the falling edge of the acknowledge
pulse. The master then sends the
data byte; the LTC1427-50 acknowledges receipt of the data byte; and,
finally, the 8-bit data byte and the
last two output bits (the two MSBs of
the 10-bit input data) from register A
are latched into the register C at the
falling edge of the final acknowledge
and the DAC current output assumes
the new 10-bit value. A stop condition
is optional.
The LTC1427-50 can respond to
one of four 7-bit addresses. The first
five bits have been factory pro-
SHDN
Description
grammed and are always 01011. The
last two LSB address bits are programmed by the user via AD1 and
AD0 (Table 1). When AD1 and AD0
are both connected to VCC, upon power
up, the 10-bit internal register C is
reset to 1000000000B and the DAC
output is set to midrange. If either
AD1 or AD0 is connected to ground,
at power-up, register C resets to
0000000000B and the DAC output is
set to zero. For the LTC1427-50, the
source current output (IOUT) can be
biased from –15V to (VCC – 1.3V);
WR
ACK
The LTC1427-50 is a 10-bit, current-output DAC with an SMBus
interface. This device provides precision, full-scale current of 50µA ±1.5%
at room temperature (±2.5% over temperature), wide output voltage DC
compliance (from –15V to (VCC – 1.3V))
and guaranteed monotonicity over a
wide supply-voltage range. It is an
ideal part for applications in contrast/brightness control or voltage
adjustment in feedback loops.
SCL
S
9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27
IOUT
S = START
P = STOP
*OPTIONAL
P
FULL-SCALE
CURRENT
ZERO-SCALE
CURRENT
1427_01.EPS
Figure 1. LTC1427-50 operating sequence
SHDN
POWER-ON
RESET
SHDN
SCL
SDA
SMBus
INTERFACE
3
REGISTER A
3-BIT
LATCH
EN1
1
REGISTER B
1-BIT LATCH
SD
EN2
2
REGISTER C
8
SD
VOLTAGE
REFERENCE
RADJ
10-BIT
LATCH
SD
10
EN2
AD0 AD1
10-BIT
CURRENT DAC
IOUT
1427_02.EPS
Figure 2. LTC1427-50 block diagram
Table 1. LTC1427-50 function table
AD1
AD0 SMBus Address Location DAC Power-Up Value
Application
L
L
0101101
Zero-scale
LCD Backlight Control
L
H
0101111
Zero-scale
General Purpose
H
L
0101110
Zero-scale
General Purpose
H
H
0101100
Mid-scale
LCD Contrast Control
Linear Technology Magazine • February 1998
DESIGN FEATURES
D1
L1
VOUT*
6
5
VIN
2–4
CELLS
R1
226k
1%
SW
LT1317
SHDN
1µF
3
SHDN
FB
GND
4
LTC1427-50
2
1
R2
12.1k
1%
VC
1
2
3
C1
1µF
4700pF
100k
Digitally Controlled
CCFL Current Using
the SMBus Interface
VCC = 3.3V
4
Figure 4 is a schematic of a 90%
efficient, digitally controlled floating
CCFL lamp supply using the SMBus
serial interface. The DAC current output is connected to the ICCFL pin of
LT1184F. With the DAC output current range of 0µA to 50µA, this circuit
gives 0mA to 6mA lamp current for a
typical display. Varying the lamp current from its minimum to maximum
level adjusts the lamp intensity, and
hence, the display brightness.
µP
SHDN
VCC
AD1
IOUT
AD0
SCL
GND
SDA
8
(e.g., 8051)
7
6
P1.2
5
P1.1
P1.0
*VOUT = 12.7V–24V IN 11mV STEPS
15mA FROM 2 CELLS
35mA FROM 3 CELLS
L1 = 10µH (SUMIDA CD43
MURATA-ERIE LQH3C
OR COILCRAFT DO1608)
D1 = MBR0530
Figure 3. Digitally controlled LCD bias generator
Conclusion
Digitally Controlled
LCD Bias Generator
Figure 3 is a schematic of a digitally
controlled LCD bias generator using
a standard SMBus 2-wire interface.
The LT1317 is configured as a boost
converter, with the output voltage
(VOUT) determined by the values of the
feedback resistors, R1 and R2. The
LTC1427-50’s DAC current output is
connected to the feedback node of the
LT1317. The LTC1427-50’s DAC current output increases or decreases
according to the data sent via the
SMBus. As the DAC output current
varies from 0µA to 50µA, the output
voltage is controlled over the range of
12.7V to 24V. A 1LSB change in the
DAC output current corresponds to
an 11mV change in the output voltage.
LAMP
AN ALUMINUM ELECTROLYTIC WITH
AN ESR ≥0.5Ω IS RECOMMENDED
FOR C3B TO PREVENT DAMAGE TO
THE LT1184F HIGH-SIDE SENSE
RESISTOR DUE TO SURGE
CURRENTS AT TURN-ON.
R3
100k
Q2*
C1*
0.1µF
1 CCFL
PGND
12
VIN
3
DIO
C7
4
CCFL VC
1µF 5
AGND
7
NC
8
NC
9
NC
CCFL 16
VSW
15
BULB
14
BAT
13
ROYER
11
REF
10
NC
6
SHDN
2
ICCFL
VCC
3.3V
+
VBAT
C3A 8V–28V
2.2µF
35V
R1
750Ω
D1
1N5818
LTC1427-50
1
7
2
3
SHDN
5
Q1*
L2
100µH
LT1184F
4
C3B
2.2µF
35V
R2
220k
*DO NOT SUBSTITUTE COMPONENTS
+
1
+
L1 = COILTRONICS CTX210605
L2 = COILTRONICS CTX100-4
COILCTRONICS (561) 241-7876
C4
2.2µF
0µA–50µA ICCFL CURRENT GIVES
0mA–6mA LAMP CURRENT FOR A
TYPICAL DISPLAY
L1
2
3
Q1, Q2 = ZETEX ZTX849 OR ROHM
C5
2SC5001
1000pF
VIN
3.3V
C2
27pF
3kV
6
10
C1 MUST BE A LOW LOSS
CAPACITOR (WIMA MKP-20)
D5
BAT85
The LTC1427-50 is a precision 10-bit,
50µA full-scale DAC that communicates directly with an I2C or SMBus
interface. It operates from a wide supply range, consumes low power, has
guaranteed monotonicity and is packaged in a popular SO-8. It is ideal for
applications such as contrast/
brightness controls, output voltage
adjustment in power supplies and
other potentiometer applications.
SHDN
SDA
IOUT
SCL
AD1
GND
AD0
VCC
5
6
4
}
SMBus TO HOST
8
C6 0.1µF
Figure 4. 90% efficient digitally controlled floating CCFL supply using the SMBus serial interface
Linear Technology Magazine • February 1998
7
DESIGN FEATURES
Micropower 600kHz Fixed-Frequency
DC/DC Converters Step Up from
a 1-Cell or 2-Cell Battery
by Steve Pietkiewicz
Linear Technology introduces two
new micropower DC/DC converters
designed to provide power from a
single-cell or higher input voltage.
The LT1308 features an onboard
switch capable of handling 2A with a
voltage drop of 300mV and operates
from an input voltage as low as 1V.
The LT1317, intended for lower power
requirements, operates from an input
voltage as low as 1.5V. Its internal
switch handles 600mA with a drop of
360mV. Both devices feature Burst
Mode operation at light load; efficiencies are above 70% for load currents
of 1mA. Both devices switch at
600kHz; this high frequency keeps
associated power components small
and flat; additionally, troublesome
interference problems in the sensitive 455kHz IF band are avoided. The
LT1308 is intended for generating
power on the order of 2W–5W. This is
sufficient for RF power amplifiers in
GSM or DECT terminals or for digitalcamera power supplies. The LT1317,
with its smaller switch, can generate
100mW to 2W of power. The LT1317
is available in LTC’s smallest 8-lead
package, the MSOP. This package is
approximately one-half the size of a
standard 8-lead SO package. The
LT1308 is available in the 8-lead SO
package.
Single Li-Ion Cell to 5V/1A
DC/DC Converter for GSM
GSM terminals have emerged as a
worldwide standard. A common
requirement for these products is an
efficient, compact, step-up converter
to develop 5V from a single Li-Ion cell
to power the RF amplifier. The LT1308
performs this function with a minimum of external components. The
circuit is detailed in Figure 1. Many
designs use a large aluminum electrolytic capacitor (1000µF to 3300µF)
at the DC/DC converter output to
hold up the output voltage during the
transmit time slice, since the amplifier can require more than 1A. The
3V TO 4.2V
SHDN
VIN
LBI
SW
C1
100µF
LBO
NiCD
CELL
5V
1A
FB
VC
C1
10µF
LBO
R2
100k
+
+
C2
100µF
3.3V
400mA
R2
100k
+
C1: CERAMIC
C2: AVX TPS SERIES
D1: IR 10BQ015
L1: COILTRONICS CTX5-1
COILCRAFT DO3316-472
1308_01,eps
Figure 1. Single Li-Ion cell to 5V/1A DC/DC converter
C2
100µF
1308_04.eps
Figure 4. Single NiCd cell to 3.3V/400mA DC/DC converter
90
95
V IN = 3.6V
VIN = 1.2V
VOUT = 3.3V
R1 = 169k
85
V IN = 4.2V
80
VOUT
200mV/DIV
AC COUPLED
85
EFFICIENCY (%)
90
EFFICIENCY (%)
D1
GND
RC
47k
CC
22nF
2200µF
C1,C2: AVX TPS SERIES
D1: INTERNATIONAL RECTIFIER 10BQ015
L1: COILTRONICS CTX5-1
COILCRAFT DO3316-472
80
V IN = 3V
75
INDUCTOR
CURRENT
1A/DIV
70
75
70
65
60
1ms/DIV
65
R1
169k
FB
VC
GND
RC
47k
CC
22nF
SW
LT1308
D1
L1
4.7µH
VIN
SHDN
LBI
R1
301k
LT1308
Li-Ion
CELL
L1
4.7µH
55
50
1
10
100
LOAD CURRENT (mA)
1
1000
10
100
LOAD CURRENT (mA)
1000
1308 G01
1308 F01a
Figure 2. Efficiency of Figure 1’s
circuit reaches 90%
8
Figure 3. Transient response of
DC/DC converter: VIN = 3V, 0A–1A
load step
Figure 5. Efficiency of Figure 4’s
circuit reaches 81%
Linear Technology Magazine • February 1998
DESIGN FEATURES
VOUT
200mV/DIV
AC COUPLED
VOUT
200mV/DIV
AC COUPLED
IL1 1A/DIV
ILOAD
400mA
50mA
ILOAD
400mA
50mA
100µs/DIV
20ms/DIV
Figure 6. DECT load transient response: with a single
NiCd cell, the LT1308 provides 3.3V with a 400mA
pulsed load. The pulse width = 416µs.
output capacitor, along with the
LT1308 compensation network,
serves to smooth out the input current demanded from the Li-Ion cell.
Efficiency, which reaches 90%, is
shown in Figure 2. Transient response
of a 0A to 1A load step with typical
GSM profiling (1:8 duty cycle, 577µs
pulse duration) is depicted in Figure
3. Voltage droop (top trace) is 200mV.
Inductor current (bottom trace)
increases to 1.7A peak; the input
capacitor supplies some of this current, with the remainder drawn from
the Li-Ion cell.
Efficiency, reaching 81% from a 1.2V
input, is pictured in Figure 5. Transient response of a typical DECT load
of 50mA to 400mA is detailed in Figure
6. Output voltage droop (top trace) is
under 200mV. Figure 7 zooms in on a
single pulse to show the output voltage and inductor current responses
more clearly.
2-Cell Digital Camera
Supply Produces
3.3V, 5V, 18V and –10V
Power supplies for digital cameras
must be small and efficient while
generating several voltages. The DSP
and logic need 3.3V, the ADC and
LCD display need 5V and biasing for
the CCD element requires 18V and
–10V. The power supplies must also
be free of low frequency noise, so that
postfiltering can be done easily. The
obvious approach, to use a separate
DC/DC converter IC for each output
voltage, is not cost-effective. A single
Single NiCd Cell to 3.3V/
400mA Supply for DECT
Only minor changes are required in
Figure 1’s circuit to construct a singlecell NiCd to 3.3V converter. The large
output capacitor is no longer required
as the output current can be handled
directly by the LT1308. Figure 4 shows
the DECT DC/DC converter circuit.
8
VIN
C1 +
100µF
C6
10µF
2
SW
VC
C8
1nF
R4
47k
C7
22nF
90
3
L1C 3
N = 0.3
R3
340k
SHDN
LT1308
85
L1B
N = 0.7
D1
D2
4
FB
GND
R1
100k
R2
2.01M
80
5V
200mA
+
C2
100µF
+
3.3V
200mA
C3
100µF
D3
CCD BIAS
18V
10mA
7
L1D
N = 3.5
+
6
D1, D2 = IR 10BQ015
D3, D4 = BAT-85
L1 = COILTRONICS CTX02-13973
+
L1E
N=2
5
1308_08.eps
D4
Figure 8. This digital camera power supply delivers 5V/200mA, 3.3V/200mA, 18V/
10mA and –10V/10mA from two AA cells.
Linear Technology Magazine • February 1998
C4
10µF
100mA LOADS
75
70
65
150mA
LOADS
60
6
C1, C2, C3 = AVX TPS
C4, C5 = AVX TAJ
C6 = CERAMIC
LT1308, along with an inexpensive
transformer, generates 3.3V/200mA,
5V/200mA, 18V/10mA and –10V/
10mA from a pair of AA or AAA cells.
Figure 8 shows the circuit. A coupledflyback scheme is used, actually an
extension of the SEPIC (single ended
primary inductance converter) topology. The addition of capacitor C6
clamps the SW pin, eliminating a
snubber network. Both the 3.3V and
5V outputs are fed back to the LT1308
FB pin, a technique known as split
feedback. This compromise results in
better overall line and load regulation. The 5V output has more influence
than the 3.3V output, as can be seen
from the relative values of R2 and R3.
Transformer T1 is available from
Coiltronics, Inc. (561-241-7876).
Efficiency vs input voltage for several
load currents on both 3.3V and 5V
outputs is pictured in Figure 9. The
CCD bias voltages are loaded with
10mA in all cases.
EFFICIENCY (%)
VIN
1.6V
TO 6V
L1A
N=1
10µH 1
Figure 7. DECT load transient response: faster sweep speed
(100µs/DIV) details VOUT and inductor current of a single
DECT transmit pulse.
C5
10µF
CCD BIAS
–10V
10mA
200mA LOADS
55
50
1
1.5
2
2.5 3
3.5 4
INPUT VOLTAGE (V)
4.5
5
1308_09.EPS
Figure 9. Camera power supply efficiency
reaches 78%.
9
DESIGN FEATURES
LT1317 2-Cell to 5V
DC/DC Converter
Figure 10 shows a simple 2-cell to 5V
DC/DC converter using the LT1317.
This device generates a clean, low
ripple output from an input voltage as
low as 1.5V. Designed for 2-cell applications, it offers better performance
than its 1-cell predecessor, the
LT1307. More gain in the error amplifier results in lower Burst Mode ripple,
and an internal preregulator eliminates oscillator variation with input
voltage. For comparison, Figure 11
details transient responses of both
the LT1307 and the LT1317 generating 5V from a 3V input. The load step
is 5mA to 200mA. Output capacitance
in both cases is 33µF. The LT1307 has
low frequency ripple of 100mV,
whereas the LT1317 Burst Mode ripple
of 20mV is the same as the 600kHz
ripple resulting from the output
capacitor’s ESR with a 200mA load.
pass through C1. Since C1 is ceramic,
its ESR is low and there is no appreciable efficiency loss. C5 is charged to
–VOUT when the switch is off, then its
bottom plate is grounded when the
switch turns on. The negative output
is fairly well regulated, since the diode drops tend to cancel. The circuit
is switching continuously at rated
load, where efficiency is 75%. Output
ripple is under 40mV and can be
reduced further with conventional
postfiltering techniques.
Single Li-Ion Cell
to ±4V DC/DC Converter
By again employing the SEPIC topology, a ±4V supply can be designed
with one IC. Figure 12’s circuit generates 4V at 70mA and –4V at 10mA
from an input voltage ranging from
2.5V to over 5V. Maximum component height is 2mm. This converter
uses two separate inductors (L1 and
L2), so it is an uncoupled SEPIC converter. This reduces the overall cost,
but requires that all output current
Conclusion
The LT1308 and LT1317 provide low
noise compact solutions for contemporary portable-product power
supplies.
SHUTDOWN
SW
LBI
2 CELLS
C1
10µF
10V
VOUT
LT1307
100mV/DIV
5V OFFSET
L1
22µH
VIN
SHDN
R1
1M
LT1317
LBO
D1
VC
VOUT
LT1317
100mV/DIV
5V OFFSET
5V
200mA
FB
GND
R2
324k
1%
RC
100k
CC
680pF
+
C2
33µF
ILOAD
200mA
5mA
500µs/DIV
C1: CERAMIC
D1: MOTOROLA MBRO520L
L1: 22 µH SUMIDA CD43-220
1308_10.eps
Figure 11. The LT1317 has reduced Burst Mode
ripple compared to the LT1307.
Figure 10. 2-cell to 5V boost converter using the LT1317
D2A
D2B
–VOUT
–4V/10mA
VIN
2.5V–5V
C5
1µF
SHDN
SHUTDOWN
C1
10µF
SW
VIN
C3
15µF
LB1
LT1317
D1
R1 1M
+VOUT
4V/70mA
FB
LB0
VC
C4
1µF
+
L1
22µH
GND
+
R3
47k
R2
442k
C2
33µF
L2
22µH
C6
680pF
L1, L2 =MURATA LQH3C220
C1 =MURATA GRM235Y5V106Z01
D1 =MBR0520
D2 =BAT54S (DUAL DIODE)
C2 =AVX TAJB33M6010
C3 =AVX TAJA156MO1O
C4, C5 =CERAMIC
Figure 12. This single Li-Ion cell to ±4V DC/DC converter has a maximum height of 2mm.
10
Linear Technology Magazine • February 1998
DESIGN FEATURES
New 333ksps, 16-Bit ADC Offers
90dB SINAD and –100dB THD by Marco Pan
❏ 333ksps throughput
❏ 16 bits with no missing codes
and ±2LSB INL
❏ Low power dissipation and power
shutdown
❏ Excellent AC and DC performance
❏ Small package—36-pin SSOP
These features of the LTC1604 can
simplify, improve, and lower the cost
2.0
1.5
INL (LSB)
1.0
0.5
0.0
–0.5
PRECISION
16-BIT DAC
COMPARATOR
+AIN
SAMPLE/
HOLD
CIRCUIT
– AIN
VREF
(2.50V)
7.5k
SAR
–1.5
–16384
0
16384
32767
CODE
1604_02. eps
Figure 2. The LTC1604 is very accurate,
as
shown in the INL error plot. This accuracy is
achieved without autocalibration and its
associated overhead. Accuracy relies on
capacitor matching, which is very stable over
temperature and time.
Linear Technology Magazine • February 1998
OUTPUT
BUFFER
16
16
LOW DRIFT
VOLTAGE
REFERENCE
REFCOMP
(4.375V)
CLOCK
CONTROL LOGIC
SHDN
RD
BUSY
CONVST
CS
Figure 1. LTC1604 block diagram
of current data acquisition systems
and open up new applications that
were not previously possible because
no similar part was available.
Fast Architecture
To achieve 333ksps with outstanding
AC and DC performance at the 16-bit
level, careful design is required. Figure 1, the LTC1604 block diagram,
illustrates the design of this part. A
high performance differential sampleand-hold circuit, combined with an
extremely fast successive-approximation ADC and an on-chip reference,
delivers an excellent combination of
AC and DC performance. A digital
interface allows easy connection to
microprocessors, FIFOs or DSPs.
Outstanding AC
and DC Performance
–1.0
–2.0
–32768
LTC1604
The DC specifications include 16 bits
with no missing codes and ±2LSB
integral nonlinearity error guaranteed over temperature. The gain of the
ADC is held nearly constant over temperature with an on-chip 10ppm/°C
(typical) curvature-corrected bandgap
reference. Figures 2 and 3 show INL
and DNL error plots, respectively, for
the LTC1604.
The sample-and-hold circuit
determines the dynamic performance
of the ADC. The LTC1604 has a wide
bandwidth, very low distortion, differential sample-and-hold. Fast
Fourier transform (FFT) test techniques are used to test the LTC1604’s
frequency response, distortion and
noise at the rated throughput. By
applying a low distortion sine wave
and analyzing the digital output using
an FFT algorithm, the ADC’s spectral
1.0
0.8
0.6
0.4
DNL (LSB)
The fastest, highest performance
16-bit sampling ADC is now available
in a tiny 36-pin SSOP package from
Linear Technology. It is the LTC1604.
This device runs at 333ksps and
delivers excellent DC and AC performance. The LTC1604 operates on ±5V
supplies and typically draws only
220mW. It is a complete differential,
high speed, low power, 16-bit sampling ADC that requires no external
components. The LTC1604 also provides two power shutdown modes,
NAP and SLEEP, to reduce power
consumption during inactive periods.
This 333ksps, 16-bit device not only
offers the performance of the best
hybrids but also provides low power,
small size, an easy-to-use interface
and the low cost of a monolithic part.
Some of the key features of this new
device include:
0.2
0.0
–0.2
–0.4
–0.6
–0.8
–1.0
–32768
–16384
0
16384
32767
CODE
1604_03. eps
Figure 3. The differential nonlinearity error
plot shows the excellent performance of the
LTC1604.
11
DESIGN FEATURES
0
fSAMPLE = 333kHz
–20
–40
SINAD = 90.2dB
–60
THD = –103.2dB
–80
2000
fIN = 97.152kHz
AMPLITUDE (dB)
fIN = 4.959kHz
–40
SINAD = 89.0dB
1500
–60
COUNT
–20
AMPLITUDE (dB)
2500
0
fSAMPLE = 333kHz
THD = –96dB
–80
–100
–100
–120
–120
1000
500
0
–140
0
20
40
60 80 100 120 140 160
FREQUENCY (kHz)
0
20
40
60
FREQUENCY (kHz)
1604_04.EPS
Figure 4. This FFT of the LTC1604’s
conversion of a full-scale 5kHz sine wave
shows outstanding response with a very low
noise floor when sampling at 333ksps.
content can be examined for frequencies other than the fundamental.
Figures 4 and 5 show the excellent AC
performance of the LTC1604 at
333ksps with fIN = 5kHz and 100kHz,
respectively. The AC performance of
the LTC1604 include total harmonic
distortion of –100dB for a 5kHz input
and –94dB for a 100kHz input and an
input bandwidth of 15MHz for the
sample-and-hold.
Very Low Noise
The noise of an ADC can be evaluated
in two ways: by signal-to-noise ratio
(SNR) in the frequency domain and by
histogram in the time domain. The
LTC1604 excels in both. Figure 4
demonstrates that the LTC1604 has
a SNR of over 90dB in the frequency
domain. The noise in the time-domain
histogram is the transition noise associated with a high resolution ADC,
which can be measured with a fixed
DC signal applied to the input of the
ADC. The resulting output codes are
collected over a large number of conversions. The shape of the distribution
of codes will give an indication of the
magnitude of the transition noise. In
AIN
SINGLE-INPUT
ADC
0 1
CODE
2
Figure 6, the distribution of output
codes is shown for a DC input that
has been digitized 4096 times. The
distribution is Gaussian and the RMS
code transition noise is about
0.66LSB. This corresponds to a noise
level of 90.9dB relative to full scale.
When added to the theoretical 98dB
of quantization error for a 16-bit ADC,
this yields an SNR of 90.1dB, which
correlates very well with the frequency
domain measurements.
Differential Inputs Ignore
Common Mode Noise
Getting a clean signal to the input(s)
of an ADC, especially a 16-bit ADC, is
not an easy task in many systems.
Large noise signals from EMI, the AC
power line and digital circuitry are
usually present. Filtering and shielding are the common techniques for
reducing noise, but these are not
always adequate (see “The Care and
Feeding of High Performance ADCs:
Getting All the Bits You Paid For”;
Linear Technology VI:3 [August,
1996]). The LTC1604 offers another
tool to fight noise: differential inputs.
+AIN
SIGNAL TO BE
MEASURED
LTC1604
AGND
AGND
3
4
5
1604_06.eps
1604_05.EPS
Figure 5. Even with inputs at 100kHz, the
LTC1604’s dynamic linearity remains
robust.
–AIN
SIGNAL TO BE
MEASURED
–5 –4 –3 –2 –1
80 100 120 140 160
Figure 6. This histogram shows that the
LTC1604 has an RMS code transition noise of
0.66dB.
Figure 7a depicts a typical singleended sampling system with ground
noise, which may be 60Hz noise, digital clock noise or some other type of
noise. When a single-ended input is
used, the ground noise adds directly
to the input signal. By using the differential inputs of the LTC1604 the
ground noise can be rejected by connecting the inputs directly across the
signal of interest, as shown in Figure
7b. Ground noise becomes “common
mode” and is rejected internally by
the LTC1604 by virtue of its excellent
common mode rejection ratio (CMRR).
Figure 8 shows the CMRR of the
LTC1604 versus frequency. Notice
that the CMRR is constant over the
entire Nyquist bandwidth and is only
6dB lower at 300kHz. This ability to
reject high frequency common mode
signals is very helpful in sampling
systems, where noise often has high
frequency components due to switching transients.
70
COMMON MODE REJECTION (dB)
–140
60
50
40
30
20
10
0
GROUND
NOISE
Figure 7a. Single-input ADC measuring
a signal riding on common mode noise.
12
GROUND
NOISE
Figure 7b. Differential-input ADC measuring a
signal riding on common mode noise.
0
10
100
INPUT FREQUENCY (kHz)
1000
1604_08.eps
Figure 8. LTC1604 CMRR vs frequency
Linear Technology Magazine • February 1998
DESIGN FEATURES
98
The LTC1604 operates on ±5V supplies, which makes the device easy to
interface to 5V digital systems. This
device can also talk to 3V digital systems: the digital input pins (SHDN,
CS, CONVST and RD) of the LTC1604
recognize 3V or 5V inputs. The
LTC1604 has a dedicated output supply pin (OVDD) that controls the output
swings of the digital output pins (D0–
D15, BUSY) and allows the part to
talk to either 3V or 5V digital systems.
92
14
86
13
80
Low Power Dissipation
and Shutdown
The LTC1604 runs at full speed on
±5V supplies and typically draws only
220mW. This power consumption can
be reduced further by using the two
power shutdown modes, NAP and
SLEEP, during inactive periods. NAP
mode cuts down the power to 8mW,
leaving the reference and logic powered up. The ADC wakes up “instantly”
(400ns) from NAP mode, so NAP mode
can be invoked even during brief
inactive periods with no penalty or
delay when conversions must start
again.
SLEEP mode is used when there
are extended inactive periods. In
SLEEP mode, the ADC powers down
all the circuitry, leaving the logic outputs in a high impedance state. The
only current that remains is junction-leakage current (less than 1µA).
It takes much longer for the ADC to
wake up from SLEEP mode because
the reference circuit must power up
EFFECTIVE BITS
16
15
12
74
11
68
10
62
9
56
8
0
10
100
FREQUENCY (kHz)
SINAD (dB)
3V Input/Output Compatible
50
1000
1604_09.eps
Figure 9. The LTC1604 has essentially
flat
SINAD and effective bits out to Nyquist.
and settle to 0.0006% for full accuracy. The wake-up time also depends
on the value of the compensation
capacitor used on the REF COMP pin.
With the recommended 47µF capacitor, the wake-up time is 160ms.
Applications
The performance of the LTC1604
makes it very attractive to use in a
wide variety of applications, such as
digital signal processing, PC data
acquisition cards, medical instrumentation and high resolution or
multiplexed data acquisition.
DSP applications often require
excellent dynamic performance, since
the ADC must sample high frequency
AC signals. The LTC1604 is the right
choice in these types of applications
because of the performance of its
sample-and-hold. Figure 9 shows how
well the signal-to-noise plus distortion ratio and the spurious free
dynamic range of the converter hold
up as the input frequency is increased.
Another common application is PC
data acquisition cards. The high
sample rate, the simple, complete
configuration and excellent linearity
of the LTC1604 make it an ideal choice
here. Another advantage that the
LTC1604 provides is the synchronized internal conversion clock, which
is very useful in this application. This
feature eliminates the second external clock required by other sampling
ADCs to run conversion, in addition
to the normal sample signal. Clearly,
this feature makes the LTC1604 an
outstanding choice for PC data acquisition cards.
For single-channel or multiplexed
high speed data acquisition systems,
the LTC1604 has the high sample
rate and high impedance inputs that
help smooth the design of these applications. High sample rates allow more
channels in the data acquisition system on a very low power and cost
budget and the high impedance inputs of the ADC make them very easy
to multiplex.
Conclusion
The new LTC1604 is a complete 16-bit
ADC with a built-in sample-and-hold
and reference. It samples at 333ksps
and is the fastest device of its kind on
the market. The excellent DC and AC
performance of the LTC1604 not only
make it extremely valuable in a wide
variety of existing high resolution applications while also opening up new
applications.
for
the latest information
on LTC products,
visit
www.linear-tech.com
Linear Technology Magazine • February 1998
13
DESIGN FEATURES
Ultralow Power 14-Bit ADC
Samples at 200ksps
High Impedance Inputs
A new, versatile 14-bit ADC, the
LTC1418, can digitize at 200ksps
while consuming only 15mW from a
single 5V supply. The LTC1418 is
designed to be easy to use and adaptable, requiring little or no support
circuitry in a wide variety of applications. Some of the key features of this
new device include:
❏
❏
❏
❏
200ksps throughput
Low power—15mW
Single 5V or ±5V supplies
1.25LSB INL max and 1LSB DNL
max
❏ Parallel and serial data output
modes
❏ NAP and SLEEP power shutdown
modes
❏ Small package—28-pin SSOP
High Performance
without High Power
Figure 1 shows a block diagram of the
LTC1418. This device includes a high
performance differential sample-andhold circuit, an ultra-efficient
successive approximation ADC, an
on-chip reference and a digital interface that allows easy serial or parallel
interface to a microprocessor, FIFO
or DSP. The LTC1418 is factory calibrated, so a lengthy calibration cycle
is not required to achieve 14-bit performance. DC specifications include
a 1LSB max differential linearity error
(no missing codes) and 1.25LSB max
integral linearity error guaranteed
over temperature. The gain of the
ADC is controlled by an on-chip
10ppm/°C reference that can be easily overdriven with an external
reference if required.
For AC applications, the dynamic
performance of the LTC1418 is
exceptional. The extremely low distortion differential sample-and-hold
acquires input signals at frequencies
up to 10MHz. At the Nyquist frequency, 100kHz, the spurious free
dynamic range is typically 95dB. The
noise is also low with a signal-tonoise ratio (SNR) of 82dB from DC to
well beyond Nyquist.
The superior AC and DC performance of the LTC1418 doesn’t require
a lot of power. In fact, the LTC1418
has the lowest power of any 14-bit
ADC available, just 15mW at 200kHz
(10mW at sample rates below 50kHz).
Two shutdown modes make it possible to cut power further at lower
sample rates.
The LTC1418’s high impedance inputs allow direct connection of high
impedance sources without introducing errors. Many ADCs have a resistive
input or input bias current that requires low source impedance to
achieve low errors. Other ADCs with
switched capacitor inputs exhibit large
offset shifts when driven with high
source impedance or a large sourceimpedance imbalance between their
differential inputs. The unique
sample-and-hold circuit of the
LTC1418 has a low capacitance, high
resistance (10MΩ||25pF) switchedcapacitor input that has only 2LSB of
offset shift with a source impedance
imbalance between 0Ω and 1M (see
Figure 2a). (There is no shift if the
input impedance is equal for +AIN and
10
CHANGE IN OFFSET VOLTAGE (LSB)
Introduction
by Dave Thomas
8
5
4
2
0
100
10k
100k
1M
1k
SOURCE IMPEDANCE MISMATCH (OHMS)
1418_02a.EPS
5V
Figure 2a. Change in offset voltage with
source impedance mismatch
10µF
VDD
D13
AIN+
S/H
14-BIT ADC
14
AIN –
4.096V
SELECTABLE
SERIAL/
PARALLEL
PORT
BUFFER
8k
VREF
D3 (SCLK)
D2 (CLKOUT)
D0 (EXT/INT)
TIMING AND
LOGIC
2.5V
REFERENCE
1µF
AGND
VSS
(0V OR – 5V)
BUSY
CS
RD
CONVST
SHDN
DGND
Figure 1. LTC1418 block diagram
14
D4 (EXTCLKIN)
D1 (DOUT)
REFCOMP
10µF
D5
1418 TA01
MAXIMUM SAMPLE RATE (SAMPLES/SEC)
SER/PAR
LTC1418
200k
100k
10k
1k
1k
100k
10k
SOURCE RESISTANCE (OHMS)
1M
1418_02b.EPS
Figure 2b. Maximum sample rate vs
unbuffered source resistance
Linear Technology Magazine • February 1998
DESIGN FEATURES
–AIN.) Connecting the ADC directly to
a high impedance source avoids additional noise and offset errors that
may be introduced by buffering circuitry. The only downside to directly
connecting the ADC to a high source
impedance is that the acquisition time
will increase. The low input capacitance (20pF) of the LTC1418 allows
full-speed operation with resistances
up to 2k. Above 2k the sample rate
must be lowered (see Figure 2b).
Differential Inputs
with Wideband CMRR
On-Chip Reference
The differential input of the LTC1418
has excellent common mode rejection, eliminating the need for some
input-conditioning circuitry. Op amps
and instrumentation amplifiers are
often used to reject common mode
noise from EMI, AC power and switching noise. Although these circuits
perform well at low frequencies, their
rejection at high frequencies deteriorates substantially. Figure 3 shows
the CMRR of the LTC1418 vs
frequency.
Single-Supply or
Dual-Supply Operation
Single-supply ADCs can be cumbersome to work with in a dual-supply
system. A signal with a common mode
of zero volts has to be shifted up to the
common mode of the ADC. Shifting
the common mode can be accomplished with AC coupling, but DC
information is lost. Alternatively, an
op amp level shifter can be used, but
this adds circuit complexity and
COMMON MODE REJECTION (dB)
The on-chip reference of the LTC1418
is a standard 2.5V and is compatible
with many system references; it is
available on the REF output (pin 3).
An internal amplifier boosts the 2.5V
reference up to 4.096V; this sets the
span for the ADC. The 4.096V output
is available on the REFCOMP output
(pin4) and may be used as a reference
for other external circuitry. With a
temperature coefficient of 10ppm/°C,
both REF and REFCOMP are suited to
serve as the master reference for the
system. However, if an external reference circuit is required, its easy to
overdrive either reference output. The
2.5V reference output is resistive (4k)
and can be easily overdriven by any
reference with low output impedance
by directly connecting the external
reference to the REF pin. If REFCOMP
(the 4.096V reference) is to be
overdriven, tie the REF pin to ground.
This disables the output drive of the
REFCOMP amplifier, allowing it to be
easily overdriven.
Parallel Data Output
for High Speed
100
80
60
40
20
0
additional errors. The LTC1418 can
operate with single or dual supplies
and allows direct coupling to the
inputs in both cases. The ADC is
equipped with circuitry that automatically detects when –5V is present
at the VSS pin. With a –5V supply, the
ADC operates in bipolar mode and the
full-scale range becomes ±2.048V for
+AIN with respect to –AIN. With a single
supply, VSS = 0V and the ADC operates in unipolar mode with an input
range of 0V to 4.096V.
1k
100k
10k
INPUT FREQUENCY (Hz)
1M
1418_03.EPS
Figure 3. Input common mode rejection vs
input frequency
Linear Technology Magazine • February 1998
The parallel output mode of the
LTC1418 allows the lowest digital overhead. A microcontroller can strobe the
ADC to start the conversion and perform other tasks while the conversion
is running. The ADC will then signal
the microcontroller after the conversion is complete with the BUSY signal,
at which time valid data is available on
the parallel output bus. BUSY may
also be used to clock latches or a FIFO
directly, since data is guaranteed to be
valid with the rising edge of BUSY.
Serial Data Output
for Minimal Wiring
The serial output mode of the LTC1418
is simple, requiring just three pins for
data transfer: a data-out pin, a serial
clock pin and a control pin. However,
its simplicity doesn’t sacrifice flexibility. Serial data can be clocked with
the internal shift clock for minimal
hardware or an external shift clock
for synchronization. Additionally, data
can be clocked out during the conversion for the highest throughput rate
or after the conversion for maximum
noise immunity.
Perfect for Telecom:
Wide Dynamic Range
Telecommunications systems require
wide dynamic range. With its low
noise and low distortion, the LTC1418
offers extremely wide dynamic range
over its entire Nyquist bandwidth.
Spurious free dynamic range is typically 95dB and only starts to drop off
at input frequencies above Nyquist.
The ultralow jitter of the sample-andhold circuit, 5psRMS, keeps the SNR
flat from DC to 1MHz, making this
device useful for undersampling
applications.
Another important requirement for
telecom systems is a low error rate. In
any ADC, there is a finite probability
that a large conversion error (greater
than 1% of full scale) will occur. In
video or flash converters, these large
errors are called “sparkle codes.” Large
errors are a problem in telecom systems such as ISDN, because they
result in errors in data transmission.
All ADCs have a rate at which errors
occur, referred to as the error rate.
The error rate is dependent on the
ADC architecture, design and process. Error rates vary greatly and can
be as low as 1 in 10 billion to as high
as 1 is 1 million. Telecom systems
typically require error rates to be 1 in
1 billion or better.
The LTC1418 is designed to have
ultralow error rates. The error rate is
so low that it is difficult to measure
because of the time in between errors.
To make measurement more practical, the error rate was measured at an
elevated temperature of 150°C,
15
DESIGN FEATURES
15mW
5V
IDD
CONVST = SHDN
0V
CONVST
IDD
LTC1418
3mA
SHDN
POWER DISSIPATION
5V
0
CONVERSION
TIME
NAP
CS
NAP
WAKE-UP
AND
AQUISITION
TIME
2mW
1k
1418_04a.EPS
10k
SAMPLE RATE (SPS)
100k 200k
1418_04b.EPS
Figure 4a. NAP mode between conversions
because error rate increases with
temperature. Even at this high temperature, the error rate was 1 in 100
billion. The projected error rate at room
temperature is 1 in 2,000,000 billion
or about 1 error every 320 years if
running at full conversion rate.
Ideal for
Low Power Applications
LTC1418 is especially well suited for
applications that require low power
and high speed. The normal operating power is low—only 15mW. Power
may be further reduced if there are
extended periods of time between conversions. During these inactive periods
when the ADC is not converting, the
LTC1418 may be shut down. There
are two power shutdown modes: NAP
and SLEEP.
NAP mode shuts down 85% of the
power and leaves only the reference
and logic powered up. The LTC1418
can wake up from NAP mode very
quickly; in just 500ns it can be ready
to start converting. In NAP mode, all
data-output control is functional; data
from the last conversion prior to starting NAP mode can be read during NAP
mode. RD also controls the state of
the output buffers. NAP mode is useful for applications that must be ready
to immediately take data after long
inactive periods.
With slow sample rates, power can
be saved by automatically invoking
NAP mode between conversions.
Referring to Figure 4, the SHDN pin
and CONVST pin are driven together.
A conversion will be started with the
falling edge of this signal; once the
conversion is completed, the ADC will
automatically shut down. Before the
next conversion can start, the
CONVST and SHDN pins must be
brought high early enough to allow
for the 500ns wake-up time. Power
drops with the sample frequency until
it approaches the power of the
reference circuit, about 2mW at frequencies less than 10kHz.
The SLEEP mode is used when the
NAP-mode current drain is too high or
if wake-up time is not critical. In
Figure 4b. Power dissipation vs sample rate
with NAP mode between conversions
SLEEP mode, all bias currents are
shut down, the reference is shut down
and the logic outputs are put in a high
impedance state. The only current
that remains is junction leakage current, less than 1µA. Wake-up from
the SLEEP mode is much slower, since
the reference circuit must power up
and settle to 0.01% for full accuracy.
The wake-up time is also dependent
on the value of the compensation
capacitor used on the REFCOMP pin;
with the recommended 10µF capacitor the wake up time is 10ms. SLEEP
mode is useful for long inactive periods, that is, times greater than 10ms.
Conclusion
The new LTC1418 low power, 14-bit
ADC will find uses in many types of
applications, from industrial instrumentation to telephony. The
LTC1418’s adaptable design reduces
the need for expensive support circuitry. This can result in a smaller,
lower cost system.
Authors can be contacted
at (408) 432-1900
16
Linear Technology Magazine • February 1998
DESIGN FEATURES
A 10MB/s Multiple-Protocol Chip Set
Supports Net1 and Net2 Standards
by David Soo
Introduction
Typical Application
With the increase in multinational
computer networks comes the need
for the network equipment to support
different serial protocols. One solution is to provide a different serial
interface board for each market. This
can become unmanageable as product volume increases. The issues of
board swapping and inventory are
often discounted. Another solution is
to place all of the serial interfaces,
each isolated, on a single board. For
example, when the product is sold
with V.35, the serial cable is mapped
to that section of the board. This
requires a large connector plus signal
routing and board space.
The best solution is to support many
different serial protocols on one connector, but that requires the circuitry
for each serial protocol to share the
same connector pins. At first glance
this may not appear to be difficult.
Further examination reveals conflicting line-termination standards that
require resistors to be switched to the
connector pins. As the designer
becomes occupied with the details of
the interface specification, there is
always the possibility that one small
detail will be missed. This compliance
headache causes designers to seek
out a cost-effective integrated solution.
With the LTC1543, LTC1544 and
LTC1344A, LTC has taken the integrated approach to multiple-protocol.
It does not make sense to use a handful of standard interface parts when
Net1 and Net2 compliance is guaranteed with the LTC1543, LTC1544 and
LTC1344A. Detecon, Inc. documents
this compliance in Test Report No.
NET2/102201/97. With this chip set,
network designers can concentrate
on functions that increase the
end-product value rather than on
standards compliance.
Like the LTC1343 software-selectable
multiprotocol transceiver, introduced
in the August, 1996 issue of Linear
Technology , the LTC1543/LTC1544/
LTC1344A chip set creates a complete software-selectable serial
interface using an inexpensive DB25 connector. The main difference
between these parts is the division of
functions: the LTC1343 can be configured as a data/clock chip or as a
control-signal chip using the CTRL/
CLK pin, whereas the LTC1543 is a
dedicated data/clock chip and the
LTC1544 is a control-signal chip. The
chip set supports the V.28 (RS232),
V.35, V.36, RS449, EIA-530, EIA-530A
and X.21 protocols in either DTE or
DCE mode.
Figure 1 shows a typical application using the LTC1543, LTC1544
and LTC1344A. By just mapping the
chip pins to the connector, the design
of the interface port is complete. The
figure shows a DCE mode connection
to a DB-25 connector.
The LTC1543 contains three drivers
and three receivers, whereas the
LTC1544 contains four drivers and
four receivers. The L TC1344A
contains six switchable resistive terminators that are connected only to
the high speed clock and data signals. When the interface protocol is
Linear Technology Magazine • February 1998
Table 1. Mode pin functions
LTC1543/LTC1544
Mode Name
Not Used
EIA-530A
EIA-530
X.21
V.35
RS449/V.36
RS232/V.28
No Cable
M2
0
0
0
0
1
1
1
1
M1
0
0
1
1
0
0
1
1
M0
0
1
0
1
0
1
0
1
changed via the mode selection pins,
M2, M1 and M0, the drivers, receivers
and line terminators are placed in
their proper configuration. The mode
pin functions are summarized in
Table 1. There are internal 50µA pullup current sources on the mode select
pins, DCE/DTE and the INVERT pins.
DTE vs DCE Operation
The LTC1543/LTC1544/LTC1344A
chip set can be configured for either
DTE or DCE operation in one of two
ways. The first way is when the chip
set is a dedicated DTE or DCE port
with a connector of appropriate gender. The second way is when the port
has one connector that can be configured for DTE or DCE operation by
rerouting the signals to the chip set
using a dedicated DTE or DCE cable.
Figure 1 is an example of a dedicated DCE port using a female DB-25
connector. The complement to this port
is the DTE-only port using a male DB25 connector, as shown in Figure 2.
If the port must accommodate both
DTE and DCE modes, the mapping of
the drivers and receivers to connector
pins must change accordingly. For
example, in Figure 1, driver 1 in the
LTC1543 is connected to pin 3 and
pin 16 of the DB-25 connector. In DTE
mode, as shown in Figure 2, driver 1
is mapped to pins 2 and 14 of the DB25 connector. A port that can be
configured for either DTE or DCE
operation is shown in Figure 3. This
configuration requires separate cables
for proper signal routing.
Cable-Selectable
Multiprotocol Interface
The interface protocol may be selected
by simply plugging the appropriate
interface cable into the connector. A
cable-selectable multiprotocol DTE/
DCE interface is shown in Figure 4.
text continued on page 32/figures on pp. 18–22
17
DESIGN FEATURES
C6
100pF
C8
100pF
C7
100pF
8
3
11
12
13
LTC1344A
14 2
+
3
1
C3
C1 +
1.0µF 1.0µF
C5
1µF
2
4
+
5
RXD
6
RXC
7
8
TXC
9
SCTE
TXD
10
11
12
13
14
NC
28
CHARGE
PUMP
D1
D2
27
26
5
4
6
7
9 10
16 15 18 17 19 20 22
23 24
MO
M1
M2
VCC
VEE
5.0V
VCC
DCE/DTE
LATCH
21
VCC
1
+ C2
1.0µF
DB-25 FEMALE
CONNECTOR
C4
+ 3.3µF
25
24
3
23
16
22
17
21
9
20
15
19
12
18
24
17
11
16
2
15
14
RXD A (104)
RXD B
RXC A (115)
RXC B
D3
R1
R2
R3
M0
M1
M2
DCE/DTE
7
1
LTC1543
TXC A (114)
TXC B
SCTE A (113)
SCTE B
TXD A (103)
TXD B
SGND (102)
SHIELD (101)
VCC
1 VCC
2 V
DD
CTS
DSR
3
4
5
DCD
DTR
RTS
LL
6
7
8
10
9
11
12
13
14
NC
VEE
GND
D1
D2
28
27
26
5
25
13
24
6
23
22
CTS A (106)
CTS B
DSR A (107)
DSR B
D3
R1
R2
R3
R4
22
8
21
10
20
20
19
23
18
4
17
19
16
18
DCD A (109)
DCD B
DTR A (108)
DTR B
RTS A (105)
RTS B
LL A (141)
D4
M0
15
M1
INVERT
NC
M2
DCE/DTE
LTC1544
M2
M1
M0
1544_01.eps
Figure 1. Controller-selectable DCE port with DB-25 connector
18
Linear Technology Magazine • February 1998
DESIGN FEATURES
C6
100pF
C8
100pF
C7
100pF
8
3
11
12
13
LTC1344A
14 2
3
1
+ C3
C1 +
1.0µF 1.0µF
C5
1µF
2
4
+
CHARGE
PUMP
27
26
5
6
SCTE
7
8
TXC
9
RXC
10
D1
D2
5
4
6
7
9 10
16 15 18 17 19 20 22 23 24
M1
MO
21
1
+ C2
1.0µF
DB-25 MALE
CONNECTOR
C4
+ 3.3µF
25
TXD
RXD
28
M2
VCC
VEE
5.0V
VCC
DCE/DTE
LATCH
24
2
23
14
22
24
21
11
20
15
19
12
18
17
17
9
16
3
15
16
TXD A (103)
TXD B
SCTE A (113)
SCTE B
D3
R1
R2
R3
11
M0
12
M1
13 M2
14
DCE/DTE
7
1
LTC1543
TXC A (114)
TXC B
RXC A (115)
RXC B
RXD A (104)
RXD B
SGND (102)
SHIELD (101)
VCC
1 VCC
2 V
DD
RTS
DTR
3
D1
4
D2
5
DCD
DSR
CTS
LL
28
27
26
4
25
19
24
20
23
23
RTS A (105)
RTS B
DTR A (108)
DTR B
D3
6
R1
7
R2
8
R3
10
R4
9
11
12
13
14
VEE
GND
22
8
21
10
20
6
19
22
18
5
17
13
16
18
DCD A (109)
DCD B
DSR A (107)
DSR B
CTS A (106)
CTS B
LL A (141)
D4
M0
15
M1
INVERT
NC
M2
DCE/DTE
LTC1544
M2
M1
M0
1544_02.eps
Figure 2. Controller-selectable multiprotocol DTE port with DB-25 connector
Linear Technology Magazine • February 1998
19
DESIGN FEATURES
C6
100pF
C8
100pF
C7
100pF
8
3
11
12
13
LTC1344A
14 2
+
3
1
C3
C1 +
1.0µF 1.0µF
C5
1µF
2
4
+
28
CHARGE
PUMP
27
26
DTE_SCTE/
DCE_RXC
6
7
DTE_TXC/
DCE_TXC
8
DTE_RXC/
DCE_SCTE
9
DTE_RXD/
DCE_TXD
10
D1
D2
4
6
7
9 10
M1
MO
21
16 15 18 17 19 20 22 23 24 1
+ C2
1.0µF
DB-25 CONNECTOR
C4
+ 3.3µF
25
5
DTE_TXD/
DCE_RXD
5
M2
VEE
VCC
5.0V
VCC
DCE/DTE
LATCH
24
2
23
14
22
24
21
11
20
15
19
12
18
17
17
9
16
3
15
16
R1
R2
R3
7
1
LTC1543
1 VCC
2 V
DD
DTE_RTS/
DCE_CTS
3
DTE_DTR/
DCE_DSR
4
5
DTE_DCD/
DCE_DCD
6
DTE_DSR/
DCE_DTR
7
DTE_CTS/
DCE_RTS
8
DTE_LL/
DCE_LL
10
9
11
12
13
14
DCE
RXD A
TXD B
RXD B
SCTE A
RXC A
SCTE B
RXC B
TXC A
TXC A
TXC B
TXC B
RXC A
SCTE A
RXC B
SCTE B
RXD A
TXD A
RXD B
TXD B
D3
11
M0
12
M1
13 M2
14
DCE/DTE
VCC
DTE
TXD A
VEE
GND
D1
D2
SGND
SHIELD
28
27
26
4
25
19
24
20
23
23
RTS A
CTS A
RTS B
CTS B
DTR A
DSR A
DTR B
DSR B
DCD A
DCD A
DCD B
DCD B
DSR A
DTR A
DSR B
DTR B
CTS A
RTS A
CTS B
RTS B
LL A
LL A
D3
R1
R2
R3
R4
22
8
21
10
20
6
19
22
18
5
17
13
16
18
D4
M0
15
M1
INVERT
NC
M2
DCE/DTE
LTC1544
DCE/DTE
M2
M1
M0
1544_03.eps
Figure 3. Controller-selectable DTE/DCE port with DB-25 connector
20
Linear Technology Magazine • February 1998
DESIGN FEATURES
CABLE WIRING FOR
DTE/DCE SELECTION
PIN 25
V.35
PIN 7
PIN 7
DTE
PIN 7
RS449, V.36
NC
PIN 7
DCE
NC
RS232
PIN 7
NC
8
VCC
C3
C1 +
1.0µF 1.0µF
C5
1µF
28
2
4
CHARGE
PUMP
+
27
26
5
DTE_SCTE/
DCE_RXC
6
D1
D2
7
DTE_TXC/
DCE_TXC
8
DTE_RXC/
DCE_SCTE
9
DTE_RXD/
DCE_TXD
10
5
4
6
7
9 10
16 15 18 17 19 20 22 23 24
+ C2
1.0µF
21
1
VCC
DB-25 CONNECTOR
C4
+ 3.3µF
25
DTE_TXD/
DCE_RXD
13
LATCH
14 2
+
12
LTC1344A
5.0V
VCC
3
1
11
M1
MO
MODE
3
C8
100pF
M2
PIN 18 PIN 21
C7
100pF
DCE/DTE
MODE
C6
100pF
VEE
CABLE WIRING FOR
MODE SELECTION
24
2
23
14
22
24
21
11
20
15
19
12
18
17
17
9
16
3
15
16
DTE
TXD A
DCE
RXD A
TXD B
RXD B
SCTE A
RXC A
SCTE B
RXC B
TXC A
TXC A
TXC B
TXC B
RXC A
SCTE A
RXC B
SCTE B
RXD A
TXD A
RXD B
TXD B
D3
R1
R2
R3
11
M0
12
M1
13 M2
NC
14
DCE/DTE
7
1
SG
SHIELD
LTC1543
25
VCC
1 VCC
2 V
DD
DTE_RTS/
DCE_CTS
3
DTE_DTR/
DCE_DSR
4
D1
D2
5
DTE_DCD/
DCE_DCD
6
DTE_DSR/
DCE_DTR
7
DTE_CTS/
DCE_RTS
8
21
18
26
4
25
19
24
20
23
23
DCE/DTE
M1
M0
RTS A
CTS A
RTS B
CTS B
DTR A
DSR A
DTR B
DSR B
DCD A
DCD A
DCD B
DCD B
DSR A
DTR A
DSR B
DTR B
CTS A
RTS A
CTS B
RTS B
D3
R1
R2
R3
10
R4
9
11
12
13
14
VEE
GND
28
27
22
8
21
10
20
6
19
22
18
5
17
13
16
D4
M0
15
M1
INVERT
NC
M2
DCE/DTE
LTC1544
1544_04.eps
Figure 4. Cable-selectable multiprotocol DTE/DCE port
Linear Technology Magazine • February 1998
21
DESIGN FEATURES
C6
100pF
3
C8
100pF
11
C7
100pF
8
12
13
LTC1344A
14 2
+ C3
+
C1
1.0µF 1.0µF
C5
1µF
1
2
4
3
+
DTE_LL/
DCE_TM
5
DTE_TXD/
DCE_RXD
6
DTE_SCTE/
DCE_RXC
7
44
9
10
12
13
DTE_TXC/
DCE_TXC
DTE_RXC/
DCE_SCTE
14
DTE_RXD/
DCE_TXD
15
DTE_TM/
DCE_LL
16
R1
100k
LB
VCC
D3
4
5
DTE_DCD/
DCE_DCD
6
DTE_DSR/
DCE_DTR
7
8
10
9 10
16 15 18 17 19 20 22 23 24
MO
1
DB-25 CONNECTOR
DTE
18
2
37
14
36
24
35
11
DCE
LL A
TM A
TXD A
RXD A
TXD B
RXD B
SCTE A
RXC A
SCTE B
RXC B
TXC A
TXC A
TXC B
TXC B
RXC A
SCTE A
RXC B
SCTE B
RXD A
TXD A
RXD B
TXD B
TM A
LL A
34
D4
33
32
15
31
12
30
17
29
28
9
3
27
16
26
25
21
DCE
19
M2
M1 18
M0 17
7
R1
R2
R3
1 VCC
2 V
DD
DTE_DTR/
DCE_DSR
7
38
40 GND
EC 24
23 LB LTC1343
3
DTE_RL/
DCE_RL
D2
R4
20
CTRL
22
LATCH
11
25 INVERT
423SET
DTE_RTS/
DCE_CTS
DTE_CTS/
DCE_RTS
39
8
6
C4
+ 3.3µF
41
D1
4
21
+ C2
1.0µF
43
42
CHARGE
PUMP
5
M2
M1
VEE
VCC
5.0V
VCC
DCE/DTE
LATCH
VEE
GND
D1
D2
SG
VCC
1
SHIELD
28
27
26
4
25
19
24
20
23
23
RTS A
CTS A
RTS B
CTS B
DTR A
DSR A
DTR B
DSR B
DCD A
DCD A
DCD B
DCD B
DSR A
DTR A
DSR B
DTR B
CTS A
RTS A
CTS B
RTS B
RL A
RL A
D3
R1
R2
R3
R4
22
8
21
10
20
6
19
22
18
5
17
13
16
21
9
D4
11 M0
15
12 M1
INVERT
NC
13 M2
14
DCE/DTE
LTC1544
DCE/DTE
M2
M1
M0
1544_05.eps
Figure 5. Controller-selectable multiprotocol DTE/DCE port with RLL, LL, TM and DB-25 connector
22
Linear Technology Magazine • February 1998
DESIGN IDEAS
High Clock-to-Center Frequency Ratio
LTC1068-200 Extends Capabilities
of Switched Capacitor Highpass Filter
by Frank Cox
continued on page 33
–10dB
10dB/DIV
input signal too much you will also
limit the passband of the filter, and
hence its usefulness.
What makes this filter different is
the 200:1 clock-to-center frequency
ratio (CCFR) and the internal sampling scheme of the LTC1068-200.
Figure 2a shows the amplitude
response of the filter plotted against
frequency from 100Hz to 10kHz. For
comparison, Figure 2b shows the
same filter built with an LTC1068-25.
This is a 25:1 CCFR part. The 200:1
CCFR filter delivers almost 30dB more
ultimate attenuation in the stopband.
A standard amplitude vs frequency
plot of a highpass filter can be misleading because it masks some of the
aforementioned spurious signals
introduced into the passband. Figure
3a is a spectrum plot of the 200:1
filter with a single 10kHz tone on the
input. This plot shows that the
100Hz
5kHz
10kHz
DI_1068_02a. EPS
Figure 2a. Amplitude vs frequency response of
Figure 1’s circuit
–10dB
10dB/DIV
The circuit in Figure 1 is a 1kHz
8th order Butterworth highpass filter
built with the LTC1068-200, a
switched capacitor filter (SCF) building block. In the past, commercially
available switched capacitor filters
have had limited use as highpass
filters because of their sampled-data
nature. Sampled-data systems generate spurious frequencies when the
sampling clock of the filter and the
input signal mix. These spurious frequencies can include sums and
differences of the clock and the input,
in addition to sums and differences of
their harmonics. The input of the
filter must be band limited to remove
frequencies that will mix with the
clock and end up in the passband of
the filter. Unfortunately, the passband of a highpass filter extends
upward in frequency by its very
nature. If you have to band limit the
RH2 10k
RH3 1.47k
100Hz
LTC1068-200
VIN
R11 10k
R31 10k
2
3
4
R41 20k
5
6
7
8
5V
9
0.1µF
10
R43 11.3k
R33 10k
11
12
13
R23 11.3k
14
INV C
INV B
HPB/NB
HPC/NC
BPB
BPC
LPB
LPC
SB
SC
NC
V–
NC
AGND
V+
CLK
NC
NC
SA
SD
LPA
LPD
BPA
BPD
HPA/NA
HPD/ND
INV D
INV A
28
27
10kHz
DI_1068_02b. EPS
Figure 2b. Amplitude vs frequency response
of comparable filter using the LTC1068-25
R22 10k
26 R32 24.3k
25
24
R42 10k
–10dB
23
–5V
22
0.1µF
21
20
19
18
17
200kHz
R44 16.9k
10dB/DIV
1
R21 20k
5kHz
R34 10k
16
15
R24 16.9k
RH4 14.7k
VOUT
200Hz
100kHz
200kHz
DI_1068_03a. EPS
Figure 1. LTC1068-200 1kHz 8th order Butterworth highpass filter
Linear Technology Magazine • February 1998
Figure 3a. Spectrum plot of Figure 1’s circuit
with a single 10kHz input
23
DESIGN IDEAS
LT1533 Ultralow Noise Switching
Regulator for High Voltage or
High Current Applications
by Jim Williams
High Voltage Input Regulator
The LT1533 switching regulator1, 2
achieves 100µV output noise by using
closed-loop control around its output switches to tightly control
switching transition time. Slowing
down switch transitions eliminates
high frequency harmonics, greatly
reducing conducted and radiated
noise.
The part’s 30V, 1A output transistors limit available power. It is possible
to exceed these limits while maintaining low noise performance by
using suitably designed output
stages.
The LT1533’s IC process limits
collector breakdown to 30V. A complicating factor is that the transformer
causes the collectors to swing to twice
the supply voltage. Thus, 15V represents the maximum allowable input
supply. Many applications require
higher voltage inputs; the circuit in
Figure 1 uses a cascoded3 output
stage to achieve such high voltage
capability. This 24V to 5V (VIN = 20V–
50V) converter is reminiscent of
previous LT1533 circuits, except for
6
the presence of Q1 and Q2.4 These
devices, interposed between the IC
and the transformer, constitute a cascoded high voltage stage. They provide
voltage gain while isolating the IC
from their large drain voltage swings.
Normally, high voltage cascodes
are designed to simply supply voltage
isolation. Cascoding the LT1533 presents special considerations because
the transformer’s instantaneous voltage and current information must be
accurately transmitted, albeit at lower
amplitude, to the LT1533. If this is
not done, the regulator’s slew-control
T1
7
5
8
24VIN
(20V TO 50V)
+
4
10µF
9
3
MBRS140
10
1
0.002µF
220Ω
10k
Q3
MPSA42
Q4
2N2222
10k
Q1
(
L3
OPTIONAL
100µH SEE TEXT
)
+
220µF
100µF
12
0.002µF
Q2
1k
5VOUT
+
10k
220Ω
L1
100µH
1k
2
+
4.7µF
2
14
4
3
1500pF
11
5
18k
6
15
COL A
VIN
0.01µF
MBRS140
SYNC
DUTY
SHDN
CT
LT1533
L2
PGND
RT
NFB
10
11
COL B
VC
RVSL
FB
GND
RCSL
9
12
13
12k
10k
16
8
7
7.5k
1%
2.49k
1%
AN70 F40
L1, L3: COILTRONICS CTX100-3
L2: 22nH TRACE INDUCTANCE, FERRITE BEAD OR
INDUCTOR COILCRAFT B-07T TYPICAL
Q1, Q2: MTD6N15
T1: COILTRONICS VP4-0860
Figure 1. A low noise 24V to 5V converter (VIN = 20V–50V): cascoded MOSFETs withstand 100V transformer swings, permitting the LT1533 to
control 5V/2A output.
24
Linear Technology Magazine • February 1998
DESIGN IDEAS
A = 20V/DIV
B = 5V/DIV
(AC COUPLED)
A = 5mV/DIV
C = 100V/DIV
B = 100µV/DIV
10µs/DIV
2µs/DIV
Figure 2. MOSFET-based cascode permits the regulator to control
100V transformer swings while maintaining a low noise 5V output.
Trace A is Q1’s source, Trace B is Q1’s gate and Trace C is the drain.
Waveform fidelity through cascode permits proper slew-control
operation.
Figure 4. Waveforms for Figure 3 at 10W output: Trace A shows
fundamental ripple with higher frequency residue just discernible. The
optional LC section results in Trace B’s 180µVP-P wideband noise
performance.
Current Boosting
loops will not function, causing a
dramatic output noise increase. The
AC-compensated resistor dividers
associated with the Q1–Q2 gate-drain
biasing serve this purpose, preventing transformer swings coupled via
gate-channel capacitance from
corrupting the cascode’s waveformtransfer fidelity. Q3 and associated
components provide a stable DC termination for the dividers while
protecting the LT1533 from the high
voltage input.
Figure 2 shows that the resultant
cascode response is faithful, even with
100V swings. Trace A is Q1’s source;
traces B and C are its gate and drain,
respectively. Under these conditions,
at 2A output, noise is inside 400µV
peak.
Figure 3 boosts the regulator’s 1A
output capability to over 5A. It does
this with simple emitter followers (Q1–
Q2). Theoretically, the followers
preserve T1’s voltage and current
waveform information, permitting the
LT1533’s slew-control circuitry to
function. In practice, the transistors
must be relatively low beta types. At
3A collector current, their beta of 20
sources ≈150mA via the Q1–Q2 base
paths, adequate for proper slew-loop
operation.5 The follower loss limits
efficiency to about 68%. Higher input
voltages minimize follower-induced
loss, permitting efficiencies in the low
70% range.
Figure 4 shows noise performance.
Ripple measures 4mV (Trace A) using
a single LC section, with high fre-
1N4148
1N5817
0.05Ω
T1
Q1
4.7µF
14
11
3
1500pF
4
5
18k
6
0.003µF
VIN
SHDN
COL A
DUTY
COL B
SYNC
CT
PGND
LT1533
RVSL
RT
RCSL
10
0.01µF
VC
Notes:
1 Witt, Jeff. The LT1533 Heralds a New Class of
Low Noise Switching Regulators. Linear Technology VII:3 (August 1997).
2 Williams, Jim. LTC Application Note 70: A Monolithic Switching Regulator with 100µ V Output
Noise. October 1997.
3 The term “cascode,” derived from “cascade to
cathode,” is applied to a configuration that places
active devices in series. The benefit may be higher
breakdown voltage, decreased input capacitance,
bandwidth improvement or the like. Cascoding
has been employed in op amps, power supplies,
oscilloscopes and other areas to obtain performance enhancement.
4 This circuit derives from a design by Jeff Witt of
Linear Technology Corp.
5 Operating the slew loops from follower base current was suggested by Bob Dobkin of Linear
Technology Corp.
330Ω
5V
+
quency content just discernible. Adding the optional second LC section
reduces ripple to below 100µV (trace
B), and high frequency content is
seen to be inside 180µV (note ×50
vertical scale-factor change).
GND
NFB
9
8
FB
+
2
4.7µF
15
Q2
0.05Ω
330Ω
16
L2
7
12V
L3
33µH
+
(
OPTIONAL FOR
LOWEST RIPPLE
)
+
100µF
100µF
1N5817
1N4148
13 10k
12 10k
680Ω
L1
300µH
R1
21.5k
1%
AN70 F42
R2
2.49k
1%
L1: COILTRONICS CTX300-4
L2: 22nH TRACE INDUCTANCE, FERRITE BEAD OR
INDUCTOR. COILCRAFT B-07T TYPICAL
L3: COILTRONICS CTX33-4
Q1, Q2: MOTOROLA D45C1
T1: COILTRONICS CTX-02-13949-X1
: FERRONICS FERRITE BEAD 21-110J
Figure 3. A 10W low noise 5V to 12V converter: Q1–Q2 provide 5A output capacity while preserving the LT1533’s voltage/current slew control.
Efficiency is 68%. Higher input voltages minimize follower loss, boosting efficiency above 71%.
Linear Technology Magazine • February 1998
25
DESIGN IDEAS
A Complete Battery Backup Solution
Using a Rechargeable NiCd Cell
by L.Y. Lin and S.H. Lim
Battery-powered systems, including notebook computers, personal
digital assistants (PDAs) and portable
instruments, require backup systems
to keep the memory alive while the
main battery is being replaced. The
most common solution is to use an
expensive, nonrechargeable lithium
battery. This solution requires lowbattery detection, necessitates battery
access and invites inadvertent battery removal. The LTC1558 battery
backup controller eliminates these
problems by permitting the use of a
single, low cost 1.2V rechargeable
Nickel-Cadmium (NiCd) cell. The
LTC1558 has a built-in fast-/tricklemode charger that charges the NiCd
cell when main power is present.
Figure 1 shows a typical application circuit with an LTC1558-3.3
providing backup power to an
LTC1435 synchronous step-down
switching regulator. The backup circuit components consist of the NiCd
cell, R11–R14, C11–C12, L11 and
Q11. SW11 and R15 provide a soft or
hard reset function.
FROM µP
OPEN DRAIN
SOFT RESET
L11†
22µH
BACKUP
BATTERY
NiCd††
1.2V
+
R14
10k
1
C11
47µF
6.3V
SW
VCC
VBAK
3
7
+ C12
8
1µF
CTL LTC1558-3.3
5
2
RESET
GND
PUSH-BUTTON
RESET
4
SW11
BKUP
FB
R15
12k
TO
µP
6
R13
100k
Q11
Si4431DY
R11
51k
1%
MAIN BATTERY
4.5V–10V
R12
21.2k
(20.0k 1% +
1.21k 1%)
C2
0.1µF
13
9
CSS
0.1µF
CC2
51pF
C1
100pF
RC
10k
16
TG
SW
14
C4
15
BOOST
0.1µF
D1***
LTC1435
6
12
INTVCC
VOSENSE
3
8
ITH
SENSE+
C5
2
7
1000pF
RUN/SS
SENSE–
Q2
1 C
11
BG
OSC
Si4412DY
+ C3
SGND PGND
4.7µF
5
10
16V
COSC
68pF
4
CC
330pF
VIN
EXTVCC
Q1
Si4412DY
SFB
*
**
***
†
††
+
CIN
100µF
16V
×2
L1*
10µH
RSENSE**
0.033Ω
+
D2
MBRS140T3
SUMIDA CDRH125-100
IRC LR2010-01-R033-F
CENTRAL CMDSH-3
SUMIDA CDRH73-220
SANYO CADNICA N-110AA
COUT
100µF
10V
×2
VOUT
3.3V
LOAD CURRENT
3A IN NORMAL MODE
30mA IN BACKUP MODE
R1
35.7k 1%
R5
20k
1%
C6
100pF
1558 01.eps
Figure 1. LTC1558 backup system with LTC1435 as main system regulator
26
Linear Technology Magazine • February 1998
DESIGN IDEAS
OUTPUT POWER (mW)
VBAK = 4V
VOUT = 3.3V
140
120
100
80
60
40
20
0
1.00 1.05 1.10 1.15 1.20 1.25 1.30 1.35 1.40
BACKUP CELL VOLTAGE (V)
1558_02
Figure 2. 3.3V output power vs backup cell
voltage
Normal Mode (Operation
from the Main Battery)
During nor mal operation, the
LTC1435 is powered from the main
battery, which can range from 4.5V to
10V (for example, a 2-series or 2series × 2-parallel Li-Ion battery pack,
or the like) and generates the 3.3V
system output. The LTC1558 operates in standby mode. In standby
mode, the LTC1558 BKUP (backup)
pin is pulled low and P-channel MOSFET Q11 is on. The NiCd cell is fast
charged by a 15mA current source
connected between the LTC1558’s VCC
and SW pins. Once the NiCd cell is
fully charged (according to the
LTC1558’s gas-gauge counter), the
LTC1558 trickle charges the NiCd
cell. R14 sets the trickle-charge current according to the formula I(TRICKLE)
= 10 • (VNiCd – 0.5)/R14. The tricklecharge current is set to overcome the
NiCd cell’s self-discharge current,
thereby maintaining the cell’s full
charge.
Backup Mode (Operation
from the Backup Battery)
The main battery voltage is scaled
down through resistor divider R11–
R12 and monitored by the LTC1558
Authors can be contacted
at (408) 432-1900
Linear Technology Magazine • February 1998
via the FB pin. If the voltage on the FB
pin drops 7.5% below the internal
1.272V reference voltage (due to discharging or exchanging the main
battery), the system enters backup
mode. In backup mode, the LTC1558’s
internal switches and L11 form a synchronous boost converter that
generates a regulated 4V at VBAK. The
LTC1435 operates from this supply
voltage to generate the 3.3V output
voltage. The BKUP pin is pulled high
by R13 and Q11 turns off , leaving its
Battery-powered systems,
including notebook
computers, personal digital
assistants (PDAs) and
portable instruments,
require backup systems to
keep the memory alive while
the main battery is being
replaced. The most common
solution is to use an
expensive, nonrechargeable
lithium battery.
body diode reverse biased. The BKUP
pin also alerts the system microprocessor. C11, a 47µ F capacitor,
provides a low impedance bypass to
handle the boost converter’s transient load current; otherwise, the
voltage drop across the NiCd cell’s
internal resistance would activate the
Table 1. VFB and VBAK voltages
Relative %
Below VR E F % of VR E F
VF B
VB A K
–0%
100%
1.272V 4.332V
–6%
94%
1.196V 4.073V
–7.5%
92.5%
1.177V 4.008V
300
VBAK = 4V
VOUT = 3.3V
250
BACKUP TIME (MINS)
180
160
200
150
100
50
0
0
5
10
15
20
LOAD CURRENT (mA)
25
30
1558_03
Figure 3. Backup time vs 3.3V output
load current
LTC1558’s undervoltage-lockout
function. Table 1 shows several values of VFB vs the VBAK voltage. Figure
2 shows the maximum output power
available at the 3.3V output vs the
NiCd cell voltage. Over 100mW of
output power is achieved for a NiCd
cell voltage greater than 1V. Figure 3
shows the backup time vs the 3.3V
load current using a Sanyo Cadnica
N-110AA cell (standard series with a
capacity of 110mAhrs). Over one hour
of backup time is realized for less
than 80mW of 3.3V output power.
Recovery from
Backup Mode to Normal Mode
When a new main battery pack is
inserted into the system, Q11’s body
diode forward biases. Once the voltage at the FB pin increases to more
than 6% below VREF, the boost converter is disabled and the system
returns to normal mode. The BKUP
pin pulls low and turns Q11 back on.
This allows the new battery pack to
supply input power to the LTC1435.
The LTC1558 now accurately replenishes the amount of charge removed
from the NiCd cell through the internal
charger and gas-gauge counter.
for
the latest information
on LTC products,
visit
www.linear-tech.com
27
DESIGN IDEAS
Zero-Bias Detector Yields High Sensitivity
with Nanopower Consumption
by Mitchell Lee
RF ID tags, circuits that detect a
“wake-up” call and return a burst of
data, must operate on very low quiescent current for months or years, yet
have enough battery power in reserve
to answer an incoming call. For smallest size, most operate in the ultrahigh
frequency range, where the design of
a micropower receiver circuit is problematic. Familiar techniques, such as
direct conversion, super regeneration
or superhetrodyne, consume far too
much supply current for long battery
life. A better method involves a
technique borrowed from simple fieldstrength meters: a tuned circuit and
a diode detector.
Figure 1 shows the complete circuit,
which was tested for proof-of-concept
at 445MHz. This circuit contains a
couple of improvements over the standard L/C-with-whip field-strength
meter. Tuned circuits aren’t easily
constructed or controlled at UHF, so
a transmission line is used to match
the detector diode (1N5712) to a quarter-wave whip antenna. The 0.23λ
transmission-line section transforms
the 1pF (350Ω) diode junction capacitance to a virtual short at the base of
the antenna. At the same time, it
converts the received antenna current to a voltage loop at the diode,
giving excellent sensitivity.
Biasing the detector diode can improve sensitivity,1 but only when the
diode is loaded by an external DC
resistance. Careful curve-tracer
examination of the 1N5712 at the
origin reveals that it follows the ideal
diode equation, with scales of millivolts and nanoamperes. To use a
zero-bias diode at the origin, the external comparator circuitry must not
load the rectified output.
The LTC1540 nanopower comparator and reference is a good choice for
this application because it not only
presents no load to the diode, but also
draws only 300nA from the battery.
This represents a 10-times improvement in battery life over biased
detector schemes. 2 The input is
CMOS, and input bias current
consists of leakage in a small ESDprotection cell connected between the
input and ground. The input leakage
measures in the picoampere range,
whereas the 1N5712 leaks hundreds
of picoamperes. Any rectified output
from the diode is loaded by the diode
itself, not by the LTC1540, and the
sensitivity can match that of a loaded,
biased detector.
The rectified output is monitored
by the LTC1540 comparator. The
LTC1540’s internal reference is used
to set up a threshold of about 18mV
2V–11V
λ/4
12M
FB
10k
3
5
+
6
7
LTC1540
4
O.23λ
10nF
at the inverting input. A rising edge at
the comparator output triggers a oneshot, which temporarily enables
answer-back and any other pulsed
functions.
Total supply current is 400nA, consuming just 7mAH battery life over a
period of five years. Monolithic oneshots draw significant load current,
but the ’4047 is about the best in this
respect. A one-shot constructed from
discrete NAND gates draws negligible
power.
Sensitivity is excellent, and the
circuit can detect about 200mW from
a reference dipole at 100 feet. Range,
of course, depends on operating frequency, antenna orientation and
surrounding obstacles. Sensitivity is
independent of supply voltage; this
receiver will work just as well with a
9V battery as with a single lithium
cell.
The length of the transmission line
does not scale with frequency. Owing
to a decrease in diode reactance, the
electrical length will shorten as frequency increases. Adjust the line
length for minimum feed-point
impedance at the operating frequency.
If an impedance analyzer is used to
measure the line, a 1pF capacitor can
be substituted for the diode to avoid
large signal effects in the diode itself.
Consult the manufacturer’s data sheet
for accurate characterization of diode
impedance at the frequency of
interest.
–
2
1
8
CMOS ONE-SHOT
(CD4047)
10nF
180k
Q
Q
Notes:
1. Eccles, W.H. Wireless Telegraphy and Telephony,
Second Edition. Ben Brothers Limited, London,
1918, page 272.
2. Lee, Mitchell. “Biased Detector Yields High Sensitivity with Ultralow Power Consumption.” Linear
Technology VII:1(February 1997), page 21.
1N5712
Figure 1. Nanopower field detector
28
Linear Technology Magazine • February 1998
DESIGN INFORMATION
Micropower Octal 10-Bit DAC Conserves
Board Space with SO-8 Footprint
by Kevin R. Hoskins
Introduction
Rail-to-Rail Output Amplifiers
Single Supply, 60µA per DAC
Historically, many circuits have relied
on potentiometers for adjustment or
control. Increasingly, microcontrollers and microprocessors are finding
applications in these circuits. The
inclusion of processors can eliminate
potentiometers, replacing them with
digital-to-analog converters (DACs).
Fulfilling this need is the LTC1660.
Each internal DAC has an amplifier
that buffers its output. The amplifiers’ output voltage can swing
rail-to-rail; they can source or sink
up to 5mA while maintaining guaranteed linearity and monotonicity
performance. Additionally, the
amplifiers can easily drive 1000pF
and remain stable. Higher capacitive
loads (such as 0.1µF) can be driven
by placing a small value resistor (100Ω
typical) in series with the output pin.
The LTC1660 maintains its specified
operation over the wide supply range
of 2.7V to 5.5V. To ensure efficient
operation on this supply range, the
total typical supply current drawn is
just 480µA. The wide supply range
and low current requirements make
this DAC ideal for battery-powered
applications.
Features
Eight DACs in 0.045in2
The LTC1660 is the latest multichannel DAC from Linear Technology. This
10-bit, voltage-output, octal DAC is
designed to conserve board space.
Packaged in a 16-pin narrow SSOP, it
has an 8-pin SO footprint. Figure 1 is
a block diagram showing the
LTC1660’s major circuit features.
LTC1660
2 VOUT A
3 VOUT B
Inherent 10-Bit
Monotonicity and Linearity
(DNL) Performance
The LTC1660 uses a DAC architecture that features excellent ±0.5dB
differential linearity accuracy,
ensuring inherently monotonic performance. This is important for
closed-loop control applications, since
nonmonotonic operation compromises loop stability. Figures 2a and
2b show the LTC1660’s INL and DNL
performance, respectively.
4 VOUT C
5 VOUT D
1
Reference Input
The LTC1660 uses a single external
reference voltage for all its internal
DACs. This voltage sets its full-scale
output range. The reference voltage
magnitude has a range of 0V to VCC.
Figure 3 shows a micropower LT14602.5 voltage reference setting the
LTC1660’s full-scale output to 2.5V.
DAC A
DAC H
DAC B
DAC G
DAC C
DAC F
DAC D
DAC E
VOUT H 15
VOUT G 14
VOUT F 13
VOUT E 12
GND
VCC
6
16
REF
7 CS/LD
8
CLK
CONTROL LOGIC
ADDRESS DECODER
11 CLR
9
DIN
SHIFT REGISTER
DOUT
10
Figure 1. LTC1660 block diagram
Linear Technology Magazine • February 1998
29
DESIGN INFORMATION
1.00
1.00
0.75
0.75
0.25
0
–0.25
1660_XX.EPS
11
0.1µF
7
–0.75
Figure 2a. LTC1660 integral nonlinearity
error
LT1460-2.5
–0.25
–0.75
128 256 384 512 640 768 896 1024
CODE
1
0
–0.50
0
16
6
0.25
–0.50
–1.00
LTC1660
0.1µF
16k
0.50
DNL ERROR (LSB)
INL ERROR (LSB)
0.50
5V
–1.00
SERIAL
INTERFACE
8
9
10
0
128 256 384 512 640 768 896 1024
CODE
VCC
REF
GND
CLR
CS/LD
CLK
DIN
DOUT
VOUT A 2
3
VOUT B
4
VOUT C
5
VOUT D
12
VOUT E
13
VOUT F
14
VOUT G
15
VOUT H
Figure 3. An LT1460 2.5V reference sets the
LTC1660’s full-scale output to 2.5V.
1660_YY.EPS
Figure 2b. LTC1660 differential nonlinearity
error
Asynchronous CLEAR
SLEEP Mode
Further power saving is possible when
the LTC1660 is placed in SLEEP mode.
Activating SLEEP mode shuts off all
internal bias currents and places the
output amplifiers in a high impedance state. The SLEEP mode reduces
current consumption to 1µA or less.
The digital circuitry remains active,
retaining the stored values for each
DAC. There are two ways to take the
part out of SLEEP mode: loading any
ADDRESS/CONTROL value other
than SLEEP mode or applying a logic
low to the CLR pin. The last technique
awakens the LTC1660 and sets all
eight outputs to 0V.
multiple LTC1660s and other LTC
DACs to the same serial data line. The
daisy chain is linked by connecting a
part’s DOUT pin to the DIN pin of the
next part in the chain. The advantages of the single serial data line
include reduced circuit board space,
reduced radiation that results from
fewer circuit traces and conservation
of limited microcontroller or microprocessor I/O lines.
This active low input will asynchronously reset all eight DAC outputs to
0V when a logic low is applied to this
pin. It also deactivates the SLEEP
mode.
Applications
The LTC1660 shines brightly in
applications that take advantage of
its micropower, linearity and
versatility. The applications include
offset and gain adjust in industrial
Power-On Reset
control systems and AGC and transmit
power
adjustment in wireless
The LTC1660’s power-on reset encommunication.
sures that the output voltage on each
DAC is set to 0V when power (2.7V–
continued on page 33
5.5V) is first applied to the VCC pin.
Serial Interface
The eight internal DACs are addressed
individually over a 3-wire, SPI-compatible interface. The three signals
are Chip Select/Load (CS/LD), Serial
Clock (CLK) and Data In (DIN).
Schmitt Trigger Inputs
The LTC1660’s Schmitt trigger digital
inputs prevent false triggers when
responding to noisy signals or those
having slow rise or fall times. This
quality makes the LTC1660 ideal for
remote placement at the end of long
serial transmission lines or lines that
use optoisolators.
DOUT Daisy Chain
Another feature of the LTC1660’s serial interface is its DOUT pin. The
current contents of the internal shift
register are shifted out on this pin as
new data is shifted in on the DIN pin.
This pin makes it possible to connect
30
Table 1. DAC address/control functions
Bit14
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
Address/Control
Bit13
Bit12
0
0
0
0
0
1
0
1
1
0
1
0
1
1
1
1
0
0
0
0
0
1
0
1
1
0
1
0
1
1
1
1
Bit11
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
Action
No Update
Load DAC A
Load DAC B
Load DAC C
Load DAC D
Load DAC E
Load DAC F
Load DAC G
Load DAC H
None
None
None
None
None
SLEEP Mode
Load all DACSs with the same 10-bit code
Linear Technology Magazine • February 1998
DESIGN INFORMATION
Tiny MSOP Dual Switch Driver
is SMBus Controlled
Introduction
by Peter Guan
VCC
2.7V TO 5.5V
The LTC1623 SMBus™ switch
controller offers an inexpensive,
space-saving alternative for controlling peripherals in today’s complex
portable computer systems. Pin-topin connections between the system
controller and each peripheral device
not only result in complicated wiring,
but also limit the number and type of
peripheral devices connected to the
system controller. Using the SMBus
architecture, the LTC1623 eliminates
these problems by requiring only two
bus wires and allowing easy upgrades
and additions of new peripherals.
10µF
VCC
(FROM
SMBus)
1k
Q1
Si3442DV
GA
CLK
DATA
0.1µF
Q1
Si3442DV
0.1µF
AD0
(PROGRAMMABLE)
AD1
GND
PRINTER
DISPLAY
1623 F02
Figure 2. LTC1623 controlling two high-side switches
5V
10µF
VCC
1k
The SMBus
Q1
Si3442DV
GA
CLK
DATA
TO PC CARD VCC
0V/3.3V/5V
0.1µF
Q2*
LTC1623
The SMBus is a low power serial bus
developed by Intel and Duracell. Only
two bus lines, DATA and CLK, are
needed to establish a set of protocols
for communication between the bus
master and slaves. Using the SEND
BYTE protocol of the SMBus to receive and execute commands from
the bus master, each LTC1623 controls the operation of two independent
external switches. To identify itself
on the SMBus, the LTC1623 has two
three-state address pins. In other
words, up to eight LTC1623s can be
programmed to control up to sixteen
different switches.
1k
LTC1623 GB
AD0
1µF
10k
1k
1623 TA02
Q3*
GB
AD1
GND
0.1µF
3.3V
*1/2 Si6926DQ
Figure 3. PC Card 3.3V/5V switch matrix.
bits and one read/write bit. If the
address byte matches, the LTC1623
acknowledges the master and then
shifts in the command byte whose two
LSBs are the controlling signals for
the two external switches. Afterwards,
the LTC1623 again acknowledges the
master so that the master can terminate the transaction by sending a
Stop signal (a DATA transition from
LTC1623 Design Information low to high while CLK is high).
The LTC1623 adheres strictly to
A timing diagram of the SEND BYTE
protocol is shown in Figure 1. After the SMBus specification of 0.6V VIL
detecting the Start signal from the and 1.4V VIH over the entire operating
bus master (a high-to-low transition range of 2.7V to 5.5V. The two built-in
on the DATA line while CLK is high), charge pump triplers with micropower
the LTC1623 shifts in the address feedback networks guarantee full enbyte, which consists of seven address hancement of the two external
logic-level MOSFET switches without
excess gate overdrive. The output gatedrive voltage is regulated to a
maximum of 6V above VIN.
Applications
The main application of the LTC1623
is to control two external high-side Nchannel switches (Figure 2). As seen
in the figure, a 0.1µF capacitor and a
1k resistor are placed on each gatedrive output to respectively slow down
the turn-on time of the external switch
and to eliminate any oscillations
caused by the parasitic capacitance
of the external switch and the parasitic inductance of the connecting
wires.
SMBus is a trademark of Intel Corp.
CLK
START
1
0
1
1
DATA
0
0
0
(PROGRAMMABLE)
ADDRESS BYTE
0
ACK
(WRITE)
0
0
0
0
0
0
1
1
ACK
STOP
(GB ON)(GA ON)
COMMAND BYTE
1623 TD02
Figure 1. SMBus SEND BYTE protocol timing diagram
Linear Technology Magazine • February 1998
31
CONTINUATIONS
Tracking the growing popularity of
portable communication systems, the
LTC1623 makes a very handy singleslot 3.3V/5V PC Card switch matrix.
As shown in Figure 3, this circuit
enables a system controller to switch
either a 3.3V or a 5V supply to any of
its SMBus-addressed peripherals.
Besides N-channel switches, the
LTC1623 can also be used to control
a P-channel switch, as shown in Figure 4. As a result, the load connected
to the P-channel switch will be turned
on upon power-up of the LTC1623,
whereas the other load must wait for
a valid address and command to be
powered.
VCC
2.7V TO 5.5V
10µF
VCC
DATA
Adding Optional Test Signal
In some cases, the optional test signals local loopback (LL), remote
loopback (RL) and test mode (TM) are
required but there are not enough
drivers and receivers available in the
Q1
Si3442DV
0.1µF
1k
LTC1623 GB
(PROGRAMMABLE)
0.1µF
AD0
Q2
Si6433DQ
AD1
GND
DISPLAY
FAN
1623 F02
Figure 4. LTC1623 controlling a P-channel switch (Q2)
Conclusion
With a standby current of only 17µA
and a tiny 8-lead MSOP (or SO) footprint, the LTC1623 offers a simple
and efficient solution for managing
system peripherals using the SMBus
architecture.
Conclusion
LTC1543, continued from page 17
The mode pins are routed to the
connector and are left unconnected
(1) or wired to ground (0) in the cable.
The internal pull-up current sources
ensure a binary 1 when a pin is left
unconnected and also ensure that
the LTC1543/LTC1544/LTC1344A
enter the no-cable mode when the
cable is removed. In the no-cable
mode, the LTC1543/LTC1544 power
supply current drops to less than
200µ A and all of the LTC1543/
LTC1544 driver outputs will be forced
into the high impedance state.
1k
GA
CLK
(FROM
SMBus)
LTC1543/LTC1544 to handle these
extra signals. The solution is to combine the LTC1544 with the LTC1343.
By using the LTC1343 to handle the
clock and data signals, the chip set
gains one extra single-ended driver/
receiver pair. This configuration is
shown in Figure 5.
In the world of network equipment,
the product differentiation is mostly
in the software and not in the serial
interface. The LTC1543, LTC1544 and
LTC1344A provide a simple yet comprehensive solution to standards
compliance for multiple-protocol
serial interface.
Compliance Testing
A European standard EN 45001 test
report is available for the LTC1543/
LTC1544/LTC1344A chip set. The
report provides documentation on the
compliance of the chip set to Layer 1
of the NET1 and NET2 standard. A
copy of this test report is available
from LTC or from Detecon, Inc. at
1175 Old Highway 8, St. Paul, MN
55112.
Authors can be contacted
at (408) 432-1900
LTC1562 continued from page 5
Quadruple 3rd Order 100kHz
Butterworth Lowpass Filter
Another example of the flexibility of
the virtual-ground inputs is the ability to add an extra, independent real
pole by replacing the input resistor in
Figure 2 with an R-C-R “T” network.
In Figure 10, a 10k input resistor has
been split into two parts and the
parallel combination of the two forms
a 100kHz real pole with the 680pF
32
Conclusion
external capacitor. Four such 3rd order Butterworth lowpass filters can
be built from one LTC1562. The same
technique can add additional real
poles to other filter configurations as
well, for example, augmenting Figure
4’s circuit to obtain a dual 5th order
filter from a single LTC1562.
The LTC1562 is the first truly compact universal active filter, yet it offers
instrumentation-grade performance
rivaling much larger discrete-component designs. It serves applications
in the 10kHz–150kHz range with an
SNR as high as 100dB or more (16+
equivalent bits). The LTC1562 is ideal
for modems and other communications systems and for DSP antialiasing
or reconstruction filtering.
Linear Technology Magazine • February 1998
CONTINUATIONS
LTC1660 continued from page 30
Accessing the Functionality
Table 1 shows the DAC ADDRESS/
CONTROL codes that update each of
the DACs, activate the SLEEP mode,
cause “No Update”, or update all DACs
with the same 10-bit value.
The four MSBs (Bit15–Bit12) of the
16-bit data word sent to the LTC1660
select a DAC for updating or a control
function such as SLEEP. The next ten
bits (Bit11–Bit2) are the data that sets
the selected DAC’s output voltage.
For example, with a 2.5V reference
voltage applied to the LTC1660’s pin
6, a value of 819 (1100110011) on
Bit11–Bit2 sets the DAC’s output voltage to 819/1024 • 2.5V, = 2.0V. The
last two bits (Bit1–Bit0) are “don’t care.”
When a 4-bit “no update” code is sent
(Bit15–Bit12 = 0000 and 1001–1101),
the contents of Bit11–Bit0 are ignored.
The SLEEP mode is selected by sending Bit15–Bit12 = 1110. The LTC1660
is awakened by applying a logic low to
the CLR pin or by completing a data
load cycle. To awaken the part with a
load cycle and return to the same
output voltages as before SLEEP, use
address/control locations Bit15–Bit12
= 0000 or 1001–1101. Using CLR to
awaken the LTC1660 changes the
contents of all DAC registers to zeros
and the output voltage to 0V. Finally,
all DACs can be forced to the same
output voltage by using address/control location Bit15–Bit12 = 1111.
Layout, Bypassing and
Grounding Considerations
Like all data converters, the LTC1660
performs best when it is properly
grounded, bypassed and placed on a
PCB layout optimized for low noise.
Proper grounding is achieved by placing the part over an analog ground
plane. Ideally, no traces should cut
through the analog ground plane. If a
digital ground plane is present, it
should make contact with the analog
ground plane at only one point, usually where the board is grounded to
the power supply ground. If the board
consists of multiple layers, the digital
and analog ground planes should not
overlap each other. The ground pin
(pin 1) should be connected to the
analog ground plane.
Two 0.1µ F bypass capacitors
should be connected between the
LTC1660 and the analog ground
plane. One capacitor is connected to
the VCC input (pin 16) and the other is
connected to the reference input (pin
6). Lead lengths should be as short as
possible.
To help ensure that digital switching noise does not contaminate the
analog output, pins 7–11 should be
placed over the digital ground plane
and not cross the analog ground plane.
Conclusion
The LTC1660 10-bit octal DAC features a very small narrow SSOP-16
package, micropower operation and
power saving SLEEP mode. These features make this the ideal part for
dense circuit boards and battery-powered applications.
LTC1068-200 continued from page 23
200Hz
100kHz
200kHz
DI_1068_03b. EPS
Figure 3b. Spectrum plot of Figure 1’s circuit
with a single 150kHz input
spurious free dynamic range (SFDR)
of the LTC1068 highpass filter is in
excess of 70dB. In fact, the filter has
a 70dB SFDR for all input signals up
to 100kHz. In a 200kHz sampleddata system, you would normally need
to band limit the input below 100kHz,
Linear Technology Magazine • February 1998
the Nyquist frequency. Because the
LTC1068 uses double sampling techniques, its useful input frequency
range extends to the Nyquist frequency and even above, albeit with
some care. Figure 3b shows the
LTC1068-200 highpass filter with an
input frequency of 150kHz. There is a
spurious signal at 50kHz, but even
though there is no input filtering, the
SFDR is still 60dB. For input signals
from 100kHz to 150kHz, the filter
demonstrates an SFDR of at least
60dB. The SFDR plot of the same
filter built with the LTC1068-25 is
shown in Figure 4. Note that the lower
CCFR (25:1) part still manages a
respectable 55dB SFDR with a 10kHz
input. The LTC1068-25 is used primarily for band-limited applications,
such as lowpass and bandpass
filters.
–10dB
10dB/DIV
10dB/DIV
–10dB
100Hz
12.5kHz
25kHz
DI_1068_04. EPS
Figure 4. Spectrum plot of a comparable filter
using the LTC1068-25 with a single 10kHz
input shows a respectable 55dB SFDR.
Note:
The filters for this article were designed using
Linear Technology’s FilterCAD™ (version 2.0) for
Windows®. This program made the design and
optimization of these filters fast and easy.
33
NEW DEVICE CAMEOS
New Device Cameos
Ultralow IQ LTC1474,
LTC1475 Stepdown DC/DC
Converter Family Grows
The LTC1474/LTC1475 family has
been expanded to cover a complete
range of output voltage, package and
operating-temperature options. All
members of the family feature 3V to
18V (20V Absolute Maximum) operation, 10µA typical quiescent current
and programmable peak inductor current. The LTC1474 is controlled by a
run pin and features a low-battery
comparator that remains active in
shutdown. The LTC1475 adds an on/
off latch, allowing push-button control of power.
Both the LTC1474 and LTC1475
are available with 3.3V, 5V or adjustable output voltages. All versions are
offered in two packages: the industrystandard small outline 8-pin plastic
package and the tiny 8-pin MSOP
package. MSOP-packaged parts are
specified for the commercial temperature range, whereas all LTC1474 S8
versions and the LTC1475 S8 adjustable version are also available specified
for the industrial temperature range
(see table).
Option
CMS8
CS8
IS8
LTC1474-ADJ
✓
✓
✓
LTC1474-3.3
✓
✓
✓
LTC1474-5
✓
✓
✓
LTC1475-ADJ
✓
✓
✓
LTC1475-3.3
✓
✓
LTC1475-5
✓
✓
Every member of the LTC1474/
LTC1475 family features operating
efficiencies exceeding 90% and a combination of cycle-by-cycle inductor
current control and ultralow quiescent current previously unavailable
in switching regulators. Strapping two
pins together defines a 400mA peak
inductor current with no external
current sense resistor, allowing up to
300mA output currents. Adding an
inexpensive external resistor allows
the user to program the peak inductor
current to as low as 10mA for efficient
low current operation with small
inductors.
The LTC1474/LTC1475 are ideal
for many quiescent-current-sensitive
applications, such as battery-powered, handheld devices, keep-alive
power supplies and industrial 4–20mA
loops.
LT1534 Ultralow Noise
2A Regulator
The LT1534 is the next in the line of
“stealth switchers,” DC/DC converters designed to significantly reduce
conducted and radiated electromagnetic interference (EMC, EMI). By
adjusting the output switch voltage
and current slew rates, noise can be
reduced to unprecedented levels.
These converters can then be used to
generate power in applications that
previously excluded switchers,
including precision instrumentation
systems, medical instruments, singleboard data acquisition systems and
wireless communications. The
LT1534 is specifically designed for
single-output topologies such as
boost, SEPIC and Cuk.
The LT1534 uses a current mode
architecture; it includes a single 2A
power switch along with all necessary
oscillator, control and protection circuitry. Unique error amp circuitry
can regulate both positive and negative voltages. The internal oscillator
may be synchronized to an external
clock. Protection features include
cycle-by-cycle short-circuit protection, undervoltage lockout and
thermal shutdown. Low shutdown
current (12µA typical) and low minimum input voltage requirements
(2.7V) make this part suitable for
battery-operated applications. The
LT1534 is offered in an SO-16 package in a commercial temperature
grade.
The user can independently adjust
the output switch current slew rate
and voltage slew rate. This allows the
user to optimally trade off noise and
efficiency. Because the slew control
reduces the source of switcher noise,
it can reduce or eliminate the need for
power supply shielding and filtering
components.
For further information on any
of the devices mentioned in this
issue of Linear Technology, use
the reader service card or call
the LTC literature service
number:
1-800-4-LINEAR
Ask for the pertinent data sheets
and Application Notes.
34
Linear Technology Magazine • February 1998
DESIGN TOOLS
DESIGN TOOLS
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 compatible) 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 powerful 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 component 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 converters based on Linear Technology’s micropower
switching regulator ICs. Given basic design parameters, MicropowerSCAD selects a circuit topology and
offers you a selection of appropriate Linear Technology
switching regulator ICs. MicropowerSCAD also performs circuit simulations to select the other components
which surround the DC/DC converter. In the case of a
battery supply, MicropowerSCAD can perform a battery life simulation. 44 page manual included.
$20.00
MicropowerSCAD supports the following LTC micropower 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 collection of data sheets covers op amps, voltage regulators,
references, comparators, filters, PWMs, data conversion 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
supplement 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
Linear Technology Magazine • February 1998
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
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 protection of RS232 devices and surface mount packages.
Available at no charge
1995 Linear Databook, Vol IV —This 1152 page supplement to the 1990, 1992 and 1994 Linear Databooks 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 Databook
Vol IV is a companion to the 1990, 1992 and 1994
Linear Databooks, which should not be discarded.
$10.00
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 performance specifications. Topics covered include battery
chargers, PCMCIA power management, microprocessor power supplies, portable equipment power supplies,
micropower DC/DC, step-up and step-down switching
regulators, off-line switching regulators, linear regulators and switched capacitor conversion.
Available at no charge
1996 Linear Databook, Vol V —This 1152 page supplement 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
1997 Linear Databook, Vol VI —This 1360 page supplement to the 1990, 1992, 1994, 1995 and 1996 Linear
Databooks is a collection of all products introduced
since 1996. A total of 79 product data sheets are
included with updated selection guides. The 1997
Linear Databook Vol VI is a companion to the 1990,
1992, 1994, 1995 and 1996 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 catalog
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 broadening topic selection. This new book includes Application
Notes 55 through 69 and Design Notes 70 through 144.
Subjects include switching regulators, measurement
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
$20.00
notes and Linear Technology magazines.
Interface Product Handbook — This 424 page handbook features LTC’s complete line of line driver and
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 descriptions, graphs and performance specifications. Topics
covered include basic amplifiers, video-related applications 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 applications—with performance graphs and specifications.
Topics covered include ADCs, DACs, voltage references and analog multiplexers. A complete glossary
defines data conversion specifications; a list of selected 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 applications. New products introduced include high speed
amplifiers, A/D converters, power products, interface
transceivers and filters. Reference material includes a
telecommunications glossary, serial interface standards, protocol information and a complete list of key
application notes and design notes.
Available at no charge
continued on page 40
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.
35
DESIGN TOOLS, continued from page 39
CD-ROM
LinearView — LinearView™ CD-ROM version 2.0 is
Linear Technology’s latest interactive CD-ROM. It allows you to instantly access thousands of pages of
product and applications information, covering Linear
Technology’s complete line of high performance analog products, with easy-to-use search tools.
The LinearView CD-ROM includes the complete product specifications from Linear Technology’s Databook
library (Volumes I–V) and the complete Applications
Handbook collection (Volumes I–III). 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 CDROM enables you to select parts by various criteria,
such as device parameters, keywords or part numbers.
All product categories are represented: data conversion, references, amplifiers, power products, filters
and interface circuits. Up-to-date versions of Linear
Technology’s software design tools, SwitcherCAD,
Micropower 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. LinearView 2.0 runs under Windows ® 3.1,
Windows 95 and Macintosh ® System 7.0 or later.
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 products 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.
Linear Technology Corporation
1630 McCarthy Boulevard
Milpitas, CA 95035-7417
Phone: (408) 432-1900
FAX: (408) 434-0507
Linear Technology Corporation
Houston, TX 77478
Phone: (972) 733-3071
FAX: (972) 380-5138
U.S. Area
Sales Offices
Linear Technology Corporation
5510 Six Forks Road, Suite 102
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Phone: (919) 870-5106
FAX: (919) 870-8831
Linear Technology Corporation
266 Lowell St., Suite B-8
Wilmington, MA 01887
Phone: (508) 658-3881
FAX: (508) 658-2701
The site is searchable by criteria such as part numbers,
functions, topics and applications. 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.)
Acrobat is a trademark of Adobe Systems, Inc.; Windows
is a registered trademark of Microsoft Corp.; Macintosh
and AppleTalk are registered trademarks of Apple Computer, Inc. PSPICE is a trademark of MicroSim Corp.
International
Sales Offices
World Headquarters
NORTHEAST REGION
Linear Technology Corporation
3220 Tillman Drive, Suite 120
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Phone: (215) 638-9667
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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 magazine 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.
CENTRAL REGION
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FAX: (847) 925-0878
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Linear Technology Corporation
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Linear Technology Corporation
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Linear Technology Corporation
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Phone: (512) 343-3679
FAX: (512) 343-3680
©
1998 Linear Technology Corporation/Printed in U.S.A./ 41K
36
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For Literature Only: 1-800-4-LINEAR
Linear Technology Magazine • February 1998