TOKO TK65025

TK65025
STEP-UP VOLTAGE CONVERTER WITH VOLTAGE MONITOR
FEATURES
APPLICATIONS
■
■
■
■
■
■
■
■
■
■
■
■
■
■
■
■
■
Guaranteed 0.9 V Operation
Very Low Quiescent Current
Internal Bandgap Reference
High Efficiency MOS Switching
Low Output Ripple
Microprocessor Reset Output
Laser-Trimmed Output Voltage
Laser-Trimmed Oscillator
Undervoltage Lockout
Regulation by Pulse Burst Modulation (PBM)
Battery Powered Systems
Cellular Telephones
Pagers
Personal Communications Equipment
Portable Instrumentation
Portable Consumer Equipment
Radio Control Systems
2
DESCRIPTION
The TK65025 Low Power Step-Up DC-DC converter is
designed for portable battery-powered systems, capable
of operating from a single battery cell down to 0.9 V. The
TK65025 provides the power switch and the control circuit
for a boost converter. The converter takes a DC input and
boosts it up to 3 volts. This regulated 3 volt output is
typically used to supply power to a microprocessor-controlled system.
The output voltage is laser-trimmed to 3.0 V. An
internal detector monitors the output voltage and provides
an active-low microprocessor reset signal whenever the
output voltage falls below an internally preset limit. An
internal undervoltage lockout circuit is utilized to prevent
the inductor switch from remaining in the "ON" mode when
the battery voltage is too low to permit normal operation.
Pulse burst modulation (PBM) is used to regulate the
voltage at the VOUT pin at the IC. PBM is the process in
which an oscillator signal is gated or not gated to the switch
drive each period. The decision is made just before the
start of each cycle and is based on comparing the output
voltage to an internally-generated bandgap reference. The
decision is latched, so the duty ratio is not modulated within
a cycle. The average duty ratio is effectively modulated by
the "bursting" and skipping of pulses which can be seen at
the IND pin of the IC. Special care has been taken to
achieve high reliability through the use of Oxide, double
Nitride passivation. The TK65025 is available in a very
small plastic surface mount package. (SOT-23L)
Customized levels of accuracy in oscillator frequency
and output voltage are available.
TK65025M
VIN 1
6 RESET
5
M2
GND 2
5 GND
4 VOUT
IND 3
BLOCK DIAGRAM
ORDERING INFORMATION
IND
V OUT
3
4
V REF
TK65025M
V IN
1
CONTROL
CIRCUIT
UVLO
6
RESET
Tape/Reel Code
RC OSC.
2,5
TAPE/REEL CODE
GND
BX : Bulk/Bag
TL : Tape Left
February, 1997 Toko, Inc.
Page 1
TK65025
ABSOLUTE MAXIMUM RATINGS
All pins except GND ................................................... 6 V
Power Dissipation (Note1) ................................. 400 mW
Storage Temperature Range ................... -55 to +150 °C
Operating Temp. Range ............................-20 to + 80 °C
Junction Temperature ........................................... 150 °C
ELECTRICAL CHARACTERISTICS
Over operating temperature range and supply voltage range, unless otherwise specified.
SYMBOL
PARAMETER
TEST CONDITION
VIN
Supply Voltage Range (Note 2, 5)
IB(Q)
No Load Battery Current (Note 5)
VI = 1.3 V, IO = 0 mA, TA = 25 °C
I (VIN)
Quiescent current into VIN pin
I (VOUT)
MIN
TYP
0.90
MAX
UNIT
1.60
V
80
120
µA
VIN = 1.3 V IO = 1mA, TA = 25 °C
20
35
µA
Quiescent current into VOUT pin
VOUT = VOUT (REG) +20 mV, TA = 25 °C
22
34
µA
ƒ(OSC)
Internal oscillator frequency
TA = 25 °C
83
102
kHz
∆ƒ(OSC)/∆T
Temperature stability of oscillator
VIN = 1.3 V , IO = 1mA
VOUT(REG)
Regulation threshold of VOUT
TA = 25 °C
∆V OUT/∆T
Temperature stability of VOUT(REG) VIN = 1.3 V, IO = 1mA
70
800
2.85
3.00
ppm/°C
3.10
250
∆V OUT(LOAD) Load regulation of VOUT(REG) (Note 2) VIN = 1.3 V, IO = 0→4 mA
V
ppm/°C
0
mV
∆V OUT(LINE)
Line regulation of VOUT(REG)
∆V IN = 0.25 V, IO = 1mA
-20
VOUT(RST)
VOUT during reset transition
VIN = 1.3 V, TA = 25 °C
2.48
VRST(HI)
Logic High of RESET w/r/t VOUT
VO ≥ 2.6 V
-100
VRST(LO)
Logic Low of RESET
VO ≤ 2.5 V
∆V OUT(RST)
VOUT(RST) threshold hysteresis
TA = 25 °C
45
mV
RSW(ON)
On-resistance of switch, IND pin
VOUT = VOUT(REG), TA = 25 °C
1
ohm
D(OSC)
On-time duty ratio of oscillator
η
Converter efficiency (Notes 4,5)
VI = 1.3 V, IO = 4 mA
74
%
VUVL
Undervoltage lockout threshold
TA = 25 °C IO = 1mA
0.74
V
IO(MAX)
Maximum IO for converter (Notes 3,5) VI ≥ 1.1 V, VO Regulated
TEST CIRCUIT
RN
1K
CN
10 µF
6
GND
2
S
300 kΩ
3
4
S
S
CS
S
S
220 pF
RS
D
CU
10 µF
Inductor L: Toko 682AE-014 or equivalent
Diode D: LL103A or equivalent
Capcitors CN : CU; C D: Panasonic TE series, ECS-T0JY106R
+
S
15
VO
+
CD
10 µF
S
1K
Page 2
mV
50
mV
64
4
%
mA
Note 3: Maximum load current depends on inductor value. With a 0.9 V or 1.0
V supply voltage, 4 mA can be obtained with a smaller inductor value.
IO
ROF
IB
VI
V
5
VOUT
IND
L = 95 µH
2.70
Note 2: Specifications are tested to 1.6 V. Device is suitable for dual cell
operation.
S
GND
mV
Note 1: Derate at 0.8 mW/oC for operation above TA = 25 oC ambient temperature, when heat conducting copper foil path is maximized on the printed circuit
board. When this is not possible, a derating factor of 1.6 mW/ °C must be used.
RR
RESET
1
20
100
36
RESET
VIN
+S
0
Note 4: Output ripple depends on filter capacitor values, ESRs and the
connection of (VOUT) sense point.
S
Note 5: When using specified TOKO inductor and Schottky diode with VF=0.45
V @ 100 mA. By trading component size for better specifications, using
Schottky diode with lower forward voltage, efficiency greater than 80% can be
attained.
February, 1997 Toko, Inc.
TK65025
TYPICAL PERFORMANCE CHARACTERISTICS
OUTPUT VOLTAGE
vs. LOAD CURRENT
OSCILLATOR FREQUENCY vs.
TEMPERATURE
3.1
L = 100 µH
Toko P/N: 636CY101M
(D73 series)
TA = 25 °C
3.0
95
110
No Load
2.5 V
2.9
2.0 V
IB(µA)
ƒ
(kHz)
(OSC)
1.6 V
VIN = 1.3 V
100
90
VIN 0.9
: V
VO(V)
BATTERY CURRENT vs.
TEMPERATURE
85
90
80
1.3 V
2.8
90
70
2.7
1
10
IO(mA)
75
-75
100
-25
4
OUTPUT VOLTAGE
vs. LOAD CURRENT
3.0
VOUT(REG) (V)
2.5 V
VO(V)
60
-75
125
2.0 V
1.6 V
1.3 V
25
-25
75
125
TA(°C)
2
3
BATTERY CURRENT
vs INPUT VOLTAGE
200
3.000
TA = 25 °C
No Load
2.995
100
2.990
IB(µA)
L = 95 µH
Toko P/N:
A682AE014=P3
(3DF series)
TA = 25 °C
2.8
75
OUTPUT REGULATION VOLTAGE
vs. TEMPERATURE
3.1
2.9
25
T (°C)
A
2.985
2.980
Vin 0
: .9 V
2.7
2.975
-75
100
10
IO(mA)
10
-25
5
AA
AA
AAAAAAA
A
OUTPUT VOLTAGE
vs. LOAD CURRENT
90
L = 47 µH
Toko P/N:
636FY-470M
(D73 series) 85
TA = 25 °C
2.5 V
VO(V)
3.0
1.3 V
2.7
1
10
IO(mA)
100
6
February, 1997 Toko, Inc.
1
1.5
VI(V)
2
2.5
3
MAXIMUM OUTPUT CURRENT vs.
INDUCTOR VALUE (µH)
16
0.9 V
80
75
70
65
60
0.1
.5
7
2.5 V
2.0 V
2.8
0
125
1
1.6 V
VIN :0.9 V
2.9
75
EFFICIENCY vs. LOAD CURRENT
η(%)
3.1
25
TA(°C)
1
ROF = 0
L = 100 µH
Toko P/N 636CY-101M
D73 Series
TA = 25 °C
10
100
IO(mA)
8
VOUT = 2.5 V
TA = 25 °C
14
OUTPUT CURRENT (mA)
1
VIN = 1.3 V
12
10
8
6
4
2
VIN = 0.9 V
0
0
80
160 240 320 400
INDUCTOR VALUE (µH)
440
Page 3
9
2
TK65025
SINGLE-CELL APPLICATION
The TK65025 is a boost converter control IC with the
power MOSFET switch built into the device. It operates
from one or two battery cells and steps up the output
voltage to a regulated 3.0 Volts. The device operates at a
fixed nominal clock frequency of 83 kHz. The analysis is
easier to follow when referencing the test circuit below.
RESET
RN
VIN
+
1K
CN
10 µF
6
GND
300 kΩ
5
VOUT
IND
3
L = 95 µH
S
GND
2
S
RR
RESET
1
S
4
VI
S
S
CS
IO
ROF
IB
S
S
220 pF
R
S
D
+
CU
10 µF
S
15
VO
+
CD
10 µF
S
S
1K
The Test Circuit shown here is identical with the one
shown on page 2 of the TK65025 data sheet.
RIPPLE AND NOISE CONSIDERATIONS
In its simplest form, a power converter using the TK65025
requires only three external components: an inductor, a
diode, and a capacitor (see figure below).
VIN
1
GND
2
IND
3
VI
S
S
RESET
6
GND
5
VOUT
4
S
+
S
VO
Compared to the test circuit, this means eliminating the
following circuitry: the RC filter into the Vin pin, the RC
snubber, the RC filter at the converter output, and the
pullup resistor to the reset pin. The RC filter at the Vin pin
is used only to prevent the ripple voltage at the battery
terminals from prematurely causing under-voltage lockout
of the IC. This is only needed when the inductor value is
relatively small and the battery resistance is relatively high
and the Vin range must extend as low as possible. The RC
Page 4
snubber dampens the ringing which occurs during the
deadtime, but this provides only a limited noise reduction,
so it isn’t required. The RC filter at the converter output
attenuates the conducted noise - the converter doesn’t
require this either. Finally, the pullup resistor at the reset
pin is needed only if the reset output signal is used. Most
of this circuitry which appears in the test circuit has been
added to minimize ripple and noise effects. But when this
is not critical, the circuit can be minimized.
When any DC-DC converter is used to convert power
in RF circuits (e.g., pagers) the spectral noise generated
by the converter, whether conducted or radiated, is of
concern. The oscillator of the TK65025 has been trimmed
and stabilized to 83 +/– 4 kHz with the intention of greatly
minimizing interference at the common IF frequency of
455 kHz. In comparison with conventional IC solutions,
where the oscillator frequency is not controlled tightly, the
TK65025 can achieve as much as 20-30 dB improvements in RF interference reduction by means of its accurately controlled oscillator frequency. This IF frequency is
halfway between the fifth and sixth harmonics of the
oscillator. The fifth harmonic of the maximum oscillator
frequency and the sixth harmonic of the minimum oscillator frequency still leave a 39 kHz band centered around
455 kHz within which a fundamental harmonic of the
oscillator will not fall. Since the TK65025 operates by
pulse burst modulation (PBM), the switching pattern can
be a subharmonic of the oscillator frequency. The simplest example and the one most to be avoided is that of the
converter causing every other oscillator pulse to be skipped.
That means that the switching pattern would have a
fundamental frequency of one-half the oscillator frequency,
or 41.5 kHz - the eleventh harmonic of which lands at
456.5 kHz, right in the IF band. Fortunately, the energy is
rather weak at the eleventh harmonic - and even more
fortunate is the ease with which that regulation mode is
avoided. Due to a finite hysteresis in the regulator comparator, when an additional output filter is used (e.g., the
RC filter of the test circuit, or an LC filter) this minimizes the
ripple at the regulation node which limits the rate at which
the oscillator can be gated. In practice, this means that
rather than exhibiting a switching pattern of skipping every
other oscillator pulse, it would be more likely to exhibit a
switching pattern of three or four pulses followed by that
many pulses skipped. Although this also tends to increase
the output ripple, it is low frequency and has low magnitude (e.g., 10 kHz and 10 mV) which tends to be of little
consequence.
February, 1997 Toko, Inc.
TK65025
Theory of Operation
The converter operates with one terminal of an inductor
connected to the DC input and the other terminal connected to the switch pin of the IC. When the switch is
turned on, the inductor current ramps up. When the switch
is turned off (or “lets go” of the inductor), the voltage flies
up as the inductor seeks out a path for its current. A diode,
also connected to the switching node, provides a path of
conduction for the inductor current to the boost converter’s
output capacitor. The TK65025 monitors the voltage of the
output capacitor and has a 3 volt threshold at which the
converter switching becomes disactivated. So the output
capacitor charges up to 3 volts and regulates there,
provided that we don’t draw more current from the output
than the inductor can provide. The primary task, then, in
designing a boost converter with the TK65025 is to determine the inductor value which will provide the amount of
current needed to guarantee that the output voltage will be
able to maintain regulation up to a specified maximum load
current. Secondary tasks include choosing the diode,
output capacitor, snubber, and filtering if desired.
The TK65025 runs with a fixed oscillator frequency and
it regulates by applying or skipping pulses to the internal
power switch. This regulation method is called pulse burst
modulation (PBM).
Reset Feature
The TK65025 also features an output voltage monitor
which provides a reset signal to a microprocessor or other
external system controller. When the output voltage is
below the reset threshold (which is less than the regulation
threshold), the reset signal is asserted low, indicating that
the system controller (e.g., microprocessor) should be in
a reset mode. Such a condition might exist during startup
of the converter or under an overload fault condition. This
method of reset control can be used to prevent improper
system operation which might occur at low supply voltage
levels.
The TK65025 has a reset threshold between 2.48 and
2.70 volts.
Analysis of a Switching Cycle
Although the derivation of equations is not discussed,
the user will more easily be able to understand (and if
desired, reproduce) the design equations if we begin by
more precisely describing how the converter operates
over a switching cycle.
From an oscillator standpoint, the switching cycle consists of only an on-time and an off-time. But from an
February, 1997 Toko, Inc.
inductor current standpoint, the switching cycle breaks
down into three important sections: on-time, off-time, and
deadtime. The on-time of the switch and the inductor
current are synonymous. During the on-time, the inductor
current increases. During the off-time of the switch, the
inductor current decreases as it flows into the output.
When the inductor current reaches zero, that marks the
end of the inductor current off-time. For the rest of the
cycle, the inductor current remains at zero. Since no
energy is being either stored or delivered, that remaining
time is called deadtime. This mode of the inductor current
decaying to zero every cycle is called discontinuous mode.
In summary, energy is stored in the inductor during the
on-time, delivered to the output during the off-time, and
remains at zero during the deadtime.
Unless otherwise specified, the term off-time refers to
the inductor current, not to the switch.
Inductor Selection
It is under the condition of lowest input voltage that the
boost converter output current capability is the lowest for
a given inductance value. Three other significant parameters with worst case values for calculating the inductor
value are: highest switching frequency, lowest duty ratio
(of the switch on-time to the total switching period), and
highest diode forward voltage. Other parameters which
can affect the required inductor value, but for simplicity will
not be considered in this first analysis are: the series
resistance of the DC input source (i.e., the battery), the
series resistance of the internal switch, the series resistance of the inductor itself, ESR of the output capacitor,
input and output filter losses, and snubber power loss.
The converter reaches maximum output current capability
when the switch runs at the oscillator frequency, without
pulses being skipped. The output current of the boost
converter is then given by the equation:
2
IO =
(
VI D
2
2 f L VO + VF − VI
)
2
(1)
where “VI” is the input voltage, “D” is the on-time duty ratio
of the switch, “f ” is the switching (oscillator) frequency, “L”
is the inductor value, “VO” is the output voltage, and “VF” is
the diode forward voltage. It is important to note that this
equation makes the assumption stated in equation form:
(
)
V I ≤ V O + V F (1 - D )
(2)
The implication from Eq. (2) is that the inductor will
operate in discontinuous mode. From a practical
Page 5
2
TK65025
standpoint for the TK65025, this is essentially guaranteed when using a single battery cell to power the
converter.
Now, plugging in worst case conditions, the inductor
value can be determined by simply transforming the
above equation in terms of “L”:
work especially well with the TK65025: 10RF, 12RF, 3DF,
D73, and D75. The 5CA series can be used for
isolated-output applications, although such design objectives are not considered here.
Other Converter Components
2
L MIN =
V I( MIN ) D( MIN )
[
2 f ( MAX )I O( MAX ) V O( MIN ) + V F( MAX ) − V I( MIN )
]
2
(3)
where “VF(MAX)” is best approximated by the diode forward
voltage at about two-thirds of the peak diode current
value. The peak diode current is the same as the peak
input current, the peak switch current, and the peak
inductor current. The formula is:
I PK =
VID
(4)
fL
Some reiteration is implied because “L” is a function
of “VF” which is a function of “IPK” which, in turn, is a function
of “L”. The best way into this loop is to first approximate
“VF”, determine “L”, determine “IPK”, and then determine a
new “VF”. Then, if necessary, reiterate.
When selecting the actual inductor, it is necessary to
make sure that the peak current rating of the inductor (i.e.,
the current which causes the core to saturate) is greater
than the maximum peak current that the inductor will
encounter. To determine the maximum peak current, use
Eq. (4) again, but this time plugging in maximum values for
“VI” and “D”, and minimum values for “f ” and “L”.
It may also be necessary when selecting the inductor to
check the rms current rating of the inductor. Whereas
peak current rating is determined by core saturation, rms
current rating is determined by wire size and power
dissipation in the wire resistance. The inductor rms
current is given by:
I L(RMS) = I PK D +
I PK f L
VO + VF − VI
(5)
3
where “IPK” is the same maximized value that was just
used to check against inductor peak current rating, and
the term in the numerator within the radical that is added
to the [on-time] duty ratio, “D”, is the off-time duty ratio.
Toko America, Inc. offers a wide range of inductor
values and sizes to accommodate varying power level
requirements. The following series of Toko inductors
Page 6
In choosing a diode, parameters worthy of consideration are: forward voltage, reverse leakage, and capacitance. The biggest efficiency loss in the converter is due
to the diode forward voltage. A schottky diode is typically
chosen to minimize this loss. Possible choices for Schottky
diodes are: LL103A from ITT MELF case; 1N5017 from
Motorola (through hole case); MBR0530 from Motorola
(surface mount) or 15QS02L from Nihon EC (surface
mount).
Reverse leakage current is generally higher in schottkys
than in pin-junction diodes. If the converter spends a good
deal of the battery lifetime operating at very light load (i.e.,
the system under power is frequently in a standby mode),
then the reverse leakage current could become a substantial fraction of the entire average load current, thus degrading battery life. So don’t dramatically oversize the schottky
diode if this is the case.
Diode capacitance isn’t likely to make much of an
undesirable contribution to switching loss at this relatively
low switching frequency. It can, however, increase the
snubber dissipation requirement.
The snubber (optional) is composed of a series RC
network from the switch pin to ground (or to the output or
input if preferred). Its function is to dampen the resonant
LC circuit which rings during the inductor current deadtime.
When the current flowing in the inductor through the output
diode decays to zero, the parasitic capacitance at the
switch pin from the switch, the diode, and the inductor
winding has energy which rings back into the inductor,
flowing back into the battery. If there is no snubbing, it is
feasible that the switch pin voltage could ring below
ground. Although the IC is well protected against latchup,
this ringing may be undesirable due to radiated noise. In
order to do an effective job, the snubber capacitor should
be large (e.g., 5~20 times) in comparison to the parasitic
capacitance. If it is unnecessarily large, then it dissipates
extra energy every time the converter switches. The
resistor of the snubber should be chosen such that it drops
a substantial voltage as the ringing parasitic capacitance
attempts to pull the snubber capacitor along for the ride. If
the resistor is too small (e.g., zero), then the snubber
capacitance just adds to the ringing energy. If the resistor
is too large (e.g., infinite) then it effectively disengages the
snubber capacitor from fighting the ringing.
The output capacitor, the capacitor connected from the
February, 1997 Toko, Inc.
TK65025
diode cathode to ground, has the function of averaging the
current pulses delivered from the inductor while holding a
relatively smooth voltage for the converter load. Typically,
the ripple voltage cannot be made smooth enough by this
capacitor alone, so an output filter is used. In any case,
to minimize the dissipation required by the output filter, the
output capacitor should still be chosen with consideration
to smoothing the voltage ripple. This implies that its ESR
(equivalent series resistance) should be low. This usually
means choosing a larger size than the smallest available
for a given capacitance. To determine the peak ripple
voltage on the output capacitor for a single switching
cycle, multiply the ESR by the peak current which was
calculated in Eq. (4). ESR can be a strong function of
temperature, being worst case when cold. The capacitance should be capable of integrating a current pulse with
little ripple. Typically, if a capacitor is chosen with reasonably low ESR and if the capacitor is the right type of
capacitor for the application (typically aluminum electrolytic or tantalum), then the capacitance will be sufficient.
ESR and printed circuit board layout have strong influence on RF interference levels. Special care must be
taken to optimize PCB layout and component placement.
The Benefits of Input Filtering
In practice, it may be that the peak current (calculated
in Eq. (4)) flowing out of the battery and into the converter
will cause a substantial input ripple voltage dropped
across the resistance inside the battery. This becomes a
more likely case for cold temperature (when battery series
resistance is higher), higher load rating converters (whose
inductor’s must draw higher peak currents), and when the
battery is undersized for the peak current application.
While the simple analysis used a parameter “VI ” to
represent the converter input voltage in the equations,
one may not know what “V I” value to use if it is delivered
by a battery that allows high ripple to occur. For example,
assume that the converter draws a peak current of 100mA
for a 1V input, and assume that the input is powered by a
partially discharged AAA battery which might have a
series resistance of 2 Ω at 0°C. (Environmentally clean, so
called “green” batteries tend to have higher source resistance than their “unclean” predecessors.) If such partially
discharged battery voltage is 1V without load, the converter battery voltage will sag to about 0.8V during the
on-time. This can cause two problems: (1) with the
effective input voltage to the converter reduced in this
way, the converter output current capability will decrease,
(2) if the same battery is powering the TK65025 at the V IN
pin (i.e., the normal case), then the IC may become
inoperable due to insufficient V IN. This is why the application test circuit features an RC filter into the VIN pin. The
February, 1997 Toko, Inc.
current draw is very small, so the voltage drop across this
filter resistor is negligible. The filter serves to average out
the input ripple caused by the battery resistance. Note
that this filter is optional and the net effect of its use is the
extension of battery life by allowing the battery to be
discharge more deeply.
A more power-efficient method comes at the price of a
large capacitor. This can be placed in parallel with the
battery to help channel the converter current pulses away
from the battery. The capacitor must have low ESR
compared to the battery resistance in order to accomplish
this effectively.
Still another solution is to filter the DC input with an LC
filter. However, it is more likely that the filter will either be
too large or too lossy. It is of questionable benefit to
smooth the input if the DC loss through the filter is large.
Assuming that input ripple voltage at the battery terminal and converter input is large, and that we filter the VIN
pin of the IC as in the test circuit, then the parameter “VI”
in the previous equations is not usable, and we will need
to use parameters to represent both the source voltage
and the source resistance.
Switch On-Resistance, Inductor Winding
Resistance, and Capacitor ESR
The on-resistance of the TK65025’s internal switch is
about 1Ω maximum. Using the previously stated example
of 100mA peak current, the voltage drop across the
switch would reach 100mV during the on-time. This
subtracts from the voltage which is impressed across the
inductor to store energy during the on-time, so less
energy is delivered to the output during the off-time.
It is quite possible for the inductor winding resistance to
meet or exceed 1Ω, also. Voltage drop across the
winding resistance of the inductor also subtracts from the
voltage used to store energy in the core. So it also
degrades efficiency.
As the inductor delivers energy into the output capacitor during the off-time, its current decays at a rate proportional to the voltage drop across it. The idealized equations assume that the voltage at the switching node is
clamped at a diode drop above the output voltage. However, the ESR of the output capacitor can increase the
voltage drop across the inductor by the additional voltage
dropped across the ESR when the peak current flows in
it. For example, the voltage across a capacitor with an
ESR of 2Ω (not unusual at cold temperature) would jump
by 200mV when 100mA peak current began to flow in it.
This extra voltage drop would cause the inductor current
to ramp down more quickly, thus, depleting the available
output current. Possible choices for low ESR capacitors
are: Panasonic TE series (surface mount); AVX TPS
Page 7
2
TK65025
series (surface mount); Matsuo 267 series (surface mount);
Sanyo OS-CON series (miniature through hold).
 D  D
(R + R L
 1 2 f L   2 f L S
V BB D
2
IO =
V O + R OF I O(TGT) +
D
2fL
(V
BB R U
)+V
F
+ R SW
)

current capability in accordance with the maximum peak
current that could be calculated using Eq. (4). For a two
2
D


− V BB  1 R S + R L )
(
 2fL

−
[
2
(
) + (V
2( V + V )
f C S V BB + V O + V F
O
2
O
+ V F − V BB
)]
2
(6)
F
Higher-Order Design Equation
The equation above was developed as a closed form
approximation for the design variable that required the
least approximation to allow a closed form. In this case,
that variable was “IO” (e.g., as opposed to “L”).
The approximations made in the equation development
have the primary consequence that error is introduced as
resistive losses become relatively large. As it is normally
a practical design goal to ensure that resistive losses will
be relatively small, this seems acceptable. The variables
used are:
IO
Output current capability
IO(TGT) Targeted output current capability
VO
Output voltage
VF
Diode forward voltage
VBB
Battery voltage, unloaded
D
Oscillating duty ratio of main switch
f
Oscillator frequency
L
Inductance value
RS
Source resistance (battery + filter)
RL
Inductor winding resistance
RSW Switch on-state resistance
ROF Output filter resistance
RU
ESR of upstream output capacitor
CS
Snubber capacitance
Deriving a design solution with this equation is necessarily an iterative process. Use worst case tolerances as
described for inductor selection, plugging in different values for “L” to approximately achieve an “IO” equal to the
targeted value. Then, fine tune the parasitic values as
needed and, if necessary, readjust “L” again and reiterate
the process.
DUAL-CELL APPLICATION
There are special considerations involved in designing
a converter with the TK65025 for use with two battery cells.
With two battery cells the TK65025 can provide substantially more output current than a single cell input for the
same efficiency.
The concern is the possibility of saturating the inductor.
For a single cell input it was only necessary to choose the
Page 8
cell input the peak current is not so readily determined
because the inductor can go into continuous mode. When
this happens, the increase of current during the on-time
remains more-or-less the same (i.e., approximately equal
to the peak current as calculated using Eq. (4)), but the
inductor current doesn’t start from zero. It starts from
where it had decayed to during the previous off-time.
There is no deadtime associated with a single switching
period when in continuous mode because the inductor
current never decays to zero within one cycle.
The cause for continuous mode operation is readily
seen by noting that the rate of current increase in the
inductor during the on-time is faster than the rate of decay
during the off-time. The reason for that is because there
is more voltage applied across the switch during the
on-time (two battery cells) than during the off-time (3 volts
plus a diode drop minus two battery cells). That situation,
in conjunction with a switch duty ratio of about 50%, implies
that the current can’t fall as much as it can rise during a
cycle. So when a switching cycle begins with zero current
in the inductor, it ends with current still flowing.
Continuous mode operation implies that the inductor
value no longer restricts the output current capability. With
discontinuous mode operation, it was necessary to choose
a lower inductor value to achieve a higher output current
rating. (Eq. (6) specifically shows “IO” as a function of “L”.)
This also implied higher ripple current from the battery. In
continuous mode operation, one can choose a larger
inductor value intentionally if it is desirable to minimize
ripple current. The catch is that high inductance and high
current rating together generally imply larger inductor size.
But generally this unrestricted inductor value allows more
freedom in the converter design.
The dual cell input and the continuous current rating
imply that the peak current in the inductor will be at least
twice as high as it would for a single cell input using the
same inductor value. The Toko D73 and D75 series
inductors are particularly suited for the higher output
current capability of the dual cell configuration.
For operation at a fixed maximum load, the inductor can
be kept free of saturation by choosing its peak current
February, 1997 Toko, Inc.
TK65025
rating equal to the converter output current rating plus the
single cycle ripple current peak given by Eq. (4). With that
guideline followed, the risk of saturation becomes only a
dynamic problem. Under the situation of placing a dynamic
load on the output of the converter, saturation may occur.
Fortunately, unlike off-line powered converters, battery
powered converters tend to be quite forgiving of dynamic
saturation, due to the limitation of available power.
Startup of the converter is an example of a practically
unavoidable dynamic load change (complicated by an output operating point change) that can cause saturation of the
inductor. However, this particular phenomenon applies to
single cell powered converters, too - so saturation is not
entirely avoidable, yet does not cause system problems. It
is beyond the scope of this application note to quantify the
practical limitations of allowed dynamic saturation and how
stressful it may be to the various components involved. It is
left to the user to examine empirically the dynamic saturation phenomenon and determine what performance is acceptable. In most cases no problem will be exhibited.
February, 1997 Toko, Inc.
2
Page 9
TK65025
Page 10
February, 1997 Toko, Inc.
TK65025
2
February, 1997 Toko, Inc.
Page 11
TK65025
PACKAGE OUTLINE
SOT-23L
6
5
4
3.2
1.0
0.6
e1
Marking Information
Orientation Mark
1
2
3
+0.1
0.4 -0.05
e
0.1
M
e
0.95
e
0.95
0.95
e
0.95
Recommended Mount Pad
2.2
± 0.2
0.2
3.3
± 0.3
30°
0.15
+0.1
-0.05
±0.15
0.4
Max
1.2 ±
0.05
± 0.05
1.25
+0.15
-0
0.3
3.4
± 0.2
MARKING INFORMATION
M25
The information furnished by TOKO, Inc. is believed to be accurate and reliable. However, TOKO reserves the right to make changes or improvements in the design, specification or manufacture
of its products without further notice. TOKO does not assume any liability arising from the application or use of any product or circuit described herein, nor for any infringements of patents or other
rights of third parties which may result from the use of its products. No license is granted by implication or otherwise under any patent or patent rights of TOKO, Inc.
TOKO AMERICA REGIONAL OFFICES
Midwest Regional Office
Toko America, Inc.
1250 Feehanville Drive
Mount Prospect, Il 60056
Tel: (847) 297-0070
Fax: (847) 699-7864
Western Regional Office
Toko America, Inc.
2480 North First Street, Suite 260
San Jose, CA 95131
Tel: (408) 432-8281
Fax: (408) 943-9790
http://www.tokoam.com
Page 12
© 1997 Toko, Inc.
All rights reserved
Printed in the USA
Eastern Regional Office
Toko America, Inc.
107 Mill Plain Road
Danbury, CT 06811
Tel: (203) 748-6871
Fax: (203) 797-1223
Semiconductor Technical Support
Toko Design Center
4755 Forge Road
Colorado Springs, CO 80907
Tel: (719) 528-2200
Fax: (719) 528-2375
IC-138-TK65025
February, 1997 Toko, Inc.