V09N1 - FEBRUARY

LINEAR TECHNOLOGY
TECHNOLOG
TECHNOLOGY
VOLUME IX NUMBER 1
FEBRUARY 1999
IN THIS ISSUE…
COVER ARTICLE
Third-Generation DC/DC Controller
Reduces Size and Cost .................. 1
Randy G. Flatness
Issue Highlights ............................ 2
LTC® in the News ........................... 2
DESIGN FEATURES
New Universal Continuous-Time Filter
with Extended Frequency Range ... 7
Max W. Hauser
SOT-23 Switching Regulators
Deliver Low Noise Outputs
in a Small Footprint ................... 11
Steve Pietkiewicz
Versatile New Switching Regulator
Fits in SO-8 ................................. 14
Craig Varga
16-Bit Parallel DAC Has 1LSB
Linearity, Ultralow Glitch and
Accurate 4-Quadrant Resistors ... 18
Patrick Copley
Fast Rate Li-Ion Battery Charger
................................................... 24
Goran Perica
DESIGN IDEAS
No RSENSE Controller Delivers 12V and
100W at 97% Efficiency .............. 26
Christopher B. Umminger
Generating Low Cost, Low Noise,
Dual-Voltage Supplies ................. 27
Third-Generation DC/DC
Controllers Reduce
Size and Cost
Introduction
The LTC1735 and LTC1736 are the
newest members of Linear Technology’s third generation of DC/DC
controllers. These controllers use the
same constant frequency, current
mode architecture and Burst Mode™
operation as the previous generation
LTC1435–LTC1437 controllers but
with improved features. With
OPTI-LOOP™ compensation, new
protection circuitry, tighter load regulation and strong MOSFET drivers,
these controllers are ideal for the
current and future generations of CPU
power applications.
The LTC1735 is pin compatible with
the previous generation LTC1435/
LTC1435A controllers with only minor external component changes.
by Randy G. Flatness
Protection features include internal
foldback current limiting, output overvoltage crowbar and optional
short-circuit shutdown. The 0.8V ±1%
reference allows the low output voltages and 1% accuracy that will be
demanded by future microprocessors.
The operating frequency (synchronizable up to 500kHz) is set by an external
capacitor, allowing maximum flexibility in optimizing efficiency.
The LTC1736 has all of the features of the LTC1735, plus voltage
programming for CPU power, in a 24lead SSOP package. The output voltage
in LTC1736 applications is programmed by a 5-bit digital-to-analog
converter (DAC) that adjusts the outcontinued on page 3
Ajmal Godil
Switched Capacitor Voltage Regulator
Provides Current Gain ................. 28
Jeff Witt
High Current Step-Down Conversion
from Low Input Voltages ............. 30
Dave Dwelley
How to Design High Order Filters with
Stopband Notches Using the LTC1562
Operational Filter (Part 2) ........... 31
Nello Sevastopoulos
DESIGN INFORMATION
The LTC1658 and LTC1655: Smallest
Rail-to-Rail 14-Bit and 16-Bit DACs
................................................... 36
Hassan Malik
New Device Cameos ..................... 37
Design Tools ................................ 39
Sales Offices ............................... 40
Figure 1. LTC1736 evaluation circuit: a complete 5V–24V to 0.9V–2V/12A converter
in 2.15in2 of PC board space
, LTC and LT are registered trademarks of Linear Technology Corporation. Adaptive Power, Burst Mode, C-Load,
FilterCAD, Hot Swap, Linear View, Micropower SwitcherCAD, No RSENSE, Operational Filter, OPTI-LOOP, PolyPhase,
SwitcherCAD and UltraFast are trademarks of Linear Technology Corporation. Other product names may be trademarks
of the companies that manufacture the products.
EDITOR’S PAGE
Issue Highlights
Happy New Year and welcome to
the ninth volume of Linear Technology magazine.
This issue is heavy on power products: our cover article introduces the
LTC1735 and LTC1736, the newest
members of Linear Technology’s third
generation of DC/DC controllers.
These controllers use the same current mode architecture with constant
frequency and Burst Mode operation
as the LTC1435–LTC1437 controllers
but with improved features. With
OPTI-LOOP compensation, new
protection circuitry, tighter load regulation and strong MOSFET drivers,
these controllers are ideal for the current and future generations of CPU
power applications.
This issue debuts the LTC1530, a
synchronous buck regulator controller in the SO-8 package. The LTC1530
is a small, versatile controller that is
usable in numerous topologies and
over a wide range of power levels. In
basic buck applications, the LTC1530
permits the designer to realize very
simple, low parts count designs that
require minimal real estate. With a
little ingenuity, it is possible to develop circuits different than those that
the part’s designers intended, but
which give excellent performance
nonetheless.
The LT®1505 is a constant-current, constant-voltage, current mode
switching battery charger using the
synchronous buck topology. Its output voltage is preset for 3–4 Li-Ion
cells, but can be programmed from 1V
to 21V. It features a 0.5% voltage
reference, low dropout operation, programmable wall adapter current
limiting and efficiencies to 94%.
Rounding out our selection of
switchers are the LT1611 and LT1613.
These current mode, constant frequency devices contain internal 36V
switches capable of generating output power in the range of 400mW to
2W, in a 5-lead SOT-23 package. The
LT1613 has a standard positive feedback pin and is designed to regulate
positive voltages. The LT1611 has a
2
novel feedback scheme designed to
directly regulate negative output voltages without the use of level-shifting
circuitry.
In the filter arena, we premier the
LTC1562-2, an extended-frequency
version of the LTC1562 quadruple
2nd order, universal, continuous-time
filter, described in the February 1998
issue. The LTC1562 introduced
Operational Filter™ building blocks,
which satisfy diverse filter
requirements and applications
compactly. The LTC1562-2 has the
same block diagram, pinout and packaging as the original LTC1562, but is
optimized for higher filter frequencies: 20kHz to 300kHz. Besides
covering a full octave of frequencies
(150kHz–300kHz) above the range of
the LTC1562, the LTC1562-2 also
overlaps the LTC1562’s utility in the
range 20kHz to 150kHz. In this
frequency range, the LTC1562-2 typically shows reduced large-signal
distortion at a cost of slightly more
noise than with the LTC1562.
We also introduce a new data converter: the LTC1597 16-bit parallel,
current output, low glitch, multiplying
DAC. The LTC1597 has outstanding
1LSB linearity over temperature,
ultralow glitch impulse, on-chip 4quadrant feedback resistors, low power
consumption, asynchronous clear and
a versatile parallel interface. For 14bit systems, its pin compatible
counterpart, the LTC1591, is an ideal
solution. Combined with the LT1468
op amp (introduced in the November
1998 issue), the LTC1597 provides the
best in its class, 1.7µs settling time to
0.0015%, while maintaining superb
DC linearity specifications. Two railto-rail, voltage output DACs can be
found in the Design Information section: the 14-bit LTC1658 and the 16-bit
LTC1655; these DACs have a flexible
3-wire serial interface that is SPI/
QSPI and MICROWIRE™ compatible.
They provide a convenient upgrade
path for users of LTC’s 12-bit voltage
output DAC family.
MICROWIRE is a trademark of National Semiconductor Corp.
LTC in the News…
On January 12, 1999, Linear Technology announced its financial
results for the second quarter of FY
1999, reporting increased sales and
profits compared to the second
quarter of the previous year. Net
sales and net income for the quarter ended December 27, 1998, were
$120,020,000 and $45,904,000,
respectively.
Reporting the results, Linear
Technology President and CEO Robert H. Swanson said, “This quarter
proved to be stronger than we
initially expected, as the general
worldwide economic climate
improved. We grew sales and profits 3% sequentially from the
previous quarter and added $35.6
million to our cash balance. Our
return on sales is an industry
leading 38.2%.”
Prior to the announcement, Linear Technology was named a top
stock pick for 1999 in a December
17, 1998 article in USA Today. Jim
Craig, manager of the $21 billion
Janus fund and one of several
financial analysts surveyed interviewed by USA Today, listed Linear
Technology among his top picks for
the coming year.
The December 28 issue of EE
Times named Linear Technology
Staff Scientist Jim Williams one of
nineteen “Times People 98.” The
issue included a full-page profile on
Jim, emphasizing the changes he
has seen in analog design over the
past two decades.
The December 7 issues of both
Electronic News and Electronic
Buyers’ News reported Linear
Technology’s December announcement of the addition of Wyle
Electronics as an authorized
distributor.
This issue features a rich selection
of Design Ideas, including four different power conversion circuits and
the second in a series of articles on
designing high order filters with stopband notches using the LTC1562
filter ICs.
The issue concludes with six New
Device Cameos.
Linear Technology Magazine • February 1999
DESIGN FEATURES
Fault Protection:
put voltage from 0.925V to 2.00V, Overcurrent Latch-Off
LTC1735/LTC1736, continued from page 1
according to Intel mobile VID
specifications.
Details
The LTC1735 and LTC1736 are synchronous step-down switching
regulator controllers that drive external N-Channel power MOSFETs using
a programmable fixed frequency OPTILOOP architecture. OPTI-LOOP
compensation effectively removes the
constraints placed on COUT by other
controllers for proper operation (such
as limits on low ESRs). A maximum
duty cycle limit of 99% provides low
dropout operation, which extends
operating time in battery operated
systems. A forced-continuous control pin reduces noise and RF
interference and can assist secondary winding regulation by disabling
Burst Mode when the main output is
lightly loaded. Soft-start is provided
by an external capacitor that can be
used to properly sequence supplies.
The operating current level is userprogrammable via an external current
sense resistor. A wide input-supply
range allows operation from 3.5V to
30V (36V maximum).
Protection
New internal protection features in
the LTC1735 and LTC1736 controllers include foldback current limiting,
short circuit detection, short-circuit
latch-off and overvoltage protection.
These features protect the PC board,
the MOSFETs and the load itself (the
CPU) against faults.
Fault Protection: Current Limit
and Current Foldback
The LTC1735/LTC1736 current comparator has a maximum sense voltage
of 75mV, resulting in a maximum
MOSFET current of 75mV/RSENSE.
The LTC1735/LTC1736 includes current foldback to help further limit
load current when the output is
shorted to ground. If the output falls
by more than one-half, the maximum
sense voltage is progressively lowered
from 75mV to 30mV. Under shortcircuit conditions with very low duty
cycle, the LTC1735/LTC1736 will
begin cycle skipping in order to limit
the short-circuit current. In this situation, the bottom MOSFET will be on
most of the time, conducting the current. The average short-circuit current
will be approximately 30mV/ RSENSE.
Note that this function is always active
and is independent of the short circuit latch-off.
Fault Protection: Output
Overvoltage Protection (OVP)
An output overvoltage crowbar turns
on the synchronous MOSFET to blow
a system fuse in the input lead when
Table 1. Overvoltage protection comparison
Operating Condition
Soft Latch
Hard Latch
Fast Transients
Controls Overshoot
Latches Off
Output Shorted to 5V
Output Clamped at OVP
Latches Off
62.5
VID Voltage Decrease
Regulates New Voltage
Latches Off
50.0
Noise
Controls Output
Latches Off
100.0
87.5
LTC1735/
LTC1736
75.0
COSC VALUE (pF)
The RUN/SS pin, in addition to providing soft-start capability, also
provides the ability to shut off the
controller and latch off when an overcurrent condition is detected. The
RUN/SS capacitor, CSS, (refer to Figure 5) is used initially to turn on and
limit the inrush current of the controller. After the controller has been
started and given adequate time to
charge the output capacitor and provide full load current, CSS is used as
a short-circuit timer. If the output
voltage falls to less than 70% of its
nominal output voltage after CSS
reaches 4.2V, it is assumed that the
output is in a severe overcurrent
and/or short-circuit condition and
CSS begins discharging. If the condition lasts for a long enough period, as
determined by the size of CSS, the
controller will be shut down until the
RUN/SS pin voltage is recycled.
This built-in latch-off can be overridden by providing >5µ A at a
compliance of 4V to the RUN/SS pin
(refer to the LTC1735/LTC1736 Data
Sheet for details). This external current shortens the soft-start period
but also prevents net discharge of the
RUN/SS capacitor during a severe
overcurrent and/or short-circuit
condition.
Why should you defeat overcurrent latch-off? During the prototyping
stage of a design, there may be a
problem with noise pickup or poor
layout causing the protection circuit
to latch off. Defeating this feature will
allow easy troubleshooting of the circuit and PC layout. The internal
short-circuit detection and foldback
current limiting still remain active,
thereby protecting the power supply
system from failure. After the design
is complete, you can decide whether
to enable the latch-off feature.
37.5
Shorted Top MOSFET
LTC1435/
LTC1436
25.0
Output Voltage Can
Reverse
12.5
0
0
100
200
300
400
500
OPERATING FREQUENCY (kHz)
600
Figure 2. COSC value vs frequency for the
LTC1435/36 and the LTC1735/36
Linear Technology Magazine • February 1999
Bottom MOSFET Overloads Bottom MOSFET Overloads
No
When Overload is Removed Resumes Normal Operation
Troubleshooting Faults
Easy DC Measurements
Yes
Remains Latched Off
Difficult; May Require
Digital Oscilloscopes
3
DESIGN FEATURES
Table 2. FCB possible states
FCB Pin
DC Voltage:
0V–0.7V
Condition
Burst Disabled/
Forced Continuous,
Current Reversal
Enabled
DC Voltage: > 0.9V
Burst Mode, No
Current Reversal
Feedback Resistors
Regulating a
Secondary Winding
(VFCBSYNC > 1.5V)
Burst Mode
Disabled, No
Current Reversal
the output of the regulator rises much
higher than nominal levels. The crowbar can cause huge currents to flow,
greater than in normal operation. This
feature is designed to protect against
a shorted top MOSFET or short circuits to higher supply rails; it does
not protect against a failure of the
controller itself.
Previous latching crowbar schemes
for overvoltage protection have a number of problems (see Table 1). One of
the most obvious, not to mention
most annoying, is nuisance trips
caused by noise or transients
momentarily exceeding the OVP
threshold. Each time that this occurs
with latching OVP, a manual reset is
required to restart the regulator. Far
more subtle is the resulting output
voltage reversal. When the synchronous MOSFET latches on, a large
reverse current is loaded into the
inductor while the output capacitor is
discharging. When the output voltage
reaches zero, it does not stop there,
but rather continues to go negative
until the reverse inductor current is
100%
90%
BURST
EFFICIENCY (%)
80%
70%
60%
SYNC
50%
CONTINUOUS
40%
30%
20%
0.001
0.01
0.1
1.0
LOAD CURRENT (A)
10.0
Figure 3. Efficiency vs load current for three
modes of operation
4
depleted. This requires a sizable
Schottky diode across the output to
prevent excessive negative voltage on
the output capacitor and load.
A further problem on the horizon
for latching OVP circuits is their
incompatibility with on-the-fly CPU
core voltage changes. If an output
voltage is reprogrammed from a higher
voltage to a lower voltage, the OVP
will temporarily indicate a fault, since
the output capacitor will momentarily
hold the previous, higher output voltage. With latching OVP, the result will
be another latch-off, with a manual
reset required to attain the new output voltage. To prevent this problem,
the OVP threshold must be set above
the maximum programmable output
voltage, which would do little good
when the output voltage was programmed near the bottom of its range.
In order to avoid these problems
with traditional latching OVP circuits,
the LTC1735 and LTC1736 use a new
“soft latch” OVP circuit. Regardless of
operating mode, the synchronous
MOSFET is forced on whenever the
output voltage exceeds the regulation
point by more than 7.5%. However, if
the voltage then returns to a safe
level, normal operation is allowed to
resume, thereby preventing latch-off
caused by noise or voltage reprogramming. Only in the case of a true
fault, such as a shorted top MOSFET,
will the synchronous MOSFET remain
latched on until the input voltage
collapses or the system fuse blows.
The new soft latch OVP also provides protection and easy diagnosis
of other overvoltage faults, such as a
lower supply rail shorted to a higher
voltage. In this scenario, the output
voltage of the higher regulator is pulled
down to the OVP voltage of the
soft-latched regulator, allowing the
problem to be easily diagnosed with
DC measurements. On the other
hand, latching OVP provides only a
millisecond glimpse of the fault as it
latches off, forcing the use of expensive
digital oscilloscopes for troubleshooting.
Three Operating Modes/One
Pin: Sync, Burst Disable and
Secondary Regulation
The FCB pin is a multifunction pin
that controls the operation of the
synchronous MOSFET and is an input
for external clock synchronization.
When the FCB pin drops below its
0.8V threshold, continuous mode
operation is forced. In this case, the
top and bottom MOSFETs continue
to be driven synchronously regardless of the load on the main output.
Burst Mode operation is disabled and
current reversal is allowed in the
inductor.
In addition to providing a logic
input to force continuous synchronous operation and external
Table 3. Comparison of LTC1735/36 controllers with LTC1435A/36A-PLL controllers
Parameter
LTC1735/1736
LTC1435A/1436A-PLL
Reference
0.8V
1.19V
Load Regulation
0.1% Typ, 0.2% Max
0.5% Typ 0.8% Max
Max Current Sense
75mV
150mV
Minimum On-Time
200ns
300ns
Synchronizable
Yes
LTC1436A-PLL Only
Int VCC Voltage
5.2V (7V Max)
5V (10V Max)
Power Good Output
LTC1736 Only
LTC1436A/36A-PLL Only
Current Foldback
Internal
External
Output OV Protection
Yes
No
Output OI Latch-Off
Optional
No
Packages
SO16, GN16/G24
SO16, G16/GN24
MOSFET Drivers
3×
1×
Linear Technology Magazine • February 1999
DESIGN FEATURES
30
no external connections are made,
the FCB pin is pulled high by a 0.25µA
internal current source.
The LTC1735 internal oscillator
can be synchronized to an external
oscillator by applying a clock signal of
at least 1.5VP-P to the FCB pin. When
synchronized to an external frequency, Burst Mode operation is
disabled but cycle skipping occurs at
low load currents since current
reversal is inhibited. The bottom gate
will come on every 10 clock cycles to
ensure that the bootstrap cap is kept
refreshed and to keep the frequency
above the audio range. The rising
edge of an external clock applied to
the FCB pin starts a new cycle.
The range of synchronization is
from 0.9 × fO to 1.3 × fO, with fO set by
COSC. Attempting to synchronize to a
higher frequency than 1.3 × fO can
result in inadequate slope compensation and cause loop instability with
high duty cycles. If loop instability is
observed while synchronized, additional slope compensation can be
obtained by simply decreasing COSC.
A plot of operating frequency versus
COSC value is shown in Figure 2.
Table 2 summarizes the possible
states available on the FCB pin.
Figure 3 gives a comparison of efficiencies in a regulator for the three
operating modes: forced continuous
operation, pulse skipping mode (synchronized at f = fO) and Burst Mode
operation.
B4
B3
B2
B1
B0
VOUT (V)
0
0
0
0
0
2.000V
0
0
0
0
1
1.950V
0
0
0
1
0
1.900V
0
0
0
1
1
1.850V
0
0
1
0
0
1.800V
0
0
1
0
1
1.750V
0
0
1
1
0
1.700V
0
0
1
1
1
1.650V
0
1
0
0
0
1.600V
0
1
0
0
1
1.550V
0
1
0
1
0
1.500V
0
1
0
1
1
1.450V
0
1
1
0
0
1.400V
0
1
1
0
1
1.350V
0
1
1
1
0
1.300V
0
1
1
1
1
*
1
0
0
0
0
1.275V
1
0
0
0
1
1.250V
1
0
0
1
0
1.225V
1
0
0
1
1
1.200V
1
0
1
0
0
1.175V
1
0
1
0
1
1.150V
1
0
1
1
0
1.125V
1
0
1
1
1
1.100V
1
1
0
0
0
1.075V
1
1
0
0
1
1.050V
1
1
0
1
0
1.025V
1
1
0
1
1
1.000V
1
1
1
0
0
0.975V
OFF
1
1
1
0
1
0.950V
ON
1
1
1
1
0
0.925V
1
1
1
1
1
**
Note: *, ** represent codes without a defined
output voltage as specified in Intel specifications.
The LTC1736 interprets these codes as a valid
inputs and produces output voltage as follows:
[01111]=1.250V, [11111]=0.900V.
synchronization, the FCB pin provides a means to regulate a flyback
winding output. It can force continuous synchronous operation when
needed by the flyback winding,
regardless of the primary output load.
In order to prevent erratic operation if
Linear Technology Magazine • February 1999
JP1
BURST MODE
10
5
200
1
2
3
330pF
4
100pF
5
6
CS1, 1000pF
7
8
RUN/SS
FCB
SGND
400
TG
BOOST
600
The LTC1735 is pin compatible with
the LTC1435/LTC1435A, with minor
component changes. Table 3 shows
the differences between the two controllers. The important items to note
are:
1. The LTC1735 has a 0.8V reference (versus 1.19V for the
LTC1435) that allows lower
output voltage operation (down to
0.8V). Thus, the output feedback
divider will have to be recalculated for the same output voltage.
2. The LTC1735’s maximum
current sense voltage is half that
of the LTC1435. This reduces the
power lost in the sense resistor
by half. Hence, for the same
maximum output current, the
current sense resistor must be
cut in half.
+
16
15
VIN
INT VCC
BG
SENSE–
PGND
SENSE+
EXT VCC
M2
FDS6680A
0.22µF
14
CB1
13
D1
CMDSH-3
SW
VOSENSE
12
11
+
C4
1µF
10
9
C2
4.7µF
M1
FDS6680A
CIN1 CIN3
22µF 22µF
30V 30V
L1†
+
RCS1
0.005Ω
VOUT
1.6V/9A
2µH
C3
47pF
D2
MBRS340T3
EXT VCC
R5 10Ω
RS1
10Ω
R7
10k
1%
R3
10k
1%
R2 10Ω
†PANASONIC ETQP6F2R0HFA
*SANYO OSCON 4SP820M
500
Converting to the LTC1735
RF1
4.7Ω
CF1
0.1µF
COSC LTC1735
ITH
300
Figure 4. MOSFET gate-charge current vs
frequency
R6, 1M
0.1µF
RC1 33k
C1
47pF
15
+VIN
JP2
LATCH-OFF
(DISABLED)
COSC1
47pF
CC2
20
FREQUENCY (kHz)
RUN
CSS
TOP AND BOTTOM MOSFETS
= FAIRCHILD NDS6680A
25
0
100
FCB/SYNC
INT VCC
CC1
GATE-CHARGE CURRENT (mA)
Table 4. VID output voltage programming
(201) 348-7522
(619) 661-6835
VO
CO1
180µF
4V
+
CO3*
820µF
4V
GND
Figure 5. High efficiency 1.6V/9A CPU power supply
5
DESIGN FEATURES
Linear Current
Comparator Operation
3. The gate drivers of the LTC1735
are 3× the strength of those in
the LTC1435. This equates to
faster rise and fall times for
driving the same MOSFETs plus
the capability to drive larger
MOSFETs with less efficiency
loss due to transition losses.
Since the trend in the marketplace
has forced output voltages to lower
and lower values, the current sense
inputs have been optimized for low
voltage operation. The current sense
comparator has a linear response
characteristic, without discontinuities, from 0V to 6V output
voltages. In the LTC1435/LTC1435A,
two input stages are used to cover
this range, so an overlap exists
together with a transition region. The
LTC1735/LTC1736 uses only one
input stage and includes slope compensation that operates over the full
output voltage range. This allows the
LTC1735/LTC1736 to be operated in
grounded RSENSE applications as well.
Speed
The LTC1735/LTC1736 are designed
to be used in higher current applications than the LTC1435 family.
Stronger gate drives allow paralleling
multiple MOSFETs or higher operating frequencies. The LTC1735 has
been optimized for low output voltage
operation by reducing the minimum
on-time to less than 200ns. Remember, though, that transition losses
can still impose significant efficiency
penalties at high input voltages and
high frequencies. Just because the
LTC1735 can operate at frequencies
above 300kHz doesn’t mean it should.
Figure 4 shows a plot of MOSFET
charge current versus frequency.
LTC1736 Additional Features
The LTC1736 includes all the features of the LTC1735, plus 5-bit
mobile VID control and a power-good
comparator in a 24-lead SSOP package. The window comparator monitors
the output voltage and its open-drain
output is pulled low when the divided
Pentium is a registered trademark of Intel Corp.
JP1
BURST MODE
FCB/SYNC
OFF
JP2
LATCH-OFF
(DISABLED)
ON
INT VCC
COSC1
47pF
RC1 33k
CC1
330pF
CC2
100pF
1
3
4
5
6
PGOOD
INT VCC
CS1, 1000pF
C1
47pF
7
8
9
10
C3
47pF
CF1
0.1µF
RF1
4.7Ω
+
R6, 680k
2
R1
100k
+VIN
RUN
11
12
24
COSC LTC1736
TG
BOOST
RUN/SS
ITH
SW
FCB
VIN
INT VCC
SGND
PGOOD
BG
SENSE–
PGND
SENSE+
EXT VCC
VFB
VID VCC
21
D1
CMDSH-3
20
+
C4
1µF
18
VOSENSE
B4
B0
B3
B1
B2
Figure 5 shows a 1.6V/9A application using the LTC1735. The input
voltage can range from 6V to 26V.
Figure 6 shows a VID application
using the LTC1736 optimized for output voltages of 1.6V to 1.3V with a 5V
to 24V input voltage range.
continued on page 35
L1†
1.2µH
RCS1
0.004Ω
D2 MBRS340T3
C2
4.7µF
16
15
Applications
CB1 0.22µF
22
17
+
M2
FDS6680A
23
19
CIN1 CIN3
22µF 22µF
30V
30V
voltage is not within ±7.5% of the 0.8V
reference voltage.
The output voltage is digitally set
to levels between 0.925V and 2.00V
using the voltage identification (VID)
inputs B0–B4. The internal 5-bit DAC
configured as a precision resistive
voltage divider sets the output voltage in 50mV or 25mV increments
according to Table 4. The VID codes
(00000–11110) are compatible with
the Intel mobile Pentium® II processor. The LSB (B0) represents 50mV
increments in the upper voltage range
(2.00V–1.30V) and 25mV increments
in the lower voltage range (1.275V–
0.925V). The MSB is B4. When all bits
are low or grounded, the output voltage is 2.00V.
The LTC1736 also has remote sense
capability. The top of the internal
resistive divider is connected to
VOSENSE and is referenced to the SGND
pin. This allows a Kelvin connection
for remotely sensing the output voltage
directly across the load, eliminating
any PC board trace resistance errors.
EXT VCC
VOUT
0.9V–2.0V
/12A
RS1
10Ω
VO
M1, M3
FDS6680A
×2
14
+
CO3*
820µF
4V
13
MSB
LSB
JP4
E
D
C
B
A
R5 10Ω
R2 10Ω
†PANASONIC ETQP6F2R0HFA
*PANASONIC EEFVEOG181R
(201) 348-7522
Authors can be contacted
at (408) 432-1900
Figure 6. High efficiency, VID programmable, 0.9V–2.0V/12A CPU power supply
6
Linear Technology Magazine • February 1999
DESIGN FEATURES
New Universal Continuous-Time Filter
with Extended Frequency Range
by Max W. Hauser
Introduction
The original LTC1562, described in
the February 1998 issue of this magazine, is a compact, quadruple 2nd
order, universal, continuous-time filter that is DC accurate and user
programmable for the 10kHz–150kHz
frequency range. The LTC1562 introduced Operational Filter building
blocks, whose virtual-ground input,
rail-to-rail outputs and precision
internal R and C components satisfy
diverse filter requirements and applications compactly.1, 2, 3
The design of the LTC1562 entailed
choices in the internal R and C values
and internal amplifiers, and these
elements were optimized to minimize
wideband noise. The LTC1562-2 is a
new product with the same block
diagram, pinout and packaging, but
optimized for higher filter frequencies: 20kHz to 300kHz. The internal
precision R and C components and
amplifiers are different in the
LTC1562-2. Besides covering a full
octave of frequencies (150kHz–
300kHz) above the range of the
LTC1562, the LTC1562-2 also overlaps the LTC1562’s utility in the range
20kHz to 150kHz. In this frequency
range, the LTC1562-2 typically shows
reduced large-signal distortion at a
cost of slightly more noise than with
the LTC1562. For example, a 100kHz
dual 4th order Butterworth lowpass
filter with a ±5V supply, built with the
LTC1562-2 and lightly loaded, exhibited 2nd-harmonic distortion of
–103dB and 3rd-harmonic distortion
of –112dB at 20kHz with an output of
1VRMS (2.8VP-P), and maintained low
distortion even with output swings
approaching the full supply voltage
(–83dB total harmonic distortion, or
THD, at 9.7VP-P output).
The LTC1562-2 is, therefore, the
product of choice for applications
above 150kHz as well as for applications in the 20kHz–150kHz range that
are especially distortion sensitive.
Both the LTC1562 and the LTC1562-2
can replace LC filters or filters built
from high performance op amps and
precision capacitors and resistors,
with a total surface mount board area
of 155mm2 (0.24in2)—smaller than a
dime (the smallest US coin).
Comparison to the LTC1562
The LTC1562-2 both resembles and
differs from the LTC1562 as follows:
❏ The parts have identical pin
configurations and block
diagrams (four independently
programmable 2nd order
Operational Filter blocks with
virtual-ground inputs and rail-torail outputs).
❏ In both products, the user can
program the filter’s centerfrequency parameter (f0) over a
wide range, using resistor values
that vary as the desired f0
changes up or down from a
design-center value. In the
LTC1562, this design-center f0 is
100kHz; for the LTC1562-2, the
value is 200kHz.
❏ The LTC1562 is optimized for
lower noise, the LTC1562-2 for
higher frequencies. Thus, a
single LTC1562 section can
deliver 103dB SNR in 200kHz
bandwidth (Q = 1), whereas a
single LTC1562-2 section
supports 99dB SNR in 400kHz.
*R1 AND C ARE PRECISION
INTERNAL COMPONENTS
1
sR1C*
INV
V+
V1
V2
INV
V1
C
V2
–
V+
SHUTDOWN
SWITCH
V–
A
B
+
2ND ORDER SECTIONS
V2
INV
SHUTDOWN
SWITCH
SHDN
AGND
D
C
+
–
V1
V2
INV
V1
Linear Technology Magazine • February 1999
VIN
V2
1562 F02
Figure 1. LTC1562-2 block diagram
1562 F01
ZIN
V–
INV
V1
RQ
R2
Figure 2. Single 2nd order Operational Filter section (inside
dashed line) with external components added: resistor for
ZIN gives lowpass at V2, bandpass at V1; capacitor for ZIN
gives bandpass at V2, highpass at V1.
7
DESIGN FEATURES
❏ Each chip contains precision R
and C components equivalent to
eight 0.25% tolerance capacitors
and four 0.5% tolerance
resistors, as well as twelve op
amps with rail-to-rail outputs
and excellent high frequency
linearity.
❏ Both circuits operate from
nominal 5V to 10V total supplies
(single or split). Single-supply
applications can use a halfsupply, ground-reference voltage
generated on the chip.
❏ Both chips feature a power-down
mode that drops the power
supply current to zero, except for
reverse junction leakages (on the
order of 1µA total).
What the LTC1562-2 Can Do
Figure 1 is an overall diagram and
Figure 2 a per-section diagram for the
LTC1562-2. These are identical to the
diagrams for the LTC1562, except for
the values of the internal precision
components in Figure 2. In the
LTC1562-2, R1 is 7958Ω and C is
100pF. External resistors can be combined with an LTC1562-2 section, as
shown in Figure 2, to define a second
order filter response with standardized parameters f0, Q and gain. Design
equations and procedures appear in
the LTC1562-2 data sheet. For
example, in Figure 2, R2 sets f0; RQ, a
multiple of R2, sets Q; and ZIN sets
both the gain and the block’s function. The 3-terminal blocks minimize
the number of external parts necessary for complete 2nd order sections
with programmable f0, Q and gain.
A resistor for ZIN in Figure 2 gives
simultaneous lowpass (at V3) and
bandpass (at V1) responses. The data
sheet describes other ways to exploit
the virtual ground INV input. For
example, because the V1 output in
Figure 2 shows a phase shift of 180°
at the user-set center frequency, f0,
summing a V1 output with a feedforward path from the signal source
yields a notch response,2 or with different weighting, allpass (phase
equalization), as used in Figure 5
8
RIN2 7.87k
VIN1
1
RIN1 7.87k RQ1 4.22k
R21 7.87k
5V
3
INV C
V1 B
V1 C
V2 B
V2 C
0.1µF
RIN3 7.87k
19
RQ2 10.2k
18
R22 7.87k
V+ LTC1562-2
20-PIN
15
SHDN SSOP AGND
13 R24 7.87k
8
V2 A
V2 D
12 RQ4 10.2k
9
V1 A
V1 D
11
10
INV A
INV D
6
R23 7.87k
VOUT1
20
16
V–
5
RQ3 4.22k
VIN2
2
INV B
–5V*
0.1µF
VOUT2
RIN4 7.87k
*V– ALSO AT PINS 4, 7, 14 & 17
ALL RESISTORS 1% METAL FILM
Figure 3. Dual 4th order 200kHz Butterworth lowpass filter
later in this article. Using capacitors
together with the INV input’s summing capability provides further
powerful techniques for zero and
notch responses (which, in turn,
enable elliptic highpass and lowpass
filtering). For example, the two outputs of each 2nd order section have a
90° phase difference, so summing V1
through a capacitor and V2 through a
resistor, into another section’s virtual-ground input, gives the same
notch or allpass option mentioned
above but without devoting an additional section for phase shift.4 Figures
5 and 9, described later, use this RC
notch method. Moreover, a capacitor
for ZIN in Figure 2 yields simultaneous highpass and bandpass
responses; the capacitor sets voltage
gain, not critical frequencies, with a
relationship of the form Gain = CIN/
100pF in the LTC1562-2. Low level
signals can exploit the built-in gain
capability, which raises filter SNR
with low input voltage amplitudes.
Such abilities to tailor the use of each
block and its built-in time constants
are reminiscent of an operational
amplifier—whence the term “operational filter.”
DC performance includes a typical
lowpass input-to-output offset of 3mV
and outputs that swing (under load)
to within approximately 100mV of
each supply rail. An internal halfsupply reference point (the AGND pin)
generates a reference voltage for the
inputs and outputs in single-supply
applications. The shutdown (SHDN)
pin accepts CMOS logic levels and in
20µ s puts the LTC1562-2 into a
“sleep” mode, in which the chip consumes approximately 1µA (the part
will default to this state if the pin is
left open). The 16-pin dies is packaged in a 20-pin SSOP (the extra pins
in the SSOP are substrate connections, to be returned to the negative
supply for best performance).
The following application examples
are tailored for specific corner frequencies, which can be modified by
properly scaling the external components, as described in the data
sheet and in LTC1562 application
articles.2, 3 Expert application assistance can be obtained by calling us at
408-954-8400, x3761. Pin numbers
in the figures that follow are for the
20-pin SSOP package, where pins 4,
7, 14 and 17 (not shown) are always
tied to the negative power supply rail.
As with other filters, achieving low
noise and distortion levels requires
electrically clean construction (as well
as equipment that can measure such
performance).
Dual 4th Order 200kHz
Butterworth Lowpass Filter
Each half of the circuit in Figure 3
provides a classic 4th order lowpass
gain roll-off (24dB per octave) with a
maximally flat passband. This schematic
includes power supply connections for a
split ±5V supply, one of the options
available for any L TC1562-2
Linear Technology Magazine • February 1999
DESIGN FEATURES
10
RFF1 6.19k
VIN
0
RB1 1.54k
RIN1
7.5k
–10
GAIN (dB)
–20
1
RQ1 3.24k
–30
R21 6.81k
–40
–50
5V
–70
RQ3 7.32k
1.5M
100k
INV B
INV C
V1 B
V1 C
V2 B
V2 C
20
19
RQ2 4.12k
18
R22 6.19k
16*
LTC1562-2 V–
20-PIN
15
SHDN SSOP AGND
13 R24 4.12k
8
V2 A
V2 D
12 RQ4 7.32k
9
V1 A
V1 D
11
10
INV A
INV D
V+
6
R23 4.12k
50k
3
5
0.1µF
–60
–80
2
1µF
FREQUENCY (Hz)
Figure 4. Frequency response of one of the
two filters in Figure 3
application (Figure 5, in a different
application, illustrates connections
for a single 5V supply). The circuit of
Figure 3 is a higher frequency variation of a 100kHz dual 4th order
Butterworth lowpass filter using the
LTC1562, which appeared in the
February 1998 Linear Technology
magazine,1 as well as in the LTC1562
data sheet. Figure 4 shows the measured frequency response for one of
the two filters in Figure 3. This ±5V
circuit supports rail-to-rail inputs and
outputs, with output noise of
approximately 60µVRMS, for a maximum SNR of 95dB (compared to
100dB with the LTC1562 equivalent
at half as much bandwidth). THD in a
1VRMS output (2.8VP-P) was measured
as –87dB at 50kHz and –72dB at
100kHz.
256kHz Phase-Linearized
6th Order Lowpass Filter
Data communication and some signal antialiasing and reconstruction
applications demand filters with controlled phase (or time-domain)
CIN4
22pF 5%
*V– ALSO AT PINS 4, 7, 14 & 17
ALL RESISTORS 1% METAL FILM
Figure 5. 256kHz linear-phase 6th order lowpass filter
responses. The circuit in Figure 5
realizes a root-raised-cosine lowpass
gain response (Figure 6). For data
communications, this filter’s timedomain pulse response (Figure 7)
approximates, in continuous time, the
ideal Nyquist-type property of crossing zero at a time interval that is
equal to 1/(2fC). When used as a
pulse-shaping filter, this response has
the special property of producing minimal intersymbol interference (ISI)
among successive data pulses at a
data rate of 2fC (512 kbits/second or
ksymbols/second for Figure 5) while
simultaneously limiting the transmitted spectrum to a bandwidth
approaching the theoretical minimum, which is fC.5 Also, data or signal
acquisition (before A/D conversion)
or reconstruction (after D/A conversion) can benefit from the linear-phase
(that is, constant-group-delay)
response (typically ±300ns group
delay variation over the passband from
0 to fC, evident in Figure 8).
The filter in Figure 5 achieves these
properties by preceding a 6th order
lowpass section (the C, A, and D quarters of the LTC1562-2 chip, in that
sequence) with a 2nd order allpass
response to linearize the phase. This
combination illustrates two practical
uses of the virtual-ground inputs in
the LTC1562-2. Combining two feedforward paths (RFF1 from the input
and RB1 from a bandpass section in
the “B” quarter of the LTC1562-2)
yields the allpass equalization. Subsequently, RIN4 and CIN4 sum together
two signals with 90° phase difference
from the two outputs of the “A” quarter, with an additional 90° phase
difference caused by the capacitor, to
achieve a stopband notch at a desired
frequency.4 Figure 5 operates from a
single supply voltage from 5V to 10V
(the AGND pin furnishes a built-in
10
8
0
7
INPUT
1V/DIV
–10
6
DELAY (µs)
–20
GAIN (dB)
VOUT
RIN4 4.12k
RIN3
4.12k
–30
–40
OUTPUT
(INVERTED)
200mV/DIV
–50
5
4
3
2
–60
1
–70
0
–80
10k
100k
FREQUENCY (Hz)
1M
Figure 6. Gain response of Figure 5’s circuit
Linear Technology Magazine • February 1999
1.953µs/DIV (= 1/512kHz)
50
100
150
200
250
300
350
400
FREQUENCY (kHz)
Figure 7. Time-domain response of Figure 5’s
circuit
Figure 8. Group delay response of Figure 5’s
circuit
9
DESIGN FEATURES
10
CIN2 82pF
0
RIN2 20.5k
CIN3 47pF
–10
VIN
1
RQ1 9.09k
2
R21 7.15k
5V
3
R23 11.3k
RQ3 59k
INV C
V1 B
V1 C
V2 B
V2 C
20
RIN3 45.3k
19
RQ2 26.7k
18
R22 10k
–30
–40
–50
–60
LTC1562-2 V– 16
20-PIN
15
6
SHDN SSOP AGND
13
8
V2 A
V2 D
12
9
V1 A
V1 D
11
10
INV A
INV D
5
0.1µF
INV B
GAIN (dB)
–20
CIN1 220pF
V+
–70
–5V*
0.1µF
–80
R24 4.02k
–90
50k
RQ4 3.24k
VOUT
RIN4 40.2k
200k
FREQUENCY (Hz)
900k
Figure 10. Frequency response of Figure 9’s
circuit
CIN4 100pF
*V– ALSO AT PINS 4, 7, 14 AND 17
ALL RESISTORS 1% METAL FILM
ALL CAPACITORS 5% STANDARD VALUES
Figure 9. 175kHz 8th order elliptic highpass filter
half-supply ground reference) and
exhibits –80dB THD at 50kHz for a
500mVRMS output with a 5V supply.
175kHz 8th Order
Elliptic Highpass Filter
In Figure 9, three response notches
below the cutoff frequency suppress
the stopband and permit a narrow
transition band in a 175kHz highpass filter, whose measured frequency
response appears in Figure 10. Each
notch is produced by summing two
180°-different currents into a virtualground “INV” summing input, one
current passing through an RIN and
the other (from a voltage 90° different
RIN2A
1.43k
C1
1000pF
5%
RQ1 6.19k
2
R21 2k
3
RQ3 6.19k
VIN2
INV B
INV C
V1 B
V1 C
V2 B
V2 C
V+
6
R23 2k
RIN3A
1.43k
RIN2B
576Ω
RIN3B
576Ω
C3
1000pF
5%
continued on page 35
VOUT1
20
19
RQ2 2.26k
18
R22 2k
16
LTC1562-2 V–
20-PIN
15
SHDN SSOP AGND
R24 2k
13
8
V2 A
V2 D
12 RQ4 2.26k
9
V1 A
V1 D
11
10
INV A
INV D
5
0.1µF
Although it is outside the 300kHz f0
limit recommended for best accuracy,
this dual 6th order 400kHz Butterworth lowpass filter (Figure 11)
illustrates an extreme of bandwidth
available from the LTC1562-2 with
some compromises. The high f 0
requires unusually small resistor val-
10
0
RIN4B
576Ω
–30
–50
–60
C4
1000pF
5%
*V– ALSO AT PINS 4, 7, 14 & 17
ALL RESISTORS 1% METAL FILM
Figure 11. 400kHz dual 6th order Butterworth lowpass filter
10
–20
–40
VOUT2
RIN4A
1.43k
–10
–5V*
0.1µF
GAIN (dB)
RIN1B
576Ω
1
5V
400kHz Dual
6th Order Lowpass Filter
C2
1000pF
5%
VIN1
RIN1A
1.43k
from the first) through a CIN.4 This
circuit exhibits only 44µVRMS of output noise over a 1MHz bandwidth and
THD of –70dB with a 200kHz signal,
0.5VP-P output, operating from a 5V
total supply.
ues, resulting in heavier loading and
an increase in distortion from the
LTC1562-2; it was also necessary to
adjust the RQ resistors in Figure 11
downwards to correct for Q enhancement encountered when the designed
f0 is very high.
The circuit of Figure 11 supplements the eight poles of filtering in
the LTC1562-2 by driving all four of
the virtual-ground INV inputs from
R-C-R “T” networks (in place of resistors) and thus obtaining additional
real poles (a method described in the
original LTC1562 application article1
and data sheet). Two such real poles
replace the Q = 0.518 pole pair of a
conventional 6th order Butterworth
pole configuration, to good accuracy.
The measured frequency response of
one 6th order section appears in Figure 12. With ±5V power, this circuit
permits rail-to-rail inputs and outputs and exhibits THD, at 1VRMS
(2.8VP-P) output, of –92dB at 50kHz
and –79dB at 100kHz. Output noise
1M
100k
FREQUENCY (Hz)
Figure 12. Frequency response of
Figure 11’s circuit
Linear Technology Magazine • February 1999
DESIGN FEATURES
SOT-23 Switching Regulators Deliver
Low Noise Outputs in a Small Footprint
by Steve Pietkiewicz
Introduction
L1
4.7µH
100
90
EFFICIENCY (%)
As portable electronics designers continue to press for reduction in
component sizes, Linear Technology
introduces the LT1611 and LT1613
SOT-23 switching regulators. These
current mode, constant frequency
devices contain internal 36V switches
capable of generating output power
in the range of 400mW to 2W, in a 5lead SOT-23 package. The LT1613
has a standard positive feedback pin
and is designed to regulate positive
voltages. The LT1611 has a novel
feedback scheme designed to directly
regulate negative output voltages
without the use of level-shifting circuitry. Boost, single-ended primary
inductance converters (SEPIC) and
inverting configurations are possible
with the LT1613 and LT1611. The
high voltage switch allows hard-todo, yet popular DC/DC converter
functions like four cells to 5V, 5V to
–5V, 5V to –15V or 5V to 15V to be
easily realized.
Both devices switch at a frequency
of 1.4MHz, allowing the use of tiny
inductors and capacitors. Many of
the components specified for use with
the LT1613 and LT1611 are 2mm or
less in height, providing a low profile
solution. The input voltage range is
1V to 10V, with 2mA quiescent
current. In shutdown mode, the quiescent current drops to 0.5µA. The
VIN
C1
15µF
SHDN
VIN = 2.8V
VIN = 1.5V
50
0
50
100 150 200 250 300 350 400
LOAD CURRENT (mA)
TA01a
Figure 2. Efficiency of Figure 1’s1613boost
converter
constant frequency switching produces low amplitude output ripple
that is easy to filter, unlike the low
frequency ripple typical of pulseskipping or PFM type converters.
Internally compensated current mode
control provides good transient
response.
LT1613 Boost Converter
Provides a 5V Output
Figure 1’s circuit details a boost converter that delivers 5V at 200mA from
a 3.3V input. The input can range
from 1.5V to 4.5V, making the circuit
usable from a variety of input sources,
such as a 2- or 3-cell battery, single
Li-Ion cell or 3.3V supply. Efficiency,
shown in Figure 2, reaches 88% from
a 4.2V input. Start-up waveforms from
a 3.3V input into a 47Ω load are
LT1613 5V to 15V
Boost Converter
By changing the value of the resistive
divider, a 15V supply can be generated in a similar manner to the 5V
converter shown in Figure 1. Figure 4
depicts the converter. L1’s value has
been changed to 10µH to provide the
same di/dt slope with a higher input
voltage. The converter delivers 15V at
60mA from a 5V input, at efficiencies
up to 85%, as shown in the efficiency
graph of Figure 5.
LT1613 4-Cell to 5V SEPIC
A 4-cell battery presents a unique
challenge to the DC/DC converter
designer. A fresh battery measures
about 6.5V, above the 5V output,
while at end of life the battery voltage
will measure 3.5V, below the 5V output. Simple switching regulator
topologies like boost or buck can only
increase or decrease an input voltage,
VOUT
5V/200mA
R1
374k
LT1613
+
C2
15µF
VOUT
1V/DIV
FB
GND
L1: MURATA LQH3C4R7M24
OR SUMIDA CD43-4R7
C1, C2: AVX TAJA156M010R
D1: MOTOROLA MBR0520
VIN = 3.5V
70
D1
SW
SHDN
80
60
VIN
3.3V
+
VIN = 4.2V
pictured in Figure 3; the converter
reaches regulation in approximately
250µs. The device requires some bulk
capacitance due to the internal compensation network used. A 10µ F
ceramic output capacitor can be used
with the addition of a phase-lead
capacitor paralleled with R1; this
capacitor is typically in the 10pF–
100pF range.
R2
121k
(814) 237-1431
(847) 956-0666
(803) 946-0362
(800) 441-2447
IL1
500mA/DIV
1613 • TA01
Figure 1. This boost converter steps up a 1.5V to 4.2V input to 5V.
It can deliver 250mA from a 3.3V input.
Linear Technology Magazine • February 1999
SHDN
5V/DIV
100µs/DIV
Figure 3. Boost converter start-up with 3.3V input into a 50Ω load
11
DESIGN FEATURES
L1
10µH
+
VOUT
15V/50mA
VIN
C1
15µF
SHDN
R1
1.37M
1% +
SW
LT1613
SHDN
1nF
L1: MURATA LQH3C100
C1: AVX TAJB226M016
C2: AVX TAJA475M025
D1: MOTOROLA MBR0520
EFFICIENCY (%)
SW
1M
SHDN
(800) 441-2447
70
65
60
1613 • TA01
(800) 441-2447
Figure 6. This single-ended primary inductance converter (SEPIC)
generates 5V from an input voltage above or below 5V.
200µs, with a maximum perturbation under 200mV. The double trace
of VOUT under load in Figure 8 is
actually switching ripple at 1.4MHz
caused by the ESR of output capacitor C2. A better (lower ESR) output
capacitor will decrease the output
ripple.
85
80
VIN = 6.5V
75
70
VIN = 3.6V
65
VIN = 5V
60
55
50
0
10 20 30 40 50 60 70 80 90 100
LOAD CURRENT (mA)
1611 TA02
Figure 5. Efficiency of Figure 4’s circuit
which will not do the trick in this
situation. The solution is a SEPIC. A
dual-winding inductor or two separate inductors are required to make
this converter. Figure 6 details the
circuit. A Sumida CLS62-150 15µH
dual inductor is specified in the application, although two 15µH units can
be used instead. Up to 125mA can be
generated from a 3.6V input. Figure
7’s graph shows converter efficiency,
which peaks at 77%. Transient
response with a 5mA to 105mA load
step is pictured in Figure 8. The converter settles to final value inside
LT1611 5V to –5V
Inverting Converter
50
0
A low noise –5V output can be generated using an inverting topology with
the LT1611. This circuit, shown in
Figure 9, bears some similarity to the
SEPIC described above, but the output is in series with the second
inductor. This results in a very low
noise output. The circuit can deliver
–5V at up to 150mA from a 5V input,
or up to 100mA from a 3V input.
Efficiency, described in Figure 10,
peaks at 75%. Figure 11 illustrates
the start-up waveforms. During startup, the switch-current increases to
approximately 1A. At this current,
the inductance of the Sumida unit
decreases, resulting in the increased
VOUT
100mV/DIV
AC COUPLED
1611 TA02
ripple current noticeable in the switchcurrent trace of Figure 11. After the
circuit has reached regulation, the
ripple current decreases by about a
factor of two. Switching waveforms
with a 100mA load are shown in Figure 12. Output voltage ripple is caused
by ripple current in the inductor multiplied by output capacitor ESR.
Although the 20mVP-P ripple pictured in Figure 12 is low, significant
improvement can be obtained by
judicious component selection. Figure 13 details the same 5 to –5V
C3
0.22µF
L1A
22µH
+
VIN
C1
22µF
SHDN
25 50 75 100 125 150 175 200 225 250
LOAD CURRENT (mA)
Figure 7. Efficiency of Figure 6’s SEPIC
reaches 77%.
VIN
5V
L1B
22µH
SW
D1
LT1611
29.4k
SHDN
VOUT
–5V/150mA
NFB
GND
10k
+
105mA
5mA
200µs/DIV
Figure 8. SEPIC transient response at 5V input with a 5mA to 105mA
load step
12
C2
15µF
(847) 956-0666
(803) 946-0362
55
ILOAD
VOUT
5V/175mA
+
324k
L1: SUMIDA CLS62-150 15µH
C1, C2: AVX TAJA156M016
C3: X7R CERAMIC
D1: MOTOROLA MBR0520
1613 • TA01
VIN = 5V
FB
GND
(814) 237-1431
(803) 946-0362
D1
L1B
15µH
LT1613
R2
121k
VIN = 6.5V
VIN = 3.6V
VIN
C1
15µF
SHDN
85
75
+
C2
22µF
Figure 4. This 4-cell to 15V boost converter can deliver 50mA
from a 3V input.
80
VIN
4V–7V
FB
GND
C3
0.22µF
L1A
15µH
D1
EFFICIENCY (%)
VIN
3V–7V
L1: SUMIDA CLS62-220 22µH
C1, C2: AVX TAJB226010
C3: X7R CERAMIC
D1: MOTOROLA MBR0520
C2
22µF
(847) 956-0666
(803) 946-0362
1613 • TA01
(800) 441-2447
Figure 9. This inverting converter delivers –5V at 150mA from
a 5V input.
Linear Technology Magazine • February 1999
DESIGN FEATURES
85
80
VOUT
2V/DIV
VIN = 5V
EFFICIENCY (%)
75
70
VIN = 3V
ISW
500mA/DIV
65
60
55
VSHDN
5V/DIV
50
0
25
50
75
100
LOAD CURRENT (mA)
125
150
200µs/DIV
Figure 11. 5V to –5V inverting converter start-up into a 47Ω load
1611 TA02
Figure 10. 5V to –5V inverting converter
efficiency reaches 76%.
VOUT
200mV/DIV
AC COUPLED
converter function with better output
capacitors. Now, output ripple measures just 4mV P-P. Additionally,
transient response is improved by the
addition of phase lead capacitor C5.
Figure 14 depicts load transient
response of a 25mA to 125mA load
step. Maximum perturbation is under
30mV and the converter reaches final
value in approximately 250µs.
It is important to take notice of how
Figures 9 and 13 are drawn. D1’s
cathode is returned to the LT1611’s
GND pin before both connect to the
ground plane. This connection combines the current of the switch and
diode, which conduct on alternate
phases. The summation of both currents equals a current with no abrupt
changes, minimizing di/dt induced
voltages caused by the few nanohenries of inductance in the ground plane.
This summed current is then depos-
ISW
100mA/DIV
VSW
10V/DIV
100ns/DIV
Figure 12. Switching waveforms of inverting converter with 100mA load
ited into the ground plane. If this
technique is not followed, 100mV
spikes can appear at the converter
output (I speak from experience: my
first several breadboards had this
problem).
Many systems, such as personal
computers, have a 12V supply available. Although the LT1611 VIN pin
5V OR 12V
(SEE TEXT)
has a 10V maximum, the 36V switch
allows a 12V supply to be used for the
inductor while the LT1611’s VIN pin is
still driven from 5V, as indicated in
Figure 13. Significantly more output
power can be obtained in this manner, as illustrated in the efficiency
graph of Figure 15.
continued on page 23
L1A
22µH C2
0.22µF
VIN
5V
D1
VIN
C1
22µF
SHDN
SW
LT1611
SHDN
VOUT
–5V/150mA
29.4k
C5
2.2nF
NFB
GND
10k
C3
4.7µF
+
+
L1B
22µH
VOUT
20mV/DIV
AC COUPLED
C4
68µF
ILOAD
L1: SUMIDA CLS62-220 22µH
C1: AVX TAJB226010
C2: X7R CERAMIC
C3: Y5V CERAMIC
C4: SANYO POSCAP 10TPC68M
D1: MOTOROLA MBR0520
(847) 956-0666
(803) 946-0362
125mA
25mA
1613 • TA01
(619) 661-6835
(800) 441-2447
Figure 13. Low noise inverting converter; component selection and
feedforward capacitor C5 reduce noise to 4mVP-P.
Linear Technology Magazine • February 1999
200µs/DIV
Figure 14. Transient response of low noise inverting converter is
under 30mV for a 25mA to 125mA load step. Steady-state output
ripple is 4mVP-P.
13
DESIGN FEATURES
Versatile New Switching Regulator
by Craig Varga
Fits in SO-8
Introduction
Linear Technology recently introduced
the LTC1530 synchronous buck
regulator controller. Although packaged in an 8-pin SO, it has proven to
be remarkably capable and versatile.
The part is loosely based on the
popular LTC1430, but with numerous
enhancements. Features include
current limiting that senses the voltage across the RDS(ON) of the high-side
MOSFET (no sense resistor required),
built in soft-start, 1% accurate reference, gate drivers capable of handling
large MOSFETs, and micropower
shutdown. The error amplifier transconductance is higher than that of
previous generation parts and is
trimmed for accuracy and stabilized
over temperature. The IMAX current,
which programs current limit, has a
positive temperature coefficient to
Instead of the traditional current
sense resistor, the LTC1530 relies on
the RDS(ON) of the high-side MOSFET
as its source of load current information. This saves the space, cost and
the power dissipation of an additional
resistor in the power path. The programming current (IMAX) has a positive
temperature coefficient that approximates the positive TC of a MOSFET’s
RDS(ON). This tends to flatten the current-limit trip point as a function of
temperature. In a slight overload, the
LTC1530 provides “square current
limiting.” In other words, the regulator starts to look like a current source.
In the event of a significant overload,
should the output fall to less than
one-half of the nominal output voltage, the soft-start capacitor will be
discharged very quickly. This forces
help cancel the positive temperature
coefficient of the MOSFET’s RDS(ON).
This allows for more consistent current limit over temperature. Although
intended primarily for buck regulator
designs, the part has been successfully
designed into boost, positive-tonegative and negative-to-positive
converters.
A Quick Look at the Insides
Figure 1 is the basic block diagram.
The LTC1530 is a voltage mode control, synchronous buck regulator
controller. An on-chip oscillator generates a 300kHz ramp waveform. The
output of the error amplifier is compared to this ramp by the PWM
comparator. So far, nothing extraordinary. Current-limit circuitry,
however, is a little more unusual.
DISDR
LOGIC AND
THERMAL SHUTDOWN
INTERNAL
OSCILLATOR
1
PVCC
POWER DOWN
8 G1
–
ICOMP
PWM
7 G2
+
COMP 4
ISS
MSS
CSS
Ω
gm = 2m
ERR
+
MIN
–
–
MAX
+
+
–
FB
VREF
VREF – 3%
FB
–
6 IFB
VSENSE
3
VOUT
FOR FIXED
VOLTAGE
VERSIONS
CC
+
3
VREF + 3%
5 IMAX
IMAX
MHCL
HCL*
MONO
+
LVC
–
VREF /2
VREF
VREF – 3%
VREF + 3%
VREF /2
VREF
1530 BD
*HCL = HARD CURRENT LIMIT
Figure 1. LTC1530 block diagram
14
Linear Technology Magazine • February 1999
DESIGN FEATURES
OPTIONAL, INSTALL IF NO 12V
D2 BAT54S
12V
C1
1µF
16V
VIN
5V
C4
1µF
16V
+
C11
4.7µF, 16V
KEMET Ta
+
C12
0.22µF
R4 750Ω
C2–C3
330µF, 6.3V
KEMET Ta
×2
C5
68pF
1
4
C6
1800pF
2
R5
10k
Q3
2N7002
3
LTC1530S8
PVCC
IMAX
COMP
G1
VFB
IFB
GND
G2
5
8
6
Q1
IRF7805
7
R3 100Ω
L1
3.5µH
ETQP6F3R5SFA
Q2
IRF7805
D1
MBRS130T3
R10
10k
C7
270pF
R1
16.5k
1%
VREF = 1.233V
R6
R2
R8
R9
1.0Ω
R7
75k 68.1k 20.5k 11.3k +
1%
1%
1% 1%
3.3V
2.5V
1.5V 1.8V
C13
2200pF
JP1
JP2
JP3
VOUT
1.5V, 1.8V,
2.5V OR 3.3V
AT 6A
C8–C10
330µF
6.3V
KEMET Ta
×3
ON/OFF
Figure 2. 6A buck regulator; output voltage is jumper selectable for 1.5V, 1.8V, 2.5V or 3.3V.
the regulator into shutdown for a
period of time, typically a few milliseconds. After the time delay, the
supply attempts to restart. If the overload still exists, the hiccup mode
operation will continue. Once the short
is removed, the regulator will start
normally.
Unlike its predecessor, the
LTC1530’s soft-start capacitor is
internal. The start-up rise time was
chosen to satisfy the vast majority of
application requirements. Turn on is
clean, well controlled and monotonic.
Since dynamic performance is of
extreme importance in many of today’s
systems, the LTC1530 incorporates
several features to provide improved
response times to load transients.
First are the min/max comparators.
Figure 3. Output voltage at turn-on for Figure
2’s circuit
Linear Technology Magazine • February 1999
These are a pair of comparators that
continuously monitor the output voltage. If the output is more than 3% on
either side of nominal, the appropriate comparator forces the duty factor
to maximum or zero in an attempt to
restore the output to the correct level
as quickly as possible. Eventually,
the error amplifier and main feedback loop will catch up and force the
output to settle nicely. The error amplifier is also an improvement over
earlier designs. The transconductance and output impedance have both
been increased substantially from the
LTC1430 values. This has the effect
of raising the DC open-loop gain of
the amplifier, resulting in better line
and load regulation. Transconductance is also trimmed to ensure
accuracy. The result is more predictable and repeatable loop response.
The amplifier gm is temperature compensated so loop gain stays nearly
constant over temperature extremes.
The LTC1530 also has a low power
shutdown mode. If the Comp pin is
pulled to ground with an open collector or open drain transistor, the
LTC1530’s quiescent current will drop
to approximately 45µA.
Virtually all integrated circuits have
some quirks that will get you in trouble
if you don’t pay attention. The
LTC1530 is no exception. Care must
be taken in choosing the power MOSFETs used in circuits that depend on
a charge pump to supply gate-drive
power. It is essential to select a FET
for the upper device that will be almost
fully enhanced before the PVCC supply voltage reaches 8V with whatever
main input voltage happens to be
available. Failure to heed this
requirement can lead to a circuit that
may not start up properly at all times.
Standard logic-level FETs work fine.
Be sure VTH is less than 2V in the
worst case.
The cause of this start-up phenomenon is related to the way the
current limit circuit behaves. Below a
PVCC level of 8V, current limit is disabled. Assume for the sake of this
discussion that the main input supply is derived from 5V. At turn on, as
the charge pump gradually pushes
the PVCC supply upward, the currentlimit circuit wakes up at 8V on PVCC.
If the 5V supply is exactly 5V, the gate
drive available for the FET is only 3V
(8V – 5V). If the FET’s RDS(ON) is very
high relative to its nominal value at
this point, the current-limit circuit
may activate in a misguided attempt
to maintain control of the output current. If, at the same time, the output
voltage has come up to less than onehalf of its final value, the LTC1530
will respond by discharging the soft15
DESIGN FEATURES
D1 BAT54S
+
C12
1µF
16V
C11
4.7µF
16V
C11
0.1µF
C2, C3, C8–C10: PANASONIC SP TYPE
(201) 348-7522
L1: GOWANDA 50-324
OR DALE IHLP2525
(SEE TEXT)
VIN
5V
+
C4
1µF
10V
(716) 532-2234
(605) 665-1627
R4 750Ω
C2–C3
47µF, 6.3V
×2
1
4
C5
4700pF
C7
68pF
3
2
LTC1530S8
PVCC
COMP
VFB
GND
IMAX
G1
IFB
G2
5
8
6
Q1A
Si4936DY
7
R5 100Ω
R2
10k
L1
4.7µH
VOUT
3.3V/3A
C6
470pF
Q1B
Si4936DY
VREF = 1.233V
R1
16.9k
1% +
R7
10k
1%
C8–C10
56µF
4V
×3
Figure 4. 3.3V/3A regulator
start capacitor and trying to initiate a
restart.
As long as the output voltage has
reached a level of greater than onehalf of its final value before the PVCC
voltage reaches 8V, the output will
continue to rise in current limit. If the
output is below this level, start-up is
not ensured. If the PVCC supply is
derived from a 12V source instead of
charge pumped from the 5V supply,
this problem cannot occur.
A Few Circuit Examples
The LTC1530 turns out to be a rather
versatile device. Although intended
as a buck regulator, the part has been
successfully used in boost and buckboost designs. Figure 2 is a classic
buck topology. The circuit was
designed to handle approximately 6A
while maintaining a low profile. Input
and output capacitors are tantalum
devices. The inductor is a very low DC
resistance design for high efficiency.
The input is 5V, while the output
voltage can be jumper selected for
3.3V, 2.5V, 1.8V or 1.5V. The photo
in Figure 3 shows the output voltage
rise at turn on. A clean, monotonic
rise is evident.
Figure 4 is a 3A design that has a
total height of less than 2.4mm. The
inductor is a Gowanda part #50-324,
which mounts through a hole in the
PCB for a total height above the board
of approximately 1.5mm. Output
ripple voltage is approximately
10mVP-P at a 3A load with the specified
Panasonic SP series output capacitors. There are several options for the
main inductor. The overall smallest
size available is an IHLP-2525 by
Dale Electronics. It’s 3mm tall but
only 6.4mm on a side. Output ripple
is about 50% higher with this inductor.
Figure 5 is an example of a synchronous boost regulator. The input
is 3.3V and the output is 5V. The
circuit is rated for a maximum output
current of 6A. Since the output curL1*
2.5µH
VIN
3.3V
+
C3
1µF
16V
C4
1µF X7R
1
2
3
LTC1517-5
5
C1–
VIN
C1–C2
470µF
16V
×2
C6
0.22µF
4
C1+
VOUT
C9
1µF
X7R
4
C15
100pF
C14
0.022µF
3
2
D3
FMM914
+
C12
10µF
16V
C13
1µF
16V
C5
0.22µF
D1
MBR0530
5
GND
D2
MBR0530
RS1
(OPTIONAL,
SEE TEXT)
LTC1530S8
IMAX
PVCC
COMP
G2
VFB
IFB
GND
G1
L2**
10µH
1
7
6
8
R1
12k
Q2
IRF7801
VREF =
1.233V
R2
71.5k
1%
+
+
R3
23.2k
1%
*L1: PULSE PE-53681 (619) 674-8100
**L2: COILCRAFT DS3316P-102 (847) 639-6400
VOUT
5V/6A
Q1
IRF7801
C10
470µF
6.3V
C7, C8,
C11
470µF
6.3V
×3
Figure 5. 5V/6A synchronous boost regulator
16
Linear Technology Magazine • February 1999
DESIGN FEATURES
rent waveform is discontinuous, the
output ripple is inherently large in
any boost regulator. The second stage
LC filter is added to clean things up a
bit. The feedback divider connects to
the output before the LC filter for a
reason. If the divider is connected
after the LC filter, the extra 180° of
phase shift above the LC corner frequency will make the regulator’s
feedback loop unstable. The DC resistance of the inductor is small, so
the effect on load regulation is minimal.
The LTC1517 charge pump is used
to generate a sufficiently high voltage
for the LTC1530 to function correctly
and also to ensure adequate gate
drive for the power MOSFETs. It runs
from the 3.3V input and delivers a
regulated 5V output. Once the main
output comes into regulation, charge
pump power is derived through D2.
This causes the LTC1517’s regulated
output voltage set-point to be exceeded
and D3 back biases, shutting the
LTC1517 down. Note that current
limit is disabled in this design by
grounding IMAX and connecting IFB to
VIN. Since in the boost topology there
is a direct DC path from input to
is driven by the other half of the
LTC1693. The driver is only required
at this location to match the propagation delay of the high-side drive.
Failure to pay attention to these details
will result in severely degraded efficiency. Output currents of up to 4A
can be obtained from this circuit.
Like the boost regulator, the output
currents are discontinuous, so ripple
on the output is somewhat high. A
small, second-stage LC filter can easily remedy this if desired.
output, there is no point in using the
current limit feature except to protect
against inductor saturation. It is also
worth mentioning that the FET RDS(ON)
cannot be used as the current sense
resistor in this application because
FET Q2’s drain is not common to VIN.
If inductor saturation protection is
desirable, it is possible to install a
small value current sense resistor
between C2 and L1. Install an appropriate value resistor (RS1) between C2
and L1; connect the IMAX pin to the C2
side of RS1 (instead of ground) and
connect IFB directly to the input side
of L1. Just don’t expect the circuit to
limit current in the event of a short
circuit.
Figure 6 is a positive input to negative 5V output design. Since the
LTC1530 needs to be referenced to
the –5V output, the design requires
external gate-drive circuitry for both
the main and synchronous FETs. The
absolute maximum voltage rating of
the LTC1530’s gate drive would be
exceeded if the high-side gate were
driven directly. Q3 and the associated
parts at the input to the LTC1693
gate driver provide the required levelshift function. The synchronous FET
Conclusion
The LTC1530 is a small, versatile
controller that is usable in numerous
topologies and over a wide range of
power levels. In the basic buck applications for which it was designed, the
LTC1530 permits the designer to
realize very simple, low parts count
designs that require minimal real
estate. The part provides clean turnon and current-limit characteristics.
With a little ingenuity, it is possible to
develop circuits different than those
that the part’s designers intended,
but which give excellent performance
nonetheless.
VIN 5V
R8
470Ω
1/4W
C7
4.7µF
+
R1
2.7k
R3
1.3k
C3
10µF
C4
0.1µF
LTC1530-ADJ
5
PVCC
IMAX
4
8
COMP
G1
3
6
VSENSE
IFB
2
7
GND
G2
R4
2.0k
RC
4.7k
Q1
Q3
D2
2N7002 MBR0530T1
1
C1
1000pF
C2
27µF
5
CIN
4 1/2
LTC1693-2
R9 1k
Q4
2N3906
+
3
+
Q2
R7 3.3Ω
L1
2.5µH
C8
4.7µF
+
CC
0.22µF
1
8
7
COUT
VOUT
–5V/5A
+
+
6
D1
MBR0530T1
C6
0.1µF
R10
47Ω
2
1/2 LTC1693-2
R5
2.96k
D4
1N4148
D3
1N4148
+
R6
1k
C5
6.8µF
R2
100Ω
L1: PANASONIC ETQP6F2R5FA
(201) 348-7522
CIN: 3× SANYO 10MV1200GX
COUT: 4× SANYO 6MV1500GX
(619) 661-6835
Q1, Q2: SUD50N03-10
Figure 6. 5V to –5V/4A synchronous switching, inverting polarity converter
Linear Technology Magazine • February 1999
17
DESIGN FEATURES
16-Bit Parallel DAC Has 1LSB Linearity,
Ultralow Glitch and Accurate
by Patrick Copley
4-Quadrant Resistors
Today’s fast paced marketplace has
developed a major appetite for high
resolution, high accuracy, fast digital-to-analog converters. System
requirements in instrumentation,
automatic test equipment, communications, waveform generation, data
acquisition and feedback control systems, among many other applications,
have fueled the need for 16-bit digitalto-analog converters. Not only does
the converter need to meet the stringent speed and accuracy requirements
of the system, it needs to do so in both
unipolar (0V to 10V) and bipolar (±10V)
modes of operation without degradation. To meet and exceed these
requirements, Linear Technology
introduces its LTC1597 16-bit parallel, current output, low glitch,
multiplying DAC with 4-quadrant
resistors. Key features of the new
DAC include:
❏ ±1LSB maximum INL and DNL
over the industrial temperature
range
❏ On-chip 4-quadrant resistors
allow precise 0V to 10V, 0V to
–10V or ±10V outputs
❏ Ultralow, < 1nV-s midscale glitch
impulse
❏ Small 28-pin SSOP package
❏ Low supply power consumption:
10µW typical
❏ Pin-compatible with the LTC1591
14-bit parallel, current output,
low glitch, multiplying DAC with
4-quadrant resistors.
Unique Features
of the LTC1597
The LTC1597 operates from a single
5V supply and provides both unipolar
48k
REF
0V to –10V or 0V to 10V and bipolar
±10V output ranges from a 10V or
–10V reference input using a single or
dual external op amp. The device
achieves bipolar operation using three
additional on-chip precision resistors.
The DAC consists of a precision thinfilm R/2R ladder for the thirteen LSBs.
The three MSBs are decoded into
seven segments of resistor value R, as
shown in Figure 1. R is nominally
48k. Each of these segments and the
R/2R ladder carry an equally weighted
current of one-eight of full-scale. The
feedback resistor, RFB, and 4-quadrant resistor, ROFS, have a value of R/
4. 4-quadrant resistors R1 and R2
have a magnitude of R/4.
The reference pin presents a constant
input impedance of R/8 in unipolar
mode and R/12 in bipolar mode. The
output impedance of the current output pin, IOUT1, varies with DAC code.
48k
1
R2
12k
RCOM 2
48k
48k
48k
48k
48k
48k
48k
96k
96k
96k
96k
ROFS
12k
RFB
12k
4 ROFS
5 RFB
R1
12k
R1 3
6 IOUT1
VCC 23
7 AGND
DECODER
LD 8
WR 9
LOAD
22 DGND
D15
(MSB)
D14
D12
D13
D11
•••
DAC REGISTER
D0
(LSB) RST
INPUT REGISTER
WR
28 CLR
RST
1597 BD
10
11
D15
D14
••••
21
24
25
26
27
D4
D3
D2
D1
D0
Figure 1. The LTC1597 16-bit CMOS DAC uses a precision thin-film modified R/2R architecture to provide unsurpassed accuracy and stability.
Accurate 4-quadrant multiplication applications are now possible with on-chip resistors R1, R2 and ROFS. A built-in deglitcher reduces glitch
impulse to 1nV-s.
18
Linear Technology Magazine • February 1999
DESIGN FEATURES
1.0
16-Bit Accuracy
Over Temperature
INTEGRAL NONLINEARITY (LSB)
0.8
0.6
0.4
0.2
0
– 0.2
– 0.4
– 0.6
– 0.8
–1.0
0
49152
32768
16384
DIGITAL INPUT CODE
2a.
65535
1597 G01
DIFFERENTIAL NONLINEARITY (LSB)
1.0
0.8
0.6
0.4
0.2
0
– 0.2
– 0.4
– 0.6
– 0.8
–1.0
0
49152
32768
16384
DIGITAL INPUT CODE
65535
1597 G02
2b.
Figure 2. The outstanding INL and DNL
(typically less than 0.25LSB) and very low
linearity drift allow a maximum 1LSB spec to
be guaranteed over the industrial temperature range.
An added feature of the LTC1597 is
a proprietary deglitcher that reduces
the glitch energy to below 1nV-s over
the DAC’s output voltage range.
The LTC1597 has a 16-bit parallel
input data bus and is double buffered
with two 16-bit registers. The double
buffered feature permits the updating of several DACs simultaneously.
The WR signal updates the input register and the LD signal loads the DAC
register. The deglitcher is activated
on the rising edge of the LD signal.
The versatility of the interface also
allows the use of the input and DAC
registers in a master/slave or edgetriggered configuration. This mode of
operation occurs when WR and LD
are tied together to act as a clock
signal.
The asynchronous clear pin (CLR)
resets the LTC1597 to zero scale and
the LTC1597-1 to midscale. CLR resets both the input and DAC registers.
The LTC1597 also features a poweron reset.
Linear Technology Magazine • February 1999
The LTC1597 has ultralow linearity
drift of well below ±0.2LSB from
–45°C to 85°C. This allows the
LTC1597 to hold its accuracy of 1LSB
integral nonlinearity (INL) and differential nonlinearity (DNL) over time
and temperature. In the past, the
only DACs that approached this
accuracy over temperature were of
the autocalibrated type. These DACs
were very large, very expensive and
therefore not very practical for most
applications.
Figures 2a and 2b show the typical
INL and DNL curves of the LTC1597.
The outstanding 0.25LSB INL, 0.15
LSB DNL (typical) and very low drift
allow a maximum 1LSB specification
over the extended industrial temperature range. For optimum performance,
the REF pin of the LTC1597 should be
driven by a source impedance of less
than 1kΩ. However, the DAC has been
designed to minimize source
impedance effects. An 8kΩ source
impedance degrades both INL and
DNL by a mere 0.2LSB.
5V
LD PULSE
5V/DIV
GATED
SETTLING
WAVEFORM
500µV/DIV
500ns/DIV
Figure 4. When used with the LT1468 and a
20pF feedback capacitor (see Figure 3), the
LTC1597 can settle in an amazing 1.7µs to
within 0.0015%. The top trace shows the LD
pulse; the bottom trace shows the gated
settling waveform settling to 1LSB in 1.7µs.
Fast Settling:
Less than 2µs to within
0.0015% of Full-Scale
Now system designers no longer have
to make tough decisions in the tradeoff between accuracy and speed. The
solution is here. The combination of
the LTC1597 DAC and the LT1468 op
amp provides an industry first: superb
16-bit settling of less than 2µs for a
10V step while maintaining 1LSB DC
accuracy.
Figure 3 shows the application circuit for unipolar mode. Figure 4 shows
the resulting full-scale 10V step settling time of the LTC1597/LT1468
combination. With a 20pF feedback
capacitor, the optimized settling time
to 0.0015% is an amazing ≈1.7µs. A
0.1µF
VREF
2
3
R1
1
REF
RCOM
R1
23
VCC
4
5
ROFS
RFB
ROFS
R2
20pF
RFB
IOUT1
16
DATA
INPUTS
LTC1597
–
6
16-BIT DAC
AGND
10 TO 21,
24 TO 27
DGND
7
+
LT1468
VOUT =
0V TO
–VREF
22
WR LD CLR
WR
LD
CLR
9
8
28
Unipolar Binary Code Table
DIGITAL INPUT
BINARY NUMBER
IN DAC REGISTER
LSB
MSB
1111
1000
0000
0000
ANALOG OUTPUT
VOUT
1111
0000
0000
0000
1111
0000
0000
0000
1111
0000
0001
0000
–VREF (65,535/65,536)
–VREF (32,768/65,536) = –VREF/2
–VREF (1/65,536)
0V
1591/97 F01b
Figure 3. With a single external op amp, the LTC1597 performs 2-quadrant multiplication with
±10V input and 0V to –VREF output. With a fixed –10V reference, it provides a precision 0V to
10V unipolar output.
19
DESIGN FEATURES
– 50
– 60
– 70
– 80
500kHz FILTER
– 90
80kHz FILTER
–100
30kHz FILTER
–110
10
100
1k
10k
FREQUENCY (Hz)
– 50
– 40
VCC = 5V USING TWO LT1468s
CFEEDBACK = 15pF
REFERENCE = 6VRMS
– 60
– 70
– 80
500kHz FILTER
– 90
–100
80kHz FILTER
10
100
– 60
– 70
– 80
500kHz FILTER
– 90
80kHz FILTER
–100
–110
1k
10k
FREQUENCY (Hz)
1591/97 G03
VCC = 5V USING TWO LT1468s
CFEEDBACK = 15pF
REFERENCE = 6VRMS
– 50
30kHz FILTER
30kHz
FILTER
–110
100k
6a. Unipolar-mode full-scale: the noise and
distortion (N + D) is less than –96dB for signal
frequencies up to 30kHz. Out to 100kHz, the
N + D is less than –78dB.
SIGNAL/(NOISE + DISTORTION) (dB)
– 40
VCC = 5V USING AN LT1468
CFEEDBACK = 30pF
REFERENCE = 6VRMS
SIGNAL/(NOISE + DISTORTION) (dB)
SIGNAL/(NOISE + DISTORTION) (dB)
– 40
10
100k
100
1k
10k
FREQUENCY (Hz)
100k
1591/97 G05
1591/97 G04
6b. Bipolar-mode zero-scale: the N + D is less
than –96dB for signal frequencies up to
30kHz. Out to 100kHz, the N + D is less than
–82dB.
6c. Bipolar-mode full-scale: the (N + D) is less
than –96dB for signal frequencies up to
30kHz. Out to 100kHz, the N + D is less than
–79dB.
Figure 6. LTC1597 multiplying-mode signal-to-noise vs frequency
detailed discussion of 16-bit settling
time can be found in Linear Technology Application Note 74, “Component
and Measurement Advances Ensure
16-Bit DAC Settling Time.”
The ability to minimize settling time
is limited by the need to null the DAC
output capacitance, which varies from
70pF to 115pF, depending on code.
This capacitance at the amplifier input
combines with the feedback resistor
to form a zero in the closed-loop frequency response in the vicinity of
200kHz–400kHz. Without a feedback
capacitor, the circuit will oscillate.
The choice of 20pF stabilizes the circuit by adding a pole at 1.3MHz to
limit the frequency peaking and also
optimizes settling time. The settling
time to 16-bit accuracy is theoretically bounded by 11.1 time constants
set by the feedback resistance and
capacitance.
OUTPUT VOLTAGE (mV)
+10
Glitches in a DAC’s output when it
updates can be a big problem in precision applications. Usually, the
worst-case glitch occurs when the
DAC output crosses midscale. The
LTC1597’s new proprietary deglitcher
reduces the output glitch impulse to
1nV-s, which is at least ten times
lower than any of the competition’s
16-bit voltage output DACs. In addition, the deglitcher makes the glitch
impulse uniform for any code. Figure
5 shows the output glitch for a midscale transition with a 0V to 10V
output range.
Unipolar 0V to 10V Outputs
with a Single Op Amp
Figure 3 shows the circuit for a 0V to
10V output range. The DAC uses an
external reference and a single op
amp in this configuration. This circuit can also perform 2-quadrant
multiplication where the REF pin is
driven by a ±10V AC input signal and
VOUT swings from 0V to –VREF.
VREF
+
5V
0.1µF
1/2 LT1112
–
2
3
R1
1
REF
RCOM
R1
5
23 4
VCC ROFS
ROFS
R2
RFB
33pF
RFB
IOUT1
16
DATA
INPUTS
LTC1597-1
–
6
1/2 LT1112
16-BIT DAC
AGND
10 TO 21,
24 TO 27
COMPETITOR’S DAC
DGND
7
+
VOUT =
–VREF
TO VREF
22
WR LD CLR
WR
LD
CLR
0
1nV-s TYP LTC1597
–10
9
8
28
Bipolar Offset Binary Code Table
DIGITAL INPUT
BINARY NUMBER
IN DAC REGISTER
1
2
TIME (µs)
3
4
03 .eps
Figure 5. The proprietary deglitcher 1595
reduces
the output glitch to less than 1nV-s, which is
ten times less than any other 16-bit, voltageoutput DAC. Further, the deglitcher makes
the glitch uniform, independent of code.
1111
1000
1000
0111
0000
ANALOG OUTPUT
VOUT
LSB
MSB
0
20
Ultralow 1nV-s Glitch
1111
0000
0000
1111
0000
1111
0000
0000
1111
0000
1111
0001
0000
1111
0000
VREF (32,767/32,768)
VREF (1/32,768)
0V
–VREF (1/32,768)
–VREF
1591/97 F02b
Figure 7. With a dual op amp, the LTC1597 performs 4-quadrant multiplication. With a fixed
10V reference, it provides a ±10V bipolar output. For fast bipolar settling applications, an
LT1468 can be used for the output amplifier.
Linear Technology Magazine • February 1999
DESIGN FEATURES
Bipolar ±10V Output
with Two Op Amps
modes of operation. For AC signals less
than 40kHz, the THD+noise is superb
(better than 90dB) and is still very good
out to 100kHz (78dB). Filtering at the
output of the LT1468 is necessary to
reduce the noise bandwidth to acceptable levels. The wider the bandwidth,
the higher the noise floor.
The LTC1597 contains all the 4-quadrant resistors necessary for bipolar
operation. For a fixed 10V reference,
the circuit shown in Figure 7 gives a
precision –10V to 10V output swing,
with a minimum of external components: a feedback capacitor and a
dual op amp. The bipolar zero error is
8LSB maximum over temperature. If
two LT1468 op amps are used instead
of the LT1112, the circuit can perform wider bandwidth 4-quadrant
multiplication, where the reference
input is driven by a ±10V AC input
signal and VOUT swings ±10V .
Figure 6 shows a graph of the multiplying mode total harmonic distortion and
noise of the LTC1597/LT1468 combination in both unipolar and bipolar
0.92LSB (140µV) at 17 bits for room
temperature. The circuit uses the
LTC1597 in its unipolar mode with
the reference input inverted (–VREF,
by means of R1 and R2 and an external op amp) for the output voltage
range 0V to VREF. When the sign bit
changes, the analog switch changes
the reference input polarity to noninverting (VREF) for the output range 0V
to –VREF.
17-Bit Sign Magnitude DAC
Gives Perfect Bipolar Zero
Figure 8 shows a novel application of
the LTC1597, a 17-bit sign magnitude DAC, and the resulting output
coding. This circuit has an extremely
accurate bipolar zero error, which is
the offset voltage of the current-tovoltage op amp plus the bias current
times the DAC feedback resistor. For
the LT1468, this corresponds to a
maximum bipolar zero error of
16
94dB SFDR
Digital Sine Wave Generator
Figure 9 shows the circuit diagram
for a variable frequency digital waveform generator. The circuit shows the
bipolar configuration for the LTC1597
but the unipolar configuration will
work just as well. For a sampling
frequency of 50kHz and an output
sine wave frequency of 1kHz, the second harmonic distortion is –94dB and
the third harmonic is –101dB. The
on-chip deglitcher circuit minimizes
the code-dependent glitch (which
14
15
Bipolar Sign Magnitude Code Table
LTC203AC
DIGITAL INPUT
BINARY NUMBER
IN DAC REGISTER
LSB
SIGN MSB
1
2
15V
LTC1236A-10
2
1
1
1
0
0
0
3
6 VREF
1111
0000
0000
0000
0000
1111
ANALOG OUTPUT
VOUT
1111
0000
0000
0000
0000
1111
1111
0000
0000
0000
0000
1111
1111
0001
0000
0000
0001
1111
VREF (65,535/65,536)
VREF (1/65,536)
0V
0V
–VREF (1/65,536)
–VREF (65,535/65,536)
+
4
5V
LT1468
–
0.1µF
15pF
3
R1
2
RCOM
1
REF
5
RFB
23 4
ROFS
SIGN BIT
20pF
R2
R1
ROFS
RFB
LTC1597
10 T0 21
24 TO 27
–
6
I0UT
16 DATA
INPUTS
16-BIT DAC
AGND
7
+
LT1468
VOUT
22
DGND
WR LD CLR
9
8
28
WR
LD
CLR
Figure 8. This 17-bit sign-magnitude DAC uses the LTC1597 in its unipolar mode with the reference bit inverted (–VREF) for the output range 0V
to VREF. When the sign bit changes, the analog switch changes the reference input polarity to noninverting (VREF) for the output range 0V to
–VREF. The resulting circuit produces an impressive bipolar zero error of 140µV (0.92LSB) max at room temperature—less than 1LSB at 17 bits.
Linear Technology Magazine • February 1999
21
DESIGN FEATURES
2
LTC1236A-10
15V
10V
6
+
4
5V
LT1001
0.1µF
–
3
R1
n = 24–32 BITS
SERIAL OR
PARALLEL
DATA INPUT
n
1
REF
5
RFB
23 4
ROFS
15pF
n
SERIAL
OR BYTE
LOAD
REGISTER
2
RCOM
R2
R1
ROFS
RFB
PHASE ACCUMULATOR
PARALLEL
n
DELTA
PHASE
REGISTER
M
n
Σ
n
PHASE
REGISTER
CLOCK
FREQUENCY CONTROL
PHASE
TRUNCATION
16 BITS
LTC1597
16-BIT DAC
AGND
10 T0 21
24 TO 27
–
6
I0UT
n SINE ROM
16 DATA
LOOKUP
INPUTS
TABLE
+
7
LOWPASS
FILTER
LT1468
22
fO =
DGND
M • fC
2n
WR LD CLR
9 8 28
fC
CLR
Figure 9. This digital waveform generator produces a 1kHz sine wave with a second harmonic distortion of –94dB. The sampling frequency is 50kHz.
BIPOLAR MODE
DAC OUTPUT ERROR
DAC OUTPUT ERROR
UNIPOLAR MODE
DAC TRANSFER CURVE WITH VOS IN CURRENT-TO-VOLTAGE OP AMP
DAC TRANSFER CURVE WITH VOS IN CURRENT-TO-VOLTAGE
OP AMP AND REF INVERTING OP AMP
GAIN ERROR =
2VOSI-to-V + 4VOSINV
GAIN ERROR =
VOSI-to-V
DAC TRANSFER CURVE
WITH IDEAL OP AMP
OFFSET ERROR =
VOSI-to-V
0
NEGATIVE FULL-SCALE
ERROR = 2VOSI-to-V
65,535
32,768
CODE
BIPOLAR ZERO ERROR =
3VOSI-to-V + 2VOSINV
DAC TRANSFER CURVE
WITH IDEAL OP AMP
32,768
CODE
0
65,535
1720 G01
1720 G01
Figure 10. The effect of op amp offset on the LTC1597 gain and offset errors in unipolar mode (left) and bipolar mode (right); op amp offset
has virtually no effect on DAC linearity; it merely shifts the end points.
Table 1. Amplifiers recommended for use with the LTC1597, with relevant specifications
Amplifier Specifications
Amplifier
VOS
µV
IB
nA
AOL
V/mV
Voltage
Noise
nV/ Hz
LT1001
25
2
800
10
0.12
LT1097
50
0.35
1000
14
LT1112 (dual)
60
0.25
1500
LT1124 (dual)
70
20
LT1468
75
10
22
Gain Bandwidth
Product
MHz
Power
Dissipation
mW
0.25
0.8
46
0.008
0.2
0.7
11
14
0.008
0.16
0.75
10.5/op amp
4000
2.7
0.3
4.5
12.5
69/op amp
5000
5
0.6
22
90
117
Current Noise Slew Rate
pA/ Hz
V/µs
Linear Technology Magazine • February 1999
DESIGN FEATURES
causes distortion) by making the glitch
impulse both ultralow and uniform
with code.
Op Amp Selection
Considerations
A significant advantage of the
LTC1597 is the ability to choose the
I-to-V output op amp to optimize system accuracy, speed, power and cost.
Table 1 shows a sampling of op amps
and their relevant specifications for
this application.
The LTC1597 is designed to minimize the sensitivity of INL and DNL to
op amp offset; this sensitivity has
been greatly reduced compared to that
of competing multiplying DACs. Figure 10 summarizes the effects of op
amp offset for both modes of operation. Note that the bipolar LSB size is
twice its unipolar counterpart. As Figure 10 shows, op amp offset has a
minimal effect on DAC linearity; it
merely shifts the end points.
LT1611/LT1613, continued from page 13
The amplifier’s input bias current,
which flows through the feedback
resistor, adds to the output offset
voltage. The amplifier’s finite DC openloop gain also degrades accuracy. The
DAC gain error is inversely proportional to the open-loop gain and
feedback factor of the op amp. In
unipolar mode at full-scale the feedback factor is 0.5; for a 0.2LSB of gain
error (REF = 10V) at 16 bits, the openloop amplifier gain should be greater
than 650,000.
The op amp’s input voltage and
current noise also limit DC accuracy.
Noise effects accuracy similarly to
voltage and current offsets and adds
in an RMS fashion. As with any precision application, and with wide
bandwidth amplifiers in particular,
the noise bandwidth should be minimized with a filter on the output of the
op amp to maximize resolution.
VIN
80
+
SHDN
70
Wherever system requirements
demand true 16-bit accuracy over
temperature, the LTC1597 provides
the best solution. The LTC1597 has
outstanding 1LSB linearity over
temperature, ultralow glitch impulse,
on-chip 4-quadrant resistors, low
power consumption, asynchronous
clear and a versatile parallel
interface.Combined with the LT1468
op amp, the LTC1597 provides the
best in its class, 1.7µs settling time to
0.0015%, while maintaining superb
DC linearity specifications.
SW
D1
L1B
15µH
LT1611
68.1k
SHDN
VOUT
–10V/60mA
NFB
GND
10k
65
+
EFFICIENCY (%)
75
C1
22µF
Conclusion:
C2
0.22µF
L1A
15µH
VIN
3.6V–7V
85
Referring to Table 1, the LT1001
provides excellent DC precision, low
noise and low power dissipation. The
LT1468 provides the optimum solution for applications requiring DC
precision, low noise and fast 16-bit
settling.
C3
6.8µF
60
55
50
0
50
100 150 200 250
LOAD CURRENT (mA)
300
350
1611 TA02
Figure 15. 12V supply at L1A increases
efficiency to 81% and output current to
350mA.
85
VIN = 6.5V
EFFICIENCY (%)
75
VIN = 3.6V
(847) 956-0666
(803) 946-0362
1613 • TA01
(800) 441-2447
Figure 16. 4-Cell to –10V inverting converter delivers 75mA from a 4V input.
LT1611 4-Cell to –10V
Inverting Converter
A –10V low noise output can be generated in a similar manner as the –5V
circuit described above. Figure 16’s
circuit can deliver –10V at up to 60mA
from a 3.6V input. Efficiency, graphed
in Figure 17, reaches a high of 78%.
80
70
L1: SUMIDA CL562-150
C1: AVX TAJB226M010
C2: X7R CERAMIC
C3: AVX TAJA685M016
D1: MOTOROLA MBR0520
VIN = 5V
65
60
Conclusion
55
The flexibility of individually controlled
outputs in multiple-supply applications can make several LT1611/
LT1613 converters attractive compared to a multiple-output flyback
50
0
25
50
75
100
LOAD CURRENT (mA)
125
150
1611 TA02
Figure 17. 4-cell to –10V converter efficiency
Linear Technology Magazine • February 1999
design with one large switching regulator and a custom transformer.
Changing an output voltage on a
multiple output flyback requires
changing the transformer turns ratio,
hardly a simple task. Conversely,
individual control of each output, using the multiple LT1611/LT1613
approach, provides for complete control of each output voltage as well as
supply sequencing. The LT1611 and
LT1613 SOT-23 switchers provide
small, low noise solutions to power
generation needs in tight spaces.
23
DESIGN FEATURES
Fast Rate Li-Ion Battery Charger
by Goran Perica
Introduction
The recent trend in notebook computers has been toward increasing
battery operating time and faster
processor speeds. These two requirements, in conjunction with a need for
faster battery recharging (1–2 hours)
have placed a strain on battery charging circuits and wall adapters. A
typical notebook computer system
configuration is shown in Figure 1.
Wall adapters are typically AC/DC
converters with a 20V output at
3A–4A of load current. When a notebook computer is running, all of the
available current from the wall adapter
may be consumed by the system,
with no power left for charging the
battery. However, as soon as the
system’s power requirements drop
below the wall adapter’s current limit,
the battery charging can resume. In
order to recharge the battery in the
shortest time possible, the recharging should start as soon as there is
any current left over from the system.
The ideal situation is when the sum of
battery charging current and the system current is just below the wall
adapter’s current limit:
IIN_MAX > ISYS + ICHARGER
where IIN_MAX is the wall adapter current limit, ISYS is the system load
current and ICHARGER is the battery
charger current.
To achieve this objective, it is necessary to adjust the battery charger
current so that the sum of the two
currents is just below the maximum
available input current, IIN_MAX. The
INPUT FROM
WALL ADAPTER
LT1505 incorporates a patented battery charger input current limiting
function along with other functions
necessary to provide a complete,
single-chip battery charging circuit
solution.
LT1505 Features
The LT1505 is a constant-current
(CC), constant-voltage (CV) current
mode switching battery charger circuit with the following features:
❏ 0.5% voltage reference
❏ 5% output current regulation
❏ Output voltage is preset for 3 or 4
Li-Ion cells (12.3V, 12.6V, 16.4V
and 16.8V)
❏ Output voltage is programmable
from 1V to 21V
❏ Low VIN-to-VOUT operation
(dropout <0.5V)
❏ Programmable AC wall adapter
current limiting
❏ Programmable peak battery
charging current
❏ Battery drain <10µA in shutdown
❏ 94% efficiency
Circuit Description
The LT1505 is a synchronous buck
converter using N-channel MOSFETs.
The LT1505 operates at 200kHz and
can be synchronized to an external
clock with a frequency higher than
240kHz. The LT1505 IC has an
undervoltage lockout circuit that
detects the presence of an input power
source and enables the battery charging. Once the undervoltage lockout
has been exceeded, the PWM will start
INPUT
CURRENT
SENSE
LT1505
BATTERY
CHARGER
Li-Ion
BATTERY
Figure 1. Typical notebook computer power supply
24
SYSTEM
LOAD
running and the input MOSFET M3 is
turned ON, thus reducing the voltage
drop across its internal body diode
DBODY (see Figure 2).
The LT1505 monitors the current
from the wall adapter and controls
the battery charger current. For
example, if a 3A, 20V wall adapter is
used along with a 12.6V Li-Ion battery pack, the peak battery charging
current, when the system is off, can
be set to:
IBATT MAX = η × IIN_MAX × VIN/VBATT
where IBATT MAX is the maximum battery charging current when the system
is idle, η is the efficiency of battery
charger, VIN is the wall adapter output voltage and VBATT is the battery
charging voltage.
Assuming an efficiency of 90%, the
above example could provide battery
charging current in excess of 4A. The
LT1505 will reduce the battery charging current as soon as the system
current exceeds (IIN_MAX – ICHARGER).
For example, if a 20V, 3A wall adapter
is used and the system draws 2A from
the adapter, the available current for
charging the battery will be ICHARGER =
1A. The resulting battery charging
current IBATT will be:
IBATT = η × ICHARGER × VIN/VBATT
or
IBATT = 0.9 × 1A × 20V/12.6V = 1.428A
The input current from the wall
adapter passes through a current
sense resistor, RS4. One part of the
input current goes to the system load
and the remaining part goes to the
LT1505 battery charger. The voltage
drop across RS4 is monitored by a
current comparator with a 90mV
threshold. Once the threshold of 90mV
is reached, the LT1505 will reduce
the programmed battery charging current so that the peak input current
does not exceed the preset limit. Thus,
the maximum input current (IIN_MAX)
will be:
IIN_MAX = ISYSTEM + ICHARGER = 0.090V/RS4
Linear Technology Magazine • February 1999
DESIGN FEATURES
VIN
(FROM
ADAPTER)
DBODY
TO
SYSTEM POWER
M3
Si4435
RS4
0.025Ω
R7
475Ω
C4
0.1µF
CIN
47µF
35V
C1
1µF
VCC
BOOST
BOOSTC
GBIAS
100k
R5
4.75k
CLN
TGATE
CLP
SW
L1
10µH
M1
Si4412
4.7Ω
D4
MBRS140
LT1505
SHDN
3 CELL
FLAG
VFB
CAP
4.2V
COMP1
4.1V
R1
1k
C7
0.68µF
AGND
RP1
330Ω
SENSE
12.6V
BATTERY
RC1
1k
RS2
200Ω
1%
CP1
1µF
RPROG
4.93k
1%
RS3
200Ω
1%
CC1
0.33µF
PGND
BAT2 BAT
COUT
22µF
25V
×2
R2
22Ω
C8
220pF
PROG
SYNC
RS1
0.025Ω
VBAT
M2
Si4412
VC
UV
C6
0.1µF
C2
1µF
D2
1N4148
BGATE
INFET
R6
4.75k
C3
4.7µF
D3
1N4148
NOTE: DBODY IS THE BODY DIODE OF M3
(619) 661-6835
CIN: SANYO OS-CON
L1: SUMIDA CDRH127 (847) 956-0666
SPIN
1505 F01
Figure 2. 4A Li-Ion battery charger
PCB Layout
When laying out the PCB, a multilayer
layout with one of the inner layers as a
solid ground plane is recommended.
IBAT_MAX = (VPROG/RPROG) × (RS2/RS1)
The LT1505 and low power compowhere VPROG is the reference voltage nents associated with it should be kept
of 2.465V. The values in Figure 2 have as close together as possible. Additionbeen selected for a current limit ally, all power components should be
(IBAT_MAX) of 4A. Changing RS1 to kept together and next to LT1505 control circuitry. The goal is to keep all
0.050Ω will set the IBAT_MAX to 2A.
Also, the peak battery charging high power switching currents as locurrent (IBAT_MAX) can be programmed calized as possible. Components that
by the host computer. The IBAT_MAX connect to the ground plane should
can be set in increments of 0.25A if have vias placed as close as possible to
RPROG is replaced by a network of the pins connected to the ground plane.
Also, power components should have
resistors, as shown in Figure 3.
larger or multiple vias connecting to
100
95
90
EFFICIENCY (%)
The battery charger in Figure 2
achieves high efficiency thanks to
synchronous operation and input
power FET. The efficiency is as high
as 94%, as can be seen in Figure 4.
where ISYSTEM is the system load current, ICHARGER is the LT1505 battery
charger current and RS4 is the current sense resistor. With the resistor
value of 0.025Ω in Figure 2, the input
current limit IIN_MAX will be set to
3.6A.
The battery charging current limit
is set by RPROG, RS1 and RS2 and is:
85
80
75
70
65
60
0
1
2
3
OUTPUT CURRENT (A)
4
TA02
Figure 4. Efficiency of 4A, 12.6V1611battery
charger at 20V input
the ground plane. Avoid placing the
power components in such a way that
input and output currents flow by the
LT1505 IC. Also, to keep the component temperature rise low, use as much
copper as possible. The use of polygon
planes for high power nets such as the
o n e s c o n n e c t i n g t o V IN, V CC,
continued on page 35
LT1505
LIMITED
INPUT
POWER
PROG
2A
1A
10k
0.5A
20k
40.2k
4× 2N3904
FROM
µP
0.25A
80.6k
BATTERY
CHARGE
CURRENT
SENSE
RP1
330Ω
CP1
1µF
{
Figure 3. Programming of battery-charge current
Linear Technology Magazine • February 1999
LT1505
BASED
CONVERTER
SYSTEM
LOAD
BATTERY SUPPLIES
ADDITIONAL PEAK POWER
Figure 5. Typical telecom application
25
DESIGN IDEAS
No RSENSE Controller Delivers 12V
and 100W at 97% Efficiency by Christopher B.
Umminger
maximum temperature of 75°C in a
25°C environment. L1 is a customwound inductor using fourteen turns
of 15 gauge wire on a Magnetics, Inc.
Kool Mµ ® 77206-A7 core. The entire
converter takes up a volume of only
0.65in3 and processes an impressive
150W per cubic inch.
The circuit uses the LTC1625 No
RSENSE™ controller to deliver the high
output voltage with excellent efficiency. This controller provides true
current mode control without using a
sense resistor by monitoring the voltage drop across the power MOSFET
switches. Eliminating the sense
resistor saves board space and
improves efficiency. In this application, a 0.01Ω sense resistor would
dissipate about 0.7W at full load.
Many current mode controllers use
a sense resistor in series with the
inductor. Unfortunately, they must
restrict the maximum output voltage
RF 1Ω
CF
0.1µF
1
2
CSS 0.1µF
3
4
CC1
2200pF
RC1 20k
5
CC2 100pF
6
7
R1 3.92k
8
LTC1625CS
16
VIN
EXTVCC
M1
15
TK
SYNC
FDS6670A
14
SW
RUN/SS
13
TG
FCB
L1 15µH
12
BOOST
ITH
CB
11 DB CMDSH-3
0.22µF
INTVCC
SGND
10
D1
BG
VOSENSE
MBRS9
+
C
140T3
PGND
VCC
VPROG
M2
4.7µF FDS6670A
R2 35.7k
VIN
CIN 12V–28V
10µF
30V
×4
+
due to limits on the input range of the
current comparator. However, the
LTC1625 has no such constraint. The
circuit in Figure 1 uses the LTC1625
in its adjustable mode, with the VPROG
pin left open. The internal error
amplifier compares the voltage at the
VOSENSE pin to a 1.19V reference and
an external resistive divider sets the
output voltage.
Figure 2 shows that 97% efficiency
is achieved over a wide range of load
current. The application uses the FCB
pin to disable Burst Mode operation
and force continuous, synchronous
operation down to no load. Enabling
Burst Mode would keep the efficiency
above 90% down to a load of only
50mA. The current mode control of
the LTC1625 incorporates foldback
current limiting that reduces the output current to 6A when the output is
shorted.
Kool Mµ is a registered trademark of Magnetics, Inc.
100
95
VOUT
12V/8.5A
+
COUT
150µF
16V
×2
EFFICIENCY (%)
Heat removal presents a thorny
problem in many of today’s compact
systems. This is especially the case
when power converters deliver high
output voltages with several amperes
of current and are processing tens to
hundreds of watts. In this regime, a
converter with only moderate efficiency will have a significant amount
of waste heat and may require heat
sinks and additional air flow. A very
high efficiency converter can reduce
the wasted power, which saves space
and lowers costs.
The circuit shown in Figure 1 is a
power converter that produces a 12V
output at up to 8.5A from an input
that can range between 12V and 28V.
The 100W of output power is converted at 97% efficiency with only 3W
dissipated on the board. No special
heat sinks were used other than a
widened VIN trace connected to the
drain of M1. This point reached a
90
85
VIN = 24V
VOUT = 12V
80
0
CIN: SANYO OS-CON 30SC10M
COUT: SANYO OS-CON 16SA150M
4
6
LOAD CURRENT (A)
8
10
(619) 661-6835
Figure 1. 100W, 12V, 8.5A supply
26
2
Figure 2. Efficiency vs load current for
Figure 1’s circuit
Linear Technology Magazine • February 1999
DESIGN IDEAS
Generating Low Cost, Low Noise,
Dual-Voltage Supplies
by Ajmal Godil
Some sensitive electronic applications, such as telecommunication and
data acquisition, require both 5V and
–5V low noise supplies, which may
have to be generated from a single
high voltage positive supply. The circuit in Figure 1 shows a cost-effective
way to generate 5V and –5V from a
single 10V–28V supply by using the
low noise LT1777 and a few off-theshelf components.
The LT1777 is a step-down regulator specially designed for low noise
applications. In order to achieve low
VIN
10V–28V
4
10
3
SHDN
14
100pF
VCC
VSW
VIN
VD
SHDN
VC
FB
LT1777
GND
GND
12
R3
22k
7
SYNC
SGND
GND
GND
6
continued on page 29
L1B
200µH
LSENSE
0.47µH
+VOUT
5V*
5
1
8
D1
MBRS1100
12
C2**
4.7µF
+
–VOUT
–5V*
C8
1µF
10V
Table 1. Allowable load current on the –5V
supply vs input voltage and 5V load current
5V ILOAD (mA)
Maximum allowed
current on the
–5V supply (mA)
VIN = 10V
50
40
100
70
200
110
300
130
350
140
VIN = 18V
50
90
100
150
200
200
300
230
350
200
VIN = 28V
D2 MBRS1100
L1A
200µH
L1A/B: COILTRONICS CTX200-4
(561) 241-7876
LSENSE: GOWANDA SML32-470K
(716) 532-2234
C3, C7: AVX TPSD107M010R0065
(803) 946-0362
C6: 63CV1D0BS
C2: AVX 1206YG475
R1
36.5k
1%
R2
12.1k
1%
9
C4
100pF
C5
2200pF
C1
1µF
10V
C3
100µF
10V
13
+
C6
100µF
63V
noise, the LT1777 is equipped with
dI/dt limiting circuitry, which is programmed via a small external inductor
in the power path. It also contains
internal circuitry to limit the dV/dt
turn-on and turn-off ramp rates. Figure 2 shows the VSW node voltage and
the VSW node current for the low noise
LT1777. Figure 3 shows the VSW node
voltage and VSW node current for the
high voltage LT1676 buck regulator
under the same test conditions. It can
be seen from Figures 2 and 3 that the
C7
100µF
10V
* SEE TABLE 1 FOR RELATIONSHIP BETWEEN LOAD
ON +VOUT AND MAXIMUM CURRENT ON –VOUT.
** THIS IS A CERAMIC CAP, BUT A
TANTALUM CAP COULD ALSO BE USED
50
130
100
180
200
260
300
270
350
230
Figure 1. This cost-effective supply generates ±5V from a 10V–28V input.
VSW NODE
VOLTAGE
VSW NODE
VOLTAGE
10V/DIV
10V/DIV
VSW NODE
CURRENT
VSW NODE
CURRENT
200mA/DIV
200mA/DIV
500ns/DIV
Figure 2. VSW node voltage and node current for the
LT1777
Linear Technology Magazine • February 1999
500ns/DIV
Figure 3. VSW node voltage and node current for the
LT1676
27
DESIGN IDEAS
Switched Capacitor Voltage Regulator
Provides Current Gain
by Jeff Witt
A switched capacitor voltage
inverter is normally used to generate
a negative supply voltage from a positive input supply. The negative supply
current is equal in magnitude to the
current drawn from the input. This
design idea describes two circuits that
use an inverter to double the current
between the input and output,
increasing efficiency and eliminating
heat dissipation problems.
V
VIN
VIN
CAP+
GND
CAP–
CAP–
VOUT
VOUT
–V
I
Figure 1. Rewiring a switched capacitor inverter for step-down regulation results in
a current gain of 2.
charging C1 into the output. The current delivered to the output is
continuous and equal to twice the
average input current. Because the
output current is continuous, the
output voltage ripple is low. Note that
C1 and COUT do not need to be
matched, as their voltages are equalized on each cycle.
Figure 3 shows the actual circuit.
Instead of halving the input voltage,
the LT1054 modulates the input current (through switch 1 of Figure 2) to
regulate the output voltage. This cir-
1
1
3
3
VOUT
VOUT
C1
2
2
COUT
4
COUT
CURRENT FLOW
Figure 2. The LT1054’s internal switches alternately charge and discharge C1, delivering
a continuous current to the output.
28
cuit can deliver 200mA at 5V from an
input of 11.2V to 13V. Typical efficiency is 74%, compared to 42% for a
linear regulator. More importantly,
dissipation is decreased from 1.4W
for the linear regulator to 0.35W, easily managed by the LT1054’s 8-pin
surface mount package. For a 3.3V/
200mA output, the circuit is 49%
efficient, compared to a linear
regulator’s 27%, with power dissipation reduced from 1.8W to 0.7W. A
6.2Ω resistor in series with C1 shares
the dissipated power with the LT1054;
no heat sink is needed.
Three Diodes
Improve the Inverter
VIN
C1
V/2
GND
2I
VIN
4
I
CAP+
More Efficient than a Linear
If the roles of the ground and output
pins are swapped (Figure 1), an
inverter will divide the input voltage
by two. This circuit can be used in
place of a linear regulator when the
input voltage is more than twice the
desired output, for example, regulation of 12V to 5V or 3.3V.
The circuit’s operation is illustrated
in Figure 2. An internal oscillator
alternately closes and opens four
switches. In the first half cycle,
switches 1 and 2 are closed and current flows from the input to the output,
charging C1. In the second half cycle,
switches 3 and 4 are closed, dis-
V
I
The same advantages can be realized
while generating a negative output.
However, a switched capacitor inverter
does not have the right compliment of
switches. By adding three diodes (see
Figure 4), the inverter can charge two
capacitors in series and then discharge them in parallel to an output
capacitor. The absolute value of the
output voltage will equal half of the
input voltage, minus some loss due to
the switches and diodes.
Figure 5 shows a practical circuit,
which converts 12V to –4V. The
LT1054’s servo loop keeps the output
regulated to –4V over an input range
of 11V to 15V and a load current up to
Linear Technology Magazine • February 1999
DESIGN IDEAS
VIN
11V–15V
VIN
12V
8
+
10µF
+
C1*
10µF
6.8µF
V+
2
GND
CAP+
3
VOUT
5V/200mA
6
VREF
LT1054CS8
1
CAP–
4
FB/SHDN
R1
39.2k
R3*
200k
VOUT
5
+
2
C1
33µF
8
V+
CAP+
VREF
U1 LT1054CS8
10µF
D2
D1
330pF
C2
33µF
4
Figure 3. This switched capacitor regulator doubles the current
between the input and the output, increasing efficiency and
eliminating the need for a heat sink.
1
3
86.6k
C3
33µF
CAP–
VOUT
5
C1, C2, C3: AVX TAJB336M010R
C4: AVX TAJB685M025R
D1, D2, D3: MOTOROLA MBR0520LT1
Q1: IR IRLML2402
*FOR 3.3V/200mA, SET R4 = 147k, PUT 6.2Ω IN SERIES
WITH C1 AND PRELOAD WITH R4 = 2.2k
100mA. (Unfortunately, there is too
much voltage loss to regulate to –5V
from a 12V source.) Note that many
negative supplies will power loads
that can pull the output above ground
(op amp circuits in particular); Q1
prevents such a load from pulling
U1’s VOUT pin above its ground pin.
20.0k
FB/SHDN
D3
GND
R4*
33k
6
VOUT
–4V/100mA
Q1
Figure 5. This circuit converts 12V to –4V. Only 63mA of input current
is required for 100mA of output current.
Because most of U1’s operating
current flows out of its ground pin,
the input current to this circuit is a
bit more than one-half of the output
current. While delivering 100mA, the
input from 12V was measured at
64mA, resulting in 53% efficiency.
One alternative, a switched capacitor
inverter followed by a linear regulator, would be 33% efficient at best and
power dissipation would be 0.8W. This
circuit dissipates only 0.35W, allowing this all–surface mount circuit to
run cool.
VIN
VIN
1
1
3
3
2
2
4
4
VOUT
VOUT
CURRENT FLOW
Figure 4. Adding three diodes to a switched capacitor inverter doubles the current between the input and the output.
LT1777, continued from page 27
switch node voltage and current waveforms for the LT1777 are more
controlled and rise and fall more slowly
than those of the LT1676 regulator.
By slowing down the sharp edges
during turn-on and turn-off for the
power switch, conducted and radiated EMI are reduced.
The circuit in Figure 1 shows three
inductors: L1A, L1B and LSENSE. L1A
Linear Technology Magazine • February 1999
and L1B are two windings on a single
core to generate ±5V. C2 has been
added to minimize coupling mismatches between the two windings
(L1A and L1B); this forces the winding potentials to be equal and improves
cross-regulation. This creates the dual
SEPIC (single-ended primary inductance converter) topology. LSENSE is a
user-selectable sense inductor to pro-
gram the dI/dt ramp rate (see the
LT1777 Data Sheet for more information). Table 1 summarizes the
allowable load current on the –5V
supply as a function of input supply
voltage and the load current on the
5V supply. Note that 5V and –5V
supplies are allowed to droop by 0.25V,
which corresponds to 5% load
regulation.
29
DESIGN IDEAS
High Current Step-Down Conversion
from Low Input Voltages
by Dave Dwelley
VIN
3.3V
RIMAX
51k
D1
MBR0530
drive to work efficiently. Two attractive
solutions to generating 2.5V or less
from a 3.3V supply are possible using
the LTC1649 and the LTC1430A.
The LTC1649 is a switching regulator controller designed to use 5V
MOSFETs while running from an input
supply as low as 2.7V. No 5V supply
is required. The LTC1649 includes an
Q1, Q2
IRF7801
TWO IN
PARALLEL
C2 1µF
PVCC1
G1
PVCC2
IFB
R3 22Ω
C3
10µF
100
CIN
3300µF
90
LEXT
1.2µH
VOUT
2.5V/15A
R4 1k
SHDN
+
C+
C1
CC
220pF 0.01µF
CSS
0.1µF
R2
12.7k
CPOUT
C4
10µF
RIMAX
51k
C2 1µF
VCC
5V
PVCC1
1649 TA01
(310) 322-3331
(800) 441-2447
C3
10µF
CIN
3300µF
LEXT
1.2µH
VOUT
2.5V/15A
IFB
Q3
IRF7801
SENSE+
NC
COMP SENSE–
NC
SS
NC
SHDN
+
RC
7.5k
C1
220pF
+
R4 1k
G2
VCC
LTC1430A
FB
IMAX
SHDN
Q1, Q2
IRF7801
TWO IN
PARALLEL
G1
R3 22Ω
PVCC2
GND
FREQSET
R1
12.4k
+
COUT
4400µF
R2
12.7k
PGND
CC
0.01µF CSS
0.1µF
IRF7801 = INTERNATIONAL RECTIFIER
MBR0530 = MOTOROLA
(310) 322-3331
(800) 441-2447
1649 TA01
Figure 3. 3.3V to 2.5V/15A converter using a 5V auxiliary supply and the LTC1430A
30
40
1
10
LOAD CURRENT (A)
100
1649 TA02
Figure 1. 3.3V to 2.5V/15A converter using the LTC1649
D1
MBR0530
60
Figure 2. Efficiency of Figure 1’s circuit
C5
0.33µF
+
D2
MBR0530
IRF7801 = INTERNATIONAL RECTIFIER
MBR0530 = MOTOROLA
VIN
3.3V
70
0.1
C–
GND
COUT
4400µF
1µF
SS
80
50
+
VIN
COMP
RC
7.5k
R1
12.4k
Q3
IRF7801
VCC
G2
LTC1649
FB
IMAX
SHDN
+
onboard charge pump to generate the
5V gate drive that the external power
MOSFETs require. It also features an
architecture designed to use all
N-channel external MOSFETs and a
high performance voltage mode feedback loop to ensure excellent transient
response for use with high speed
microprocessors and logic.
EFFICIENCY (%)
Many modern logic systems run
with 3.3V as the sole power source. At
the same time, some modern microprocessors and ASICs require supply
voltages of 2.5V or less. Traditional
step-down switching regulators can
have difficulty running from the 3.3V
supply, because affordable power
MOSFETs generally require 5V gate
A typical circuit is shown in Figure
1. The 3.3V supply voltage at VIN is
converted to a regulated 5V output at
CPOUT. This 5V supply powers the
PVCC2 and VCC pins to provide gate
drive to Q3. Q1 and Q2 require an
additional charge-pump stage to drive
their gates above the VIN supply voltage. D1 and C2 provide this boosted
supply at PVCC1. The voltage feedback
loop is closed through R1 and R2,
with loop compensation provided by
an RC network at the COMP pin. Softstart time is programmed by the value
of CSS. Maximum output current is
set by RIMAX at the IMAX pin and is
sensed across the RDS(ON) of the Q1/Q2
pair, eliminating the need for a high
current external resistor to monitor
current. The circuit boasts efficiency
approaching 95% at 5A (Figure 2).
Some applications have a small 5V
supply available, but need to draw
the load current from the 3.3V supply. Such an application can use the
circuit shown in Figure 3, with the
continued on page 35
Linear Technology Magazine • February 1999
DESIGN IDEAS
How to Design High Order Filters with
Stopband Notches Using the LTC1562
Operational Filter (Part 2) by Nello Sevastopoulos
This is the second in a series of
articles describing applications of the
LTC1562 connected as a lowpass,
highpass or bandpass filter with added
stopband notches to increase selectivity. Part 1 (Linear Technology VIII:2,
May 1998, pp. 28–31) described one
method of coupling the four Operational Filter™ building blocks of the
LTC1562 to design an 8th order lowpass filter with two stopband notches.
Part 2 expands the technique of Part
1 to design an 8th order bandpass
filter with two stopband notches.
Throughout this series of articles,
notches will be generated by first summing the input signal with a 180
degree out-of-phase signal appearing
at the output(s) of the LTC1562
Operational Filter and second, by adjusting the summation gains to yield
a zero sum.
Part 1 showed one proprietary
method of creating notches in the
stopband of a lowpass filter. The
essence of this method is briefly
revisited in Figure 1, where two of
1/2 LTC1562
four Operational Filter sections are
coupled to form a 4th order lowpass
filter with one stopband notch. The
notch is obtained by summing the
input signal, VIN, with the output,
V1A, into the inverting node of the
next section of the IC. The two signals, VIN and V1A, will tend to cancel
each other at a frequency where they
are 180 degrees out of phase. The
cancellation will be complete if the
amplitudes of VIN and VIA yield equal
(and opposite) currents at the summing junction of the op amp of Figure
1, that is if:
RIN2 = RFF2 • (RQ1/RIN1)
(1)
In Figure 1, the lead capacitor CIN1
raises the frequency where a 180
degree phase shift occurs above the
center frequency of the 2nd order
section (fO). The resulting notch frequency is then higher than the cutoff
frequency of the 4th order filter.
Figure 1 can be easily modified to
make the frequency of the notch lower
than the center frequency of the 2nd
C
–
C R21
R1
•
•
RQ1 CIN1 RIN1
(R1 = 10k; C = 159.15pF)
and the gain conditions dictating
Equation 1 now translate to:
RIN2 = RFF2 •
(
(
RQ1 CIN1
• C
R1
(3)
The circuit of Figure 2 can be used
to build a 4th order bandpass filter
with one notch below its center
frequency. Such a filter can simultaneously detect a tone and reject an
unwanted frequency located in the
vicinity of the passband.
RFF2
RIN1
1
20
CIN1
RQ2
CIN1
R21
R21
(2)
RQ1
+
+
RQ1
1–
VIN
–
1
VIN
fN2 = fO1 •
C
RIN2
RIN1
order section from which it is derived.
This is useful in bandpass filters where
an unwanted frequency lower than
the center frequency of the filter must
be rejected. This is shown in Figure 2,
where the input signal is summed
with output V2A instead of output
V1A. The frequency of the resulting
notch is:
2
V1A
19
V1B
R22
2
V1A
LTC1562
3
3
V2A
1
sCR1
1
sCR1
18
V2B
R1, C ARE PRECISION INTERNAL COMPONENTS
R1 = 10k; C = 159.15pF
Figure 1. Two out of four Operational Filter sections are coupled to form a 4th order lowpass
filter with one stopband notch.
Linear Technology Magazine • February 1999
V2A
(OTHER CONNECTIONS
AS SHOWN IN FIGURE 1)
Figure 2. Figure 1’s circuit modified to make
the frequency of the notch lower than the
center frequency of the 2nd order section
from which it is derived.
31
DESIGN IDEAS
20
Table 1. Parameters of the four sections of an 8th order, 100kHz bandpass filter
GAIN (dB)
–20
–40
–60
–65dB
BANDWIDTH
–80
–100
–120
50 60 70 80 90 100 110 120 130 140 150
FREQUENCY (kHz)
Figure 3. Theoretical amplitude response of
8th order, 100kHz bandpass filter
The notch techniques of Figures 1
and 2 will be referred as “feedforward.” This is necessary to separate
these techniques from others to be
shown later, in Part 3 of this series of
articles.
The feedforward notch technique
of Figure 2 can be advantageously
combined with Figure 1 to realize
sharp bandpass filters with two stopband notches: one notch below and
one above the center frequency. Filters of this type can be very selective,
although they are quite cumbersome
to design. A step-by-step design procedure is illustrated below.
A Practical Example
An 8th order 100kHz bandpass filter
is realized, through FilterCAD™ for
Windows® (available at no charge from
Linear Technology—see the “Design
Tools” page in this issue), by cascading four 2nd order sections of
equal Q. The –3dB band-edges are
arithmetrically symmetric with
respect to the filter’s 100kHz center
frequency and signals below 80kHz
and above 125kHz are attenuated by
60dB or more. Figure 3 shows the
theoretical amplitude response and
Table 1 shows the desired filter
parameters, namely, the center frequencies, Qs and notch frequencies.
The filter of Figure 3/Table 1 can be
realized by decomposing the 8th order
realization into two independent 4th
order filter sections and then cascading these two 4th order sections, which
is an easier task than designing an
8th order elliptic bandpass filter all at
once. FilterCAD, in custom mode,
32
fO
99.9687e3
96.9964e3
103.0322e3
100.0000e3
Q
10.0000
10.0000
10.0000
10.0000
fN
———
129.2814e3
77.3023e3
———
should be used to perform this operation. Figure 4 and Table 2 show the
filter decomposition and the cascading sequence; note the left and right
notches. Figure 5 uses the LTC1562
Operational Filter to realize the filter
of Figure 3 as decomposed in Figure
4. The design is split into two 4th
order sections. The algorithm to
calculate the external passive components is outlined below.
In order to obtain a practical realization that closely approximates the
theoretical one, the Q of each 2nd
order section will be lowered by 15%.
(Please consult the LTC1562 final data
sheet.)
In order to follow the long and
tedious algorithm below, consider the
intuitive outline: We need to calculate
the following set of passive components for the first 4th order section:
RIN1, CIN1, R21, RQ1, and RIN2, RFF2,
R22 and RQ2. The resistors R21, RQ1,
QN
———
———
———
———
Type
BP
LPN
HPN
BP
R22 and RQ2 are easily calculated via
the expression for the center frequency, fOi, and Qi for the 2nd order
section “i.” The expression for the
notch, equation (2), involves the product of RIN1 • CIN1, so neither component
can be calculated separately. Instead,
RIN1 is calculated by considering the
maximum gain (which occurs around
the center frequency fO1) at either
node V1A or V2A. This controls premature internal clipping. Once RIN1 is
set, CIN1 is easily calculated via equation (2) for the lower band notch.
Similarly, equation (3) defines the ratio of RIN2 to RFF2, so neither of these
components can be calculated independently of the other. R FF2 is
calculated by considering the gain
factor (“GAIN”) of the 4th order filter
section at the V1B output (Figure 1/
Table 2)). Once RFF2 is set, RIN2 is
calculated via equation (3).
20
0
–20
GAIN (dB)
0
–40
–60
–80
–100
50 60 70 80 90 100 110 120 130 140 150
FREQUENCY (kHz)
50 60 70 80 90 100 110 120 130 140 150
FREQUENCY (kHz)
Figure 4. Cascading two 4th order bandpass sections to realize the filter of Figure 3.
Table 2. Filter decomposition and cascading sequence
fO1 = 96.9964k
Q1 = 10
fO2 = 99.9687k
Q2 = 10
fO3 = 100k
fN2 = 77.3k
Q3 = 10
fO4 = 103.0322k Q4 = 10 fN2 = 129.2814k
MH(s) = GAIN • N(s)/D(s)
MH(s) = GAIN • N(s)/D(s)
MGAIN = 0.2823
MGAIN = 0.1788
MN(s) = A1s(s2 + 235 • 9072 • 109)
MN(s) = A1s(s2 + 659 • 83 • 109)
MA1 = 62.8122 • 103
MA1 = 62.8319 • 103
Linear Technology Magazine • February 1999
DESIGN IDEAS
20
RIN1 = RQ1 •
I. Calculate the passive components
of the of the first 4th order
section
(fO1 = 96.9964kHz, Q = 8.5, fO2 =
99.9687kHz, Q = 8.5, fn2 =
77.3kHz)
1. Calculate the center frequencysetting resistor, R21:
(For details, please refer to the
LTC1562 data sheet.)
R21 = (100kHz/fO1)2 • 10k =
10.629k
(choose the closest 1% value,
R21 = 10.7k (1%))
2. Calculate the Q-setting resistor,
RQ1:
(For details, please refer to the
LTC1562 data sheet)
RQ1 = Q1 √R21 • 10k = 87.925k
(choose the closest 1% value,
RQ1 = 86.6k (1%))
3. Calculate the input resistor RIN1
from the following expression(s):
3a. if fO1 ≤100kHz (for LTC1562)
1+
1
(5)
2
fN22
Q12 • 1 –
fO12
(
(
Make sure, in either case 3a or 3b,
that RIN1 is greater than R21, that is,
the DC gain at pin 3 in Figure 5 is less
than unity; if not set RIN1 = R21 and
proceed to step 4a.
The expression for RIN1 sets the
gain at fO1 equal to unity at the node
of maximum swing (V1A or V2A). Note
that, for high Qs, the gain at fO1 is the
maximum gain. If you know the spectrum of the signals that will be applied
to the filter input and if internal gains
higher than unity will be allowed, the
value of RIN1 can be reduced to improve
the input signal-to-noise ratio.
4a. Use the value of RIN1, calculated above, and calculate the
value for the input capacitor
CIN1 from the notch equation (2).
0
–20
GAIN (dB)
The same design method is later
repeated to derive the passive components for the second 4th order section:
–40
–60
–65dB
BANDWIDTH
–80
–100
–120
50 60 70 80 90 100 110 120 130 140 150
FREQUENCY (kHz)
Figure 6. Measured amplitude response of
Figure 5’s filter
4b. Recalculate the value of RIN1
after CIN1 is chosen.
RIN1 = (CIN1(ideal) RIN1(ideal))/
CIN1(NPO,0402) = 96.22k
Choose the closest 1% value:
RIN1 = 95.3k (1%)
5. Calculate the frequency- and Qsetting resistors R22, RQ2, as
done in steps 1 and 2, above.
Choose the closest 1% standard
1
resistor values.
(6)
R1
R21
2
R22 = 10k (1%);
CIN1 =
fN2
•
• C
RQ1 RIN1
1–
RQ1 = 84.5k(1%)
fO12
6. Calculate the feedforward
resistor, RFF2:
1
(4) (fN1 < fO1; C = 159.15pF)
RIN1 = Q1 • R21 • 1 +
1/(R
FF2 C) = Gain • A1;
2 2
2 1 – fN2
C
=
159.15pF
Q1 •
CIN1 = 5.639pF.
fO12
The values for parameter (Gain •
Use
the
commercially
available
NPO
A1)
are provided by FilterCAD; they
RIN1 = 95.56k
type 0402 surface mount capacitor relate to the coefficients of the nuAlthough not applicable for this with the value nearest the ideal value merator of the transfer function (V1B/
example, thoroughness dictates men- of CIN1 calculated above. For instance, VIN in Figure 1); a passband AC gain of
tioning the case below:
for CIN1, choose an off-the-shelf 5.6pF unity is assumed (see Table 2). Please
3b. if fO1 ≥ 100kHz (for LTC1562)
capacitor.
note that, for a lowpass case, as in
Part 1 of this article series, the value
of (Gain • A1) is the DC gain of the
RFF2, 357k
filter and its value can be easily set
CIN1, 5.6pF
RIN2, 110k
without software assistance.
Equating the numerator of the fil16
1
INV C
VIN
INV B
R
,
84.5k
ter
transfer function with the values
RIN1, 10.7k RQ1, 86.6k
Q2
15
2
V1 C
V1 B
provided
by FilterCAD:
R22,
10k
R21,10.7k
14
3
(
( (
(
V2 C
V2 B
4
5V
0.1µF
5
6
RIN3, 294k
R23, 10k
7
RQ3, 84.5k
8
CIN3, 18pF
V–
V + LTC1562
SHDN
AGND
V2 A
V2 D
V1 A
V1 D
INV A
INV D
13
12
–5V
0.1µF
11
10
R24, 9.53k
9
RQ4, 82.5k
GAIN = 0.2823
A1 = 62.8122 • 103
A2 = (2πfN2)2 = 235.9 • 109
RIN4, 95.3k
RFF4, 332k
V1B s(s2 + ωN22)
GAIN (A1s)(s2 + A2) (7)
=
=
VIN (RFF2 • C) • D(s)
D(s)
VOUT
1562 TA03
RFF2 = 1/((Gain A1) C) = 354.35k;
C = 159.15pF
RFF2 = 357k(1%)
Figure 5. Hardware realization of the filter in Figure 3, using all four sections of an LTC1562
Linear Technology Magazine • February 1999
33
DESIGN IDEAS
VIN(RMS), fOUT = 100kHz
5
4a. Use the theoretical value for
RIN3, calculated above, and
calculate the value of the input
capacitor CIN3 from the notch
equation (2) of part 1 of this
article; for convenience this is
repeated below:
VS = ±5V
1
f 2
R
CIN3 = C • Q3 • 1 – O3
RIN3
fN42
(
0.1
0.1
1
5
(
condition for the occurrence of
a notch. For convenience, this
gain condition is repeated
below.
RIN4 = RFF4 •
RQ3
RIN3
(12)
RIN4 = 95.422k; RIN4 = 95.3k(1%)
(10)
Experimental Results
Figure 6 shows the measured amplitude response of the filter of Figure 5.
Use a commercially available NPO- The values of the passive component
type 0402 surface mount capacitor are as calculated above and as shown
with the value nearest the ideal value in Figure 5. The measured amplitude
of CIN3 calculated above. For instance, response closely approximates the
7. Solve for RIN2 by using Equation
C
IN3 = 18pF.
ideal response as synthesized by Fil(3), which dictates the gain
4b.
Recalculate the value for RIN3
terCAD. The peak frequency with
condition for the occurrence of
calculated in step 3a after CIN3
standard 1% resistor values and 5%
the notch:
is chosen.
capacitor values is 100.65kHz (0.65%
RIN2 = (RFF2 RQ1 CIN1)/(R1 C) =
108.785k; (R1,C) = (10k, 159.15pF) RIN3 = (CIN3(ideal) RIN3(ideal))/CIN3(NPO,0402) off). The higher frequency notch,
although it shows a respectable depth
RIN2 = 110k (1%)
= 300.058k
of 70dB, is not as well defined as the
RIN3 = 294k (1%)
notch below the filter’s center freII. Calculate the passive
5. Calculate the frequency- and
quency, yet the –65dB bandwidth is
components of the second 4th
Q-setting resistors, R24 and
as predicted by FilterCAD. The 10dB
order section
RQ4, as done in steps 1 and 2,
lack of the upper band notch depth is
(fO3 = 100kHz, Q3 = 8.5, fO4 =
above. Choose the nearest 1%
due to the finite speed of the internal
103.0322kHz, Q4 = 8.5, fn4 =
standard value.
op amps; they cause the practical 180
129.2814kHz)
degree phase shift frequency and the
R24 = 9.42k; R24 = 9.53k (1%)
Except for the bandpass gain
gain at V1A’s output to depart slightly
RQ4 = 82.97k; RQ4 = 82.5k (1%)
calculations, the algorithm will
from the theoretical calculations.
be the same as the lowpass
6. Calculate the feedforward
For the sake of perfection, the notch
design of Part 1 of this article.
resistor, RFF4. First equate the
depth can be easily restored by tweak1. R23 = (100kHz/fO3)2 • 10k =
numerator of the 4th order filter
ing the value of RQ3; the new RQ3 will
10k (1%)
transfer function with the
be 75k. This is shown with dashed
2. RQ3 = Q3 √R23 • 10k = 85k,
values provided by FilterCAD
lines in Figure 6. This, however, lowRQ3 = 84.5k (1%)
(see Table 2):
ers the passband gain by the ratio of
3. Calculate the input resistor RIN3
the new to the old RQ3 value, that is,
from the following expression(s):
ωO32 s2 + ωN42 (11) by about –1.0dB (you cannot fool
VOUT
s
3a. if fO3 ≤ 100kHz (for LTC1562)
=
=
•
•
V1B
mother nature). Depending on the
D(s)
RFF4 • C ωO42
2
2
(8)
application, the 10dB of additional
1 + 1 – fO3 • Q32
RIN3 = Q3 • R23 •
GAIN • A1s • (s2 + ωN42)
notch depth for 1.5dB of passband
fN42
D(s)
gain loss may be a reasonable trade.
The passband gain can also be cor2
ωO3
RIN3 = 302.41k
1
1
rected by lowering the values of either
THEN RFF4 =
•
• 2
GAIN • A1
C
ω N4
3b. if fO3 ≥ 100kHz (for LTC1562)
pair, (RFF2, RIN2) or (RFF4, RIN4), by the
GAIN = 0.1788
same amount (1.5dB). In Figure 6,
2
(9) A1 = 62.8319 • 103
fO32
the gain was restored to 0dB by chang2
RIN3 = RQ3 • 1 + 1 –
2 • Q3
ing the values of RIN2, RFF2 to 93.1k
fN4
and
300.1k respectively.
RFF4 = 334.64k, choose RFF4 = 332k
The total integrated noise was an
For fO3 = 100kHz, as in the example (1%).
impressively low 69µVRMS, allowing a
above, either expression can be used.
7. Solve for RIN4 by using equation signal-to-noise ratio well in excess of
Note that the expression for RIN3 in
(1) of Part 1 of this article,
80dB. The input signal-to-noise ratio
3b, above, is the same as expression
which dictates the gain
can be further increased if the passfor RIN1 shown in Part 1 of this article.
VOUT(RMS), fOUT = 100kHz
CIN3 = 17.86pF;
Figure 7. Gain linearity of Figure 5’s filter,
measured at the 100kHz theoretical center
frequency
(
(
34
(
(
Linear Technology Magazine • February 1999
CONTINUATIONS
range. This is true provided the filter
magnitude response does not change
with varying input signal levels, that
is, the filter gain is linear. The gain
linearity measured at the 100kHz
theoretical center frequency of the
filter is shown in Figure 7. The gain is
perfectly linear for input amplitudes
up to 1.25VRMS (3.5VP-P) so an 84dB
dynamic range can be claimed. The
input signal, however, can reach amplitudes up to 3VRMS (8.4VP-P, 92dB
SNR) with some reduction in gain
linearity.
The LTC1735 and LTC1736 are the
latest members of Linear Technology’s
family of constant frequency, N-channel high efficiency controllers. With
new protection features, improved circuit operation and strong MOSFET
drivers, the LTC1735 is an ideal upgrade to the LTC1435/LTC1435A for
higher current applications. With the
integrated VID control, the LTC1736
is ideal for CPU power applications.
The high performance of these controllers with wide input range, 1%
reference and tight load regulation
makes them ideal for next generation
designs.
LTC1562-2, continued from page 10
References
level is 44µVRMS over a bandwidth of
800kHz or 98dB below the maximum
unclipped output.
1. Hauser, Max. “Universal Continuous-Time Filter Challenges Discrete
Designs.” Linear Technology VIII:1
(February 1998), pp. 1–5 and 32.
2. Sevastopoulos, Nello. “How to Design High Order Filters with Stopband
Notches Using the LTC1562 Quad
Operational Filter, Part 1.” Linear
Technology VIII:2 (May 1998), pp.
28-31.
3. Sevastopoulos, Nello. “How to Design High Order Filters with Stopband
Notches Using the LTC1562 Quad
Operational Filter, Part 2.” in the Design Ideas section of this issue of
Linear Technology.
4. LTC1562 Final Data Sheet.
5. For example: Schwartz, Mischa.
Information Transmission, Modulation, and Noise, fourth edition, pp.
180–192. McGraw-Hill 1990.
band gain can be higher than 0dB or
if internal nodes are allowed to have
gains higher than 0dB. Please contact the LTC Filter Design and
Applications Group for further details.
The low noise behavior of the filter
makes it useful in applications where
the input signal has a wide voltage
LTC1735/LTC1736, continued from page 6
Conclusion
Acknowledgments
Philip Karantzalis and Nello Sevastopoulos of LTC’s Monolithic Filter
Design and Applications Group contributed to the application examples.
LT1505, continued from page 25
By doing so, the required peak power
from the wall adapter can be much
lower than the peak power required
by the load. The wall adapter has to
supply the average power only.
The LT1505 can also be used in other
system topologies, such as the telecom application shown in Figure 5.
The circuit in Figure 5 uses the battery to supply peak power demands.
Conclusion
The LT1505 is a complete, singlechip battery charger solution for
today’s demanding charging requirements in high performance laptop
applications. The device requires a
small number of external components
and provides all necessary functions
for battery charging and power management. High efficiency and small
size allow for easy integration with
the laptop circuits. Also, by adding a
simple external circuit, charging can
be easily controlled by the host computer, allowing for more sophisticated
charging schemes.
Step-Down Conversion, continued from page 30
cuitry works in the same manner as
in Figure 1. Efficiency and performance are virtually the same as the
LTC1649 solution, but parts count
and system cost are lower.
In a 3.3V to 2.5V application, the
steady-state, no-load duty cycle is
76%. If the input supply drops to
3.135V (3.3V – 5%), the duty cycle
requirement rises to 80% at no load,
and even higher under heavy or
transient load conditions. Both the
LTC1649 and the LTC1430A guarantee a maximum duty cycle of greater
than 90% to provide acceptable load
regulation and transient response.
The standard LTC1430 (not the
LTC1430A) can max out as low as
83%—not high enough for 3.3V to
2.5V circuits. Applications with larger
step-down ratios, such as 3.3V to
2.0V, can use the circuit in Figure 3
successfully with a standar d
LTC1430.
SW, VBAT and GND in Figure 2 will
help in spreading the heat and will
reduce the power dissipation in conductors and MOSFETs.
Other Applications
lower cost LTC1430A replacing the
LTC1649. The LTC1430A does not
include the 3.3V to 5V charge pump
and requires a 5V supply to drive the
external MOSFET gates. The current
drawn from the 5V supply depends
on the gate charge of the external
MOSFETs but is typically below 50mA,
regardless of the load current on the
2.5V output. The drains of the Q1/Q2
pair draw the main load current from
the 3.3V supply. The remaining cirLinear Technology Magazine • February 1999
35
DESIGN INFORMATION
The LTC1658 and LTC1655: Smallest
Rail-to-Rail 14-Bit and 16-Bit DACs
by Hassan Malik
These DACs have a flexible 3-wire
serial interface that is SPI/QSPI and
MICROWIRE compatible.
Figures 1 demonstrates the ease of
using the LTC1658. The output swings
from 0V to VREF at full-scale. VREF
should be less than or equal to VCC to
prevent the loss of codes and degradation of PSRR near full-scale. The input
serial data is loaded as one 16-bit
word with two dummy bits. The digital
inputs are TTL/CMOS level compatible and the CLK input has an internal
Schmitt trigger for noise immunity.
This allows direct optocoupler interfacing to the part. Figure 2 plots the
part’s 0.25LSB typical DNL.
Expanding the rail-to-rail, voltage
output DAC family, Linear Technology introduces two new voltage output
DACs that break the size/bits barrier. The LTC1658 is a 14-bit
rail-to-rail voltage output DAC in a
tiny MSOP-8 package and the
LTC1655 is a 16-bit voltage output
DAC in an SO-8 package. Both of
these DACs also provide a convenient
upgrade path for users of LTC’s 12bit voltage output DAC family. The
LTC1658 draws only 270µA from a
3V or 5V supply and is 14-bit monotonic over temperature. The LTC1655
draws 600µA from a 5V supply and is
16-bit monotonic over temperature.
2.7V TO 5.5V
8
6
REF
VCC
2 DIN
µP
3 CS/LD
+
16-BIT
SHIFT
REG
AND
DAC
LATCH
1.0
VOUT
14
14-BIT
DAC
RAIL-TO-RAIL
VOLTAGE
OUTPUT
7
–
4 DOUT
POWER-ON
RESET
TO
OTHER
DACS
0.8
0.6
DNL ERROR (LSB)
1 CLK
A typical application for the
LTC1655 is shown in Figure 3. The
LTC1655 has the same interface as
the LTC1658 and is also capable of
being daisy chained. There is an
onboard 2.048V bandgap reference
connected internally to the 16-bit
DAC. The rail-to-rail output nominally swings from 0V to 4.096V, since
there is a gain of two in the output
amplifier. The reference pin can be
overdriven to a value higher than
2.048V if a larger output swing is
desired. Since there is a gain of 2 from
the reference pin to the output at fullscale, the voltage on the REF pin
must always be less than VCC /2.
Figure 4 plots the typical DNL of the
LTC1655.
0.4
0.2
0
– 0.2
– 0.4
– 0.6
GND
1658 TA01
– 0.8
5
– 1.0
0
4096
Figure 1. LTC1658 block diagram
8192
CODE
12288
16383
1658 TA02
4.5V TO 5.5V
8
1 CLK
µP
3 CS/LD
2.048V
6
REF
1.0
REF
+
16-BIT
SHIFT
REG
AND
DAC
LATCH
16
16-BIT
DAC
–
0.8
VOUT
7
RAIL-TO-RAIL
VOLTAGE
OUTPUT
4 DOUT
TO
OTHER
DACS
POWER-ON
RESET
0.6
DNL ERROR (LSB)
VCC
2 DIN
Figure 2. The LTC1658 14-bit rail-to-rail
DAC in MSOP has 0.25LSB typical DNL.
0.4
0.2
0
– 0.2
– 0.4
– 0.6
– 0.8
GND
5
1658 TA01
– 1.0
0
16384
32768
CODE
49152
65535
1658 TA02
Figure 3. LTC1655 block diagram
36
Figure 4. LTC1655 typical DNL plot
Linear Technology Magazine • February 1999
NEW DEVICE CAMEOS
New Device Cameos
LTC1502-3.3
Single Cell to 3.3V
Inductorless DC/DC Converter
The LTC1502-3.3 is LTC’s latest
offering in the regulated charge pump
arena. This new charge pump is the
only inductorless single-cell boost
converter in the industry. The part
employs a quadrupler switched
capacitor architecture to generate a
regulated 3.3V supply from a single
NiCd or alkaline cell. Start-up
enhancement circuitry enables the
LTC1502-3.3 to power up with VIN as
low as 0.8V. Only five small ceramic
capacitors are required to make a
complete 3.3V single-cell power supply with 10mA of output load
capability.
The part also has a shutdown feature that disconnects the load from
VIN and reduces quiescent current to
only 5µA. The LTC1502-3.3 is shortcircuit protected and can survive an
indefinite VOUT short to GND. Small
size (8-pin MSOP package) and low
quiescent current (40µA typical) make
the LTC1502-3.3 ideal for space conscious, low power applications such
as pagers and PDAs. Since the VOUT
pin is high impedance during shutdown, the part is also well suited for
single-cell battery backup applications.
LTC1661 Micropower Dual
10-Bit DAC with Sleep Mode
Available in MS-8
The LTC1661 is a micropower, dual,
10-bit voltage-output DAC that is
available in a tiny 8-pin MSOP package. Required board area is only
0.01in2 per DAC.
Operating on a single 2.7–5.5V
supply, the LTC1661 draws just 60µA
per DAC (120µA total for the part) for
true micropower performance. Sleep
mode further reduces total supplyplus-reference current to just 1µA.
The LTC1661 is guaranteed monotonic over temperature—differential
nonlinearity error is typically ±0.2LSB
(±0.75LSB Max). Each DAC has a
Linear Technology Magazine • February 1999
gain of 1 from reference to output; the
Reference pin can be tied to VCC for
full rail-to-rail operation. The output
amplifiers are stable driving capacitive loads of up to 1000pF and can
source or sink up to 5mA. The outputs swing to within a few millivolts of
either supply rail when unloaded and
have an equivalent output resistance
of 85Ω when driving a load to the
rails.
The 3-wire serial interface uses a
16-bit input word comprising 4 control bits, 10 input-code bits, and 2
don’t-care bits. Power-on reset is also
provided. The input logic is double
buffered for additional flexibility in
interfacing with the microprocessor
and for more effective control of multiple chips that share clock and data
lines.
Low supply current, power-saving
Sleep mode and extremely compact
size make the LTC1661 ideal for battery-powered applications, while its
straightforward usability, high performance and wide supply range make
it an excellent choice as a generalpurpose converter.
LTC1841/LTC1842/LTC1843
Dual Micropower Comparator
with Built-In Reference
The LTC1841/LTC1842/LTC1843
are dual micropower comparators
with built-in references (LTC1842/
LTC1843). These parts feature less
than 5.7µA supply current over temperature, a 1.182V ±1% reference
(LTC1842/LTC1843), programmable
hysteresis (LTC1842/LTC1843) and
open-drain output comparators that
can sink greater than 20mA. The reference output can drive a bypass
capacitor of up to 0.01µF without
oscillation.
The comparators operate from
single 2V to 11V supplies or ±1V to
±5.5V supplies (LTC1841). Comparator hysteresis is easily programmed
using two resistors and the HYST pin.
The comparator’s input operates from
the negative supply to within 1.3V of
the positive supply. The comparator
output stage can typically sink greater
than 20mA. By eliminating the crossconduction current that normally
occurs when the comparator changes
logic states, power supply glitches
are eliminated.
The LTC1841/LTC1842/LTC1843
are available in 8-pin SO packages.
LTC1605-1/-2: 100ksps
16-Bit ADC Now Available
with 0V to 4V and ±4V
Analog Input Ranges
The LTC1605-1 and LTC1605-2 are
the newest members of Linear
Technology’s family of 16-bit ADCs.
The two new ADCs offer the user a
choice of analog input ranges to help
make full use of the wide dynamic
range offered by these converters.
These 100ksps sampling ADCs feature 16-bit resolution with no missing
codes and ±2LSB INL. They operate
from a single 5V supply with typical
power dissipation of only 55mW. They
are offered in both 28-pin PDIP and
SSOP packages.
The LTC1605-1 has an analog input
range of 0V to 4V with ±20V overvoltage protection. This 16-bit ADC is
ideally suited for single-supply systems. It is a complete data acquisition
system containing a differential, successive-approximation A/D that uses
switched capacitor technology to perform a 16-bit conversion. The analog
front end consists of a resistor divider
network followed by a sample-andhold that allows fast moving signals
to be digitized. The LTC1605-1 also
has a trimmed bandgap reference that
can be overdriven with an external
reference if greater accuracy is needed.
It also features a simple parallel I/O
where the digital output word can be
read as a 16-bit word or as two 8-bit
bytes. The digital output word format
for the LTC1605-1 is straight binary.
The LTC1605-2 has a bipolar analog input range of ±4V with ±20V
overvoltage protection (±15V overdrive
recoverable) operating on a single 5V
supply. It is also a complete data
acquisition system with the same features and parallel I/O as the
37
NEW DEVICE CAMEOS
LTC1605-1. The LTC1605-2 digital
output word format is two’s
complement.
LTC1754-5 Regulated Charge
Pump Delivers 50mA in an
SOT-23 Package
The LTC1754-5 is the newest addition to Linear Technology’s industry
leading family of switched capacitor
regulated charge pumps. Combining
the best features of its predecessors,
it delivers a full 50mA from a tiny
SOT-23 package while stepping up
from 3V to a regulated 5V. The 6-pin
package provides additional functionality by including shutdown
capability. Finally, it has built-in thermal shutdown circuitry that allows it
to survive a continuous short circuit
to ground at its output.
The quiescent supply current of
the LTC1754-5 is only 13µA. This low
supply current means very low power
consumption in light load
applications. Furthermore, because
it uses Burst Mode operation, its
efficiency is typically 82.7% when
delivering moderate to high load current. This efficiency is very close to
the ideal 83.3% for a 3V to 5V regulating charge pump. In shutdown, the
supply current is guaranteed to be
less than 1µA.
With no inductors and only three
small capacitors, the LTC1754-5 regulated charge pump delivers significant
power from a small amount of real
estate.
LTC1569-7: Unique 10th
Order, Linear-Phase, DC
Accurate Lowpass Filter is
Tunable by a Single Resistor
The LTC1569-7 is a self-contained
10th order linear-phase filter featuring cutoff frequencies up to 256kHz
while operating on supplies from 3.3V
(3V minimum) up to ±5V. Cutoff frequencies up to 128kHz can also be
obtained with a 3V (2.7V minimum)
supply. Unlike other monolithic filters, the LTC1569-7’s precision
on-chip oscillator allows the cutoff
for
the latest information
on LTC products,
visit
www.linear-tech.com
frequency to be set accurately (within
2%) by a single resistor. Alternatively,
for swept cutoff frequency applications, an external clock can be used.
The amplitude response of the
LTC1569-7 approximates a root raised
cosine, with an alpha of 0.5, for phase
linearity with excellent attenuation.
The attenuation of the LTC1569-7 at
1.5 times the cutoff frequency is 55dB,
whereas attenuation is in excess of
60dB at 2.1 times the cutoff frequency.
The DC offset of the LTC1569-7 is
typically 2mV. Its DC gain linearity
and SINAD are suitable for 12-bit
systems. The input of the filter can be
configured as single ended or
differential.
When operated at full bandwidth,
the LTC1569-7 consumes 20mA on a
single 5V supply but, when slower
sampling rates are required (that is,
at lower cutoff frequencies), the device
automatically switches to a reduced
supply current, which can be as low
as 5mA. The LTC1569-7 is available
in an 8-pin SO package.
Authors can be contacted
at (408) 432-1900
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.
38
Linear Technology Magazine • February 1999
DESIGN TOOLS
DESIGN TOOLS
Applications on Disk
Technical Books
FilterCAD™ 2.0 CD-ROM — This CD is a powerful filter
design tool that supports all of Linear Technology’s high
performance switched capacitor filters. Included is FilterView™, a document navigator that allows you to
quickly find Linear Technology monolithic filter data
sheets, the FilterCAD manual, application notes, design
notes and Linear Technology magazine articles. It does
not have to be installed to run FilterCAD. It is not
necessary to use FilterView to view the documents, as
they are standard .PDF files, readable with any version
of Adobe Acrobat™. FilterCAD runs on Windows® 3.1 or
Windows 95. FilterView requires Windows 95. The
FilterCAD program itself is also available on the web and
will be included on the new LinearView™ CD.
Available at no charge.
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
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.
Information furnished by Linear Technology Corporation
is believed to be accurate and reliable. However, Linear
Technology makes no representation that the circuits
described herein will not infringe on existing patent rights.
Linear Technology Magazine • February 1999
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
1994 Linear Databook, Vol III —This 1826 page supplement to the 1990 and 1992 Linear Databooks is a
collection of all products introduced since 1992. A total
of 152 product data sheets are included with updated
selection guides. The 1994 Linear Databook Vol III is a
companion to the 1990 and 1992 Linear Databooks,
which should not be discarded.
$10.00
1995 Linear Databook, Vol IV —This 1152 page supplement to the 1990, 1992 and 1994 Linear 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
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
notes and Linear Technology magazines.
$20.00
1998 Data Converter Handbook — This impressive
1360 page handbook includes all of the data sheets,
application notes and design notes for Linear
Technology’s family of high performance data converter
products. Products include A/D converters (ADCs), D/A
converters (DACs) and multiplexers—including the fastest monolithic 16-bit ADC, the 3Msps, 12-bit ADC with
the best dynamic performance and the first dual 12-bit
DAC in an SO-8 package. Also included are selection
guides for references, op amps and filters and a glossary
of data converter terms.
$10.00
Interface Product Handbook — This 424 page handbook features LTC’s complete line of line driver and
receiver products for RS232, RS485, RS423, RS422,
V.35 and AppleTalk® applications. Linear’s particular
expertise in this area involves low power consumption,
high numbers of drivers and receivers in one package,
mixed RS232 and RS485 devices, 10kV ESD protection
of RS232 devices and surface mount packages.
Available at no charge
Power Solutions Brochure — This collection of circuits contains real-life solutions for common power
supply design problems. There are over 70 circuits,
including descriptions, graphs and performance
specifications. Topics covered include battery chargers,
power supplies for desktop and portable computers,
supplies for portable electronics, telecommunications
supplies, offline supplies and various other power management techniques, including Hot Swap™ circuits.
Available at no charge
Data Conversion Solutions Brochure — This 64 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 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
39
DESIGN TOOLS, continued from page 39
CD-ROM Catalog
LinearView — LinearView™ CD-ROM version 3.0 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–VI) 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 runs under Windows 95 and Macintosh® System 8.0 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 internet web site. Located at www.lineartech.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
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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.
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Linear Technology Magazine • February 1999