TOKO TK65130MTL/30M

TK651xx
STEP-UP VOLTAGE CONVERTER WITH VOLTAGE MONITOR
FEATURES
APPLICATIONS
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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
DESCRIPTION
The TK651xx 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
TK651xx provides the power switch and the control circuit
for a boost converter. The converter takes a DC input and
boosts it up to a regulated 2.7, 3.0 or 3.3 V output .
The output voltage is laser-trimmed. A Low Output Indicator
detector (LOI) 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 (UVLO) 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 of 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 SW pin of the IC. Special
care should be taken to achieve reliability through the use
of Oxide, double Nitride passivation. The TK651xx is
available in a miniature 6-pin SOT-23L-6 surface mount
package.
Customized levels of accuracy in oscillator frequency and
output voltage are available.
TK651xx
VIN
GND
20 P
GND
VOUT
SW
SW
ORDERING INFORMATION
BLOCK DIAGRAM
Vref
TK651xxM
CONTROL
CIRCUIT
Tape/Reel Code
LOI
VOUT
UVLO
LOI
VIN
Voltage Code
OSCILLATOR
VOLTAGE CODE
TAPE/REEL CODE
27 = 2.7 V
30 = 3.0 V
33 = 3.3 V
TL: Tape Left
January 1999 TOKO, Inc.
GND
Page 1
TK651xx
ABSOLUTE MAXIMUM RATINGS
All Pins Except SW and GND .................................... 6 V
SW Pin ....................................................................... 9 V
Power Dissipation (Note 1) ................................ 400 mW
Storage Temperature Range ................... -55 to +150 °C
Operating Temperature Range ...................-20 to +80 °C
Junction Temperature ........................................... 150 °C
TK651xx ELECTRICAL CHARACTERISTICS
Over operating temperature range and supply voltage range, unless otherwise specified.
SYMBOL
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNITS
70
83
102
kH z
-5%
VOUT
+3%
V
0
50
mV
fOSC
Internal Oscillator Frequency
VIN = 1.3 V, IOUT = 0 mA
VOUT(REG)
Regulation Threshold of VOUT
TA = 25 ° C
∆VOUT(LOAD)
Load Regulation of VOUT(REG)
VIN = 1.3 V, IOUT = 0 to 4 mA
∆VOUT(LINE)
Line Regulation of VOUT(REG)
∆VIN = 0.25 V
-20
0
20
mV
DOSC
On-time Duty Ratio of Oscillator
TA = 25 ° C
45
50
55
%
VLOI
VOUT During LOI Transition
TA = 25 ° C
-5%
+4%
V
0.87
VOUT
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.
GENERAL CIRCUIT
V IN
LOI
I(V IN )
GND
GND
SW
V OUT
300 k Ω
I(V OUT )
I OUT
IB
V IN
V OUT
L
D
C
Page 2
January 1999 TOKO, Inc.
TK651xx
FINAL TEST CIRCUIT
CN
10 µF
VIN
LOI
GND
GND
VOUT
SW
IB
VIN
300 kΩ
IOUT
ROF
VOUT
L = 95 µF
CS
220 pF
Note: Inductor L: Toko A682AE-014 or equivalent
Diode D: LL101
Capacitors CN:CU:CD: Panasonic TE series,
ECS-TOJY106R
D
RS
+
15
CU
10 µF
+
CD
10 µF
1K
Above is the Final Test Circuit through which each of the production parts must pass. In this test circuit, the part is tested
against the specification limits in the data sheet (the min. and max. values in the Electrical Characteristics) at room
temperature, and is rejected if the tested values are outside the minimum (min.) and maximum (max.) values.
The Bench Test Circuits shown on the following pages are the circuits used most of the time to measure the typical (typ.)
values in the Electrical Characteristics section, and make the Typical Performance graphs.
Note: In measuring the oscillator frequency and the Max IOUT on the bench, the converter was loaded until “no pulse
skipping” mode was achieved.
January 1999 TOKO, Inc.
Page 3
TK651xx
TK65127 ELECTRICAL CHARACTERISTICS
Over operating temperature range and supply voltage range, unless otherwise specified.
SYMBOL
PARAMETER
TEST CONDITIONS
MIN
TYP
UNITS
1.60
V
VIN
Supply Voltage
IB(Q)
No Load Battery Current (Note 3)
VIN = 1.3 V, IOUT = 0 mA,
T A = 25 ° C
56
84
µA
I(VIN)
Quiescent Current into VIN Pin
VIN = 1.3 V, IOUT = 0 mA,
T A = 25 ° C
12.5
20
µA
I(VOUT)
Quiescent Current into VOUT Pin
VIN = 1.3 V, IOUT = 0 mA,
14.5
23
µA
∆fOSC /∆T
Temperature Stability of Oscillator
VIN = 1.3 V, No Pulse Skipping
VOUT(REG)
Regulation Threshold of VOUT
T A = 25 ° C
∆VOUT /∆T
Temperature Stability of VOUT(REG)
VIN = 1.3 V, IOUT = 0 mA,
VOUT(LOI)
VOUT During LOI Transition
VIN = 1.3 V, TA = 25 ° C
∆VOUT(LOI)
VOUT(LOI) Threshold Hysteresis
TA = 25 ° C
38
mV
RSW(ON)
On-resistance of SW Pin
VOUT ≥ 2.4 V
1.0
Ω
EFF
Converter Efficiency (Notes 2,3)
VIN = 1.3 V, IOUT = 6 mA,
L = 95 µH, 3DF Coil
76
%
VULV
Undervoltage Lockout Voltage
TA = 25 ° C, (Note 4)
IOUT(MAX)
0.90
MAX
Maximum IOUT for Converter
(Notes 1,3)
2.56
2.24
1K
CN
10 µF
2.79
V
ppm/° C
2.45
0.79
V
V
VIN = 1.1 V, TA = 25 ° C,
L = 95 µH, 3DF Coil
6
7.6
mA
VIN = 1.3 V, TA = 25 ° C,
L = 95 µH, 3DFCoil
8
12.8
mA
VIN = 1.1 V, TA = 25 ° C,
L = 39 µH, D73 Coil
15.5
mA
VIN = 1.3 V, TA = 25 ° C,
L = 39 µH, D73 Coil
33.6
mA
VIN
LOI
GND
GND
Note 1:
300 kΩ
Note 3:
VOUT
IND
Note 4:
IOUT
I(VOUT)
IB
VIN
Maximum load current depends on
inductor value and input voltages.
Output ripple depends on filter
capacitor values, ESRs and the
inductor value.
When using specified Toko inductor
and Schottky diode with VF = 0.45 V
@ 100 mA.
Regulation not guaranteed.
VOUT
L = 95 µH
CB
10 µF
2.36
0.45
Note 2:
I(VIN)
2.70
%/° C
100
BENCH TEST CIRCUIT
Inductor L: Toko A682AE-014 or equivalent
Diode D: LL103A or equivalent
Capacitors CN:CO:CB: Panasonic TE series,
RN
ECS-TOJY106R
0.1
CS
220 pF
D
RS
CO
10 µF
1K
Page 4
January 1999 TOKO, Inc.
TK651xx
TYPICAL PERFORMANCE CHARACTERISTICS
TK65127
OSCILLATOR FREQUENCY VS.
TEMPERATURE
OUTPUT REGULATION VOLTAGE VS.
TEMPERATURE
2.80
95
BATTERY CURRENT VS.
INPUT VOLTAGE
120
TA = 25 °C
NO LOAD
100
85
2.75
80
IB (µA)
VOUT(REG) (V)
f OSC (kHz)
90
2.70
60
40
2.65
80
20
75
-50
2.8
0
50
2.60
-50
100
0
100
1.5
2
2.5
OUTPUT VOLTAGE VS.
LOAD CURRENT
OUTPUT VOLTAGE VS.
LOAD CURRENT
2.8
TA = 25 °C
L = 100 µH
TOKO P/N: A636CY-101M
(D73 SERIES)
2.8
TA = 25 °C
1.3 V
1.1 V
VIN = 0.9 V
2.6
1.3 V
1.1 V
1.6 V
2.5
10
100
TA = 25 °C
1.3 V
1.1 V
1.6 V
2.5
2.4
1
VIN = 0.9 V
2.6
1.6 V
2.5
2.4
L = 39 µH
TOKO P/N: A636CY-390M
(D73 SERIES)
3
2.7
VOUT (V)
VIN = 0.9 V
2.4
1
10
100
1
10
100
IOUT (mA)
IOUT (mA)
IOUT (mA)
EFFICIENCY VS. LOAD CURRENT
EFFICIENCY VS. LOAD CURRENT
MAXIMUM OUTPUT CURRENT VS.
INDUCTOR VALUE (µH)
85
1.3 V
75
1.6 V
70
75
65
60
60
1
10
IOUT (mA)
January 1999 TOKO, Inc.
100
NO PULSE
SKIPPING
MODE
TA = 25 °C
40
1.3 V
80
65
0.1
1.1 V
1.6 V
70
VIN = 0.9 V
50
TA = 25 °C
VIN = 0.9 V
1.1 V
80
L = 100 µF
Toko P/N: 636CY-101M
(D73 SERIES) LARGER COIL
IOUT(MAX) (mA)
90
TA = 25 °C
L = 95 µF
Toko P/N: A682AE-014
(3DF SERIES) SMALL COIL
EFF (%)
85
1
OUTPUT VOLTAGE VS.
LOAD CURRENT
2.7
90
.5
VIN (V)
L = 95 µH
TOKO P/N: A682AE-014
(3DF SERIES)
2.6
0
TEMPERATURE (°C)
VOUT (V)
VOUT (V)
50
TEMPERATURE (°C)
2.7
EFF (%)
0
30
20
1.1 V
1.3 V
10
VIN = 0.9 V
0.1
1
10
IOUT (mA)
100
0
0
40
80
120
160
INDUCTOR VALUE (µH)
Page 5
TK651xx
TK65130 ELECTRICAL CHARACTERISTICS
Over operating temperature range and supply voltage range, unless otherwise specified.
SYMBOL
PARAMETER
TEST CONDITIONS
MIN
TYP
UNITS
2.50
V
VIN
Supply Voltage
IB(Q)
No Load Battery Current (Note 3)
VIN = 1.3 V, IOUT = 0 mA,
TA = 25 ° C
79
111
µA
I(VIN)
Quiescent Current into VIN Pin
VIN = 1.3 V, IOUT = 0 mA,
TA = 25 ° C
20
35
µA
I(VOUT)
Quiescent Current into VOUT Pin
VIN = 1.3 V, IOUT = 0 mA,
22
40
µA
∆fOSC /∆T
Temperature Stability of Oscillator
VIN = 1.3 V, No Pulse Skipping
0.1
VOUT(REG)
Regulation Threshold of VOUT
TA = 25 ° C
∆VOUT /∆T
Temperature Stability of VOUT(REG)
VIN = 1.3 V, IOUT = 0 mA,
VOUT(LOI)
VOUT During LOI Transition
VIN = 1.3 V, TA = 25 ° C
∆VOUT(LOI)
VOUT(LOI) Threshold Hysteresis
TA = 25 ° C
60
mV
RSW(ON)
On-resistance of SW Pin
VOUT
1.0
Ω
EFF
Converter Efficiency (Notes 2,3)
VIN = 1.3 V, IOUT = 6 mA,
L = 95 µH, 3DF Coil
77
%
VULV
Undervoltage Lockout Voltage
TA = 25 ° C, (Note 4)
IOUT(MAX)
0.90
MAX
Maximum IOUT for Converter
(Notes 1,3)
2.85
2.4 V
1K
CN
10 µF
V
ppm/° C
2.70
0.79
V
V
VIN = 1.1 V, TA = 25 ° C,
L = 95 µH, 3DF Coil
4
6.7
mA
VIN = 1.3 V, TA = 25 ° C,
L = 95 µH, 3DFCoil
6
10.8
mA
VIN = 1.1 V, TA = 25 ° C,
L = 39 µH, D73 Coil
14.0
mA
VIN = 1.3 V, TA = 25 ° C,
L = 39 µH, D73 Coil
28.6
mA
VIN
LOI
GND
GND
Note 1:
300 kΩ
Note 3:
VOUT
IND
IOUT
I(VOUT)
IB
VIN
Note 4:
Maximum load current depends on
inductor value and input voltages.
Output ripple depends on filter
capacitor values, ESRs and the
inductor value.
When using specified Toko inductor
and Schottky diode with VF = 0.45 V
@ 100 mA.
Regulation not guaranteed.
VOUT
L = 95 µH
CB
10 µF
2.82
0.45
Note 2:
I(VIN)
3.10
100
2.48
BENCH TEST CIRCUIT
Inductor L: Toko A682AE-014 or equivalent
Diode D: LL103A or equivalent
Capacitors CN:CO:CB: Panasonic TE series,
RN
ECS-TOJY106R
3.00
%/° C
CS
220 pF
D
RS
CO
10 µF
1K
Page 6
January 1999 TOKO, Inc.
TK651xx
TYPICAL PERFORMANCE CHARACTERISTICS
TK65130
OUTPUT REGULATION VOLTAGE VS.
TEMPERATURE
3.10
OSCILLATOR FREQUENCY VS.
TEMPERATURE
95
BATTERY CURRENT VS.
INPUT VOLTAGE
300
TA = 25 °C
NO LOAD
250
85
3.05
200
IB (µA)
VOUT(REG) (V)
fOSC (kHz)
90
3.00
150
100
2.95
80
50
75
-50
3.1
0
50
2.90
-50
100
1
1.5
2
2.5
OUTPUT VOLTAGE VS.
LOAD CURRENT
OUTPUT VOLTAGE VS.
LOAD CURRENT
L = 95 µH
TOKO P/N: A682AE-014
(3DF SERIES)
3.1
TA = 25 °C
L = 100 µH
TOKO P/N: A636CY-101M
(D73 SERIES)
3.1
TA = 25 °C
2.0 V
VIN = 0.9 V
1.6 V
1.1 V
1.3 V
VIN = 0.9 V
2.9
2.0 V
1.1 V
2.5 V
2.8
2.7
10
100
TA = 25 °C
1.3 V
1.6 V
VIN = 0.9 V
2.9
2.5 V
2.5 V
1.1 V
2.8
1.6 V
2.7
1
L = 39 µH
TOKO P/N: A636CY-390M
(D73 SERIES)
3
3.0
VOUT (V)
VOUT (V)
2.0 V
2.7
1
10
100
1
10
100
IOUT (mA)
IOUT (mA)
IOUT (mA)
EFFICIENCY VS. LOAD CURRENT
EFFICIENCY VS. LOAD CURRENT
MAXIMUM OUTPUT CURRENT VS.
INDUCTOR VALUE (µH)
85
1.3 V
2.0 V
70
1.1 V
2.0 V
75
2.5 V
70
2.5 V
65
0.1
1
NO PULSE
SKIPPING
MODE
TA = 25 °C
40
30
20
1.1 V
1.3 V
10
VIN = 0.9 V
65
VIN = 0.9 V
50
= 25 °C
1.6 V
80
1.1 V
75
L = 100 µF
TA
Toko P/N: 636CY-101M
(D73 SERIES) LARGER COIL
1.3 V
1.6 V
EFF (%)
80
90
TA = 25 °C
L = 95 µF
Toko P/N: A682AE-014
(3DF SERIES) SMALL COIL
IOUT(MAX) (mA)
VOUT (V)
.5
OUTPUT VOLTAGE VS.
LOAD CURRENT
2.8
EFF (%)
0
VIN (V)
3.0
2.9
60
0
100
TEMPERATURE (°C)
1.3 V
85
50
TEMPERATURE (°C)
3.0
90
0
VIN = 0.9 V
10
IOUT (mA)
January 1999 TOKO, Inc.
100
60
0.1
1
10
IOUT (mA)
100
0
0
40
80
120
160
INDUCTOR VALUE (µH)
Page 7
TK651xx
TK65133 ELECTRICAL CHARACTERISTICS
Over operating temperature range and supply voltage range, unless otherwise specified.
SYMBOL
PARAMETER
TEST CONDITIONS
MIN
TY P
UNITS
2.50
V
VIN
Supply Voltage
IB(Q)
No Load Battery Current (Note 3)
VIN = 1.3 V, IOUT = 0 mA,
T A = 25 ° C
88
134
µA
I(VIN)
Quiescent Current into VIN Pin
VIN = 1.3 V, IOUT = 0 mA,
T A = 25 ° C
20
35
µA
I(VOUT)
Quiescent Current into VOUT Pin
VIN = 1.3 V, IOUT = 0 mA,
24
40
µA
∆fOSC /∆T
Temperature Stability of Oscillator
VIN = 1.3 V, No Pulse Skipping
0.1
VOUT(REG)
Regulation Threshold of VOUT
TA = 25 ° C
∆VOUT /∆T
Temperature Stability of VOUT(REG)
VIN = 1.3 V, IOUT = 0 mA,
VOUT(LOI)
VOUT During LOI Transition
VIN = 1.3 V, TA = 25 ° C
∆VOUT(LOI)
VOUT(LOI) Threshold Hysteresis
TA = 25 ° C
60
mV
RSW(ON)
On-resistance of SW Pin
VOUT ≥ 2.4 V
1. 0
Ω
EFF
Converter Efficiency (Notes 2,3)
VIN = 1.3 V, IOUT = 6 mA,
L = 95 µH, 3DF Coil
80
%
VULV
Undervoltage Lockout Voltage
TA = 25 ° C, (Note 4)
IOUT(MAX)
0.90
MAX
Maximum IOUT for Converter
(Notes 1,3)
3.13
1K
CN
10 µF
V
ppm/° C
2.93
0.79
V
V
VIN = 1.1 V, TA = 25 ° C,
L = 95 µH, 3DF Coil
4
6.5
mA
VIN = 1.3 V, TA = 25 ° C,
L = 95 µH, 3DFCoil
6
8.0
mA
VIN = 1.1 V, TA = 25 ° C,
L = 39 µH, D73 Coil
12.5
mA
VIN = 1.3 V, TA = 25 ° C,
L = 39 µH, D73 Coil
20.0
mA
VIN
LOI
GND
GND
Note 1:
300 kΩ
Note 3:
VOUT
IND
IOUT
I(VOUT)
IB
VIN
Note 4:
Maximum load current depends on
inductor value and input voltages.
Output ripple depends on filter
capacitor values, ESRs and the
inductor value.
When using specified Toko inductor
and Schottky diode with VF = 0.45 V
@ 100 mA.
Regulation not guaranteed.
VOUT
L = 95 µH
CB
10 µF
2.82
0.45
Note 2:
I(VIN)
3.40
100
2.68
BENCH TEST CIRCUIT
Inductor L: Toko A682AE-014 or equivalent
Diode D: LL103A or equivalent
Capacitors CN:CO:CB: Panasonic TE series,
RN
ECS-TOJY106R
3.30
%/° C
CS
220 pF
D
RS
CO
10 µF
1K
Page 8
January 1999 TOKO, Inc.
TK651xx
TYPICAL PERFORMANCE CHARACTERISTICS
TK65133
OSCILLATOR FREQUENCY VS.
TEMPERATURE
OUTPUT REGULATION VOLTAGE
VS. TEMPERATURE
95
BATTERY CURRENT VS.
INPUT VOLTAGE
3.40
300
TA = 25 °C
NO LOAD
250
85
3.35
200
IB (µA)
VOUT(REG) (V)
fOSC (kHz)
90
3.30
150
100
3.25
80
50
75
-50
3.4
0
50
3.20
-50
100
50
100
.5
1
1.5
2
2.5
TEMPERATURE (°C)
VIN (V)
OUTPUT VOLTAGE VS.
LOAD CURRENT
OUTPUT VOLTAGE VS.
LOAD CURRENT
OUTPUT VOLTAGE VS.
LOAD CURRENT
L = 95 µH
TOKO P/N: A682AE-014
(3DF SERIES)
3.4
TA = 25 °C
L = 100 µH
TOKO P/N: A636CY-101M
(D73 SERIES)
3.4
TA = 25 °C
3.3
2.0 V
1.6 V
1.1 V
3.1
1.3 V
2.0 V
VIN = 0.9 V
3.2
1.6 V
1.1 V
2.5 V
L = 39 µH
TOKO P/N: A636CY-390M
(D73 SERIES)
3
TA = 25 °C
3.3
VOUT (V)
VOUT (V)
1.3 V
VIN = 0.9 V
3.2
0
TEMPERATURE (°C)
3.3
VOUT (V)
0
0
2.5 V
3.1
1.3 V
VIN = 0.9 V
3.2
2.0 V
1.1 V
2.5 V
3.1
1.6 V
3.0
3.0
1
85
100
3.0
1
10
100
10
100
IOUT (mA)
IOUT (mA)
EFFICIENCY VS. LOAD CURRENT
EFFICIENCY VS. LOAD CURRENT
MAXIMUM OUTPUT CURRENT VS.
INDUCTOR VALUE (µH)
90
TA = 25 °C
L = 95 µF
Toko P/N: A682AE-014
(3DF SERIES) SMALL COIL
85
2.0 V
1.3 V
1.1 V
75
2.5 V
70
2.5 V
1.6 V
2.0 V
75
70
1.1 V
1.6 V
VIN = 0.9 V
65
NO PULSE
SKIPPING
MODE
TA = 25 °C
16
80
EFF (%)
80
20
TA = 25 °C
L = 100 µF
Toko P/N: 636CY-101M
(D73 SERIES) LARGER COIL
1.3 V
EFF (%)
1
IOUT (mA)
IOUT(MAX) (mA)
90
10
12
8
1.1 V
4
65
1.3 V
VIN = 0.9 V
VIN = 0.9 V
60
0.1
1
10
IOUT (mA)
January 1999 TOKO, Inc.
100
60
0.1
1
10
IOUT (mA)
100
0
0
40
80
120
160
INDUCTOR VALUE (µH)
Page 9
TK651xx
SINGLE-CELL APPLICATION
The TK651xx is a boost converter control IC with the power
MOSFET switch built into the device. It operates from a
single battery cell and steps up the output voltage to a
regulated 2.7, 3.0 and 3.3 V. The device operates at a
fixed nominal clock frequency of 83 kHz.
In its simplest form, a boost power converter using the
TK651xx requires only three external components: an
inductor, a diode, and a capacitor.
filtering component values (consult the “Ripple and Noise
Considerations” section) can be determined if needed or
desired.
The TK651xx 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).
ANALYSIS OF SWITCHING CYCLE
The analysis is easier to follow when referencing the
simple boost circuit below.
VIN
LOI
GND
GND
SW
IPEAK
di/dt = - (VOUT + Vf - VIN)/ L
di/dt = VIN / L
VOUT
VOUT
+
FIGURE 1: SIMPLE BOOST CONVERTER
t (on)
t (off)
t (deadtime)
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 TK651xx monitors the voltage of the output capacitor
and has a 2.7, 3.0 and 3.3 V threshold at which the
converter switching becomes deactivated. So the output
capacitor charges up to 2.7, 3.0 and 3.3 V and regulates
there, provided that no more current is drawn from the
output than the inductor can provide. The primary task,
then, in designing a boost converter with the TK651xx
is to determine the inductor value (and its peak current
rating to prevent inductor core saturation problems)
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 necessary tasks also include choosing
the diode and the output capacitor. Then the snubber and
Page 10
Above is the input or inductor current waveform over a
switching cycle.
From an oscillator standpoint, the switching cycle consists
of only an on-time and an off-time. But from an 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, 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 on-time, delivered to the
output during off-time, and remains at zero during deadtime.
January 1999 TOKO, Inc.
TK651xx
SINGLE-CELL APPLICATION (CONT.)
The output current of the boost converter comes from the
second half of the input current triangle waveform (averaged
over the period or multiplied by the frequency) given by the
equation:
where “VIN” 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, “VOUT” is the output voltage, and “VF”
is the diode forward voltage. It is important to note that
Equation 1 makes the assumption stated in Equation 2:
IOUT = [IPK x t(off)] x f / 2
VIN ≤ (VOUT + VF)(1 - D)
and:
(2)
IPK = (VIN / L) x t(on) = VIN D / f L
The implication from Equation 2 is that the inductor will
operate in discontinuous mode.
and:
t(off) = IPK / [(VOUT + VF - VIN) / L]
=(VIN D / f L) / [(VOUT + VF - VIN) / L
= VIN D / f (VOUT + VF - VIN)
Using worst-case conditions, the inductor value can be
determined by simply transforming the above equation in
terms of “L”:
therefore:
L(MIN) =
IOUT = (VIN)2 (D)2 / 2 f L (VOUT + VF - VIN)
VIN(MIN)2 D(MIN)2
2 f(MAX) IOUT(MAX) [VOUT(MIN) + VF(MAX) - VIN(MIN)]
(3)
which derives Equation 1 of the next section.
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:
IOUT =
(1)
(VIN)2 (D)2
2 f L (VOUT + VF - VIN)
January 1999 TOKO, Inc.
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:
IPK =
VIN D
fL
(4)
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 peak current rating of the inductor (i.e., the
current which causes the core to saturate) is greater than
the maximum peak current the inductor will encounter. To
determine the maximum peak current, use Equation 4
again, but use maximum values for “VIN” 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
Page 11
TK651xx
SINGLE-CELL APPLICATION (CONT.)
rating is determined by wire size and power dissipation in
the wire resistance. The inductor rms current is given by:
IL(RMS) = IPK
(5)
IPK f L
D+ V
OUT + VF - VIN
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. can offer a miniature matched
magnetic solution in a wide range of inductor values and
sizes to accommodate varying power level requirements.
The following series of Toko inductors work especially well
with the TK651xx : 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
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 (look in the “Ripple and Noise Considerations”
section) dissipation requirement.
The output capacitor, the capacitor connected from the
diode cathode to ground, has the function of averaging the
Page 12
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
Equivalent Series Resistance (ESR) 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 Equation 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
Equation 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
inductors must draw higher peak currents), and when the
battery is undersized for the peak current application.
While the simple analysis used a parameter “VIN” to
represent the converter input voltage in the equations, one
may not know what “VIN” 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 100 mA
for a 1 V input, and assume that the input is powered by a
partially discharged AAA battery which might have a series
resistance of 2 Ohms 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 1 V without load, the
converter battery voltage will sag to about 0.8 V 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,
January 1999 TOKO, Inc.
TK651xx
SINGLE-CELL APPLICATION (CONT.)
2) if the same battery is powering the TK651xx at the VIN
pin (i.e., the normal case), then the IC may become
inoperable due to insufficient VIN. This is why the application
test circuit features an RC filter into the VIN pin. The 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 discharged 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 be either
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 “VIN” in the
previous equations is not usable, and we will need to use
parameters to represent both the source voltage and the
source resistance.
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 2
Ohms (not unusual at cold temperature) would jump by
200 mV when 100 mA 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
series (surface mount); Matsuo 267 series (surface mount);
Sanyo OS-CON series.
LOI FEATURES
The Low Output Indicator (LOI) output can provide a reset
signal to a microprocessor or other external system
controller. When the output voltage falls below the LOI
threshold (during start-up of the converter or under a
current overload fault condition), the LOI signal is asserted
low, indicating that the system controller (i.e.,
microprocessor) should be in a reset mode. This method
of reset control can be used to prevent improper system
operation which might occur at low supply voltage levels.
The LOI threshold voltage is between 87% and 93% of the
regulated output voltage value. The LOI threshold also has
about 45 mV hysteresis between its on-off trigger levels.
RIPPLE AND NOISE CONSIDERATIONS
SWITCH ON-RESISTANCE, INDUCTOR WINDING
RESISTANCE, AND CAPACITANCE ESR
The filtered test circuit of the TK651xx is shown below in
Figure 2.
The on-resistance of the TK651xx’s internal switch is
about 1 Ohm maximum. Using the previously stated
example of 100 mA peak current, the voltage drop across
the switch would reach 100 mV during the on-time. This
subtracts from the voltage which is impressed across the
inductor to store energy during the on-time. As a result,
less energy is delivered to the output during the off-time.
RN
1K
CN
10 µF
VIN
LOI
GND
GND
VOUT
SW
IB
If the winding resistance of the inductor increases to 1 Ohm
or greater, the voltage drop across the winding resistance
also subtracts from the voltage used to store energy in the
core. Thus, efficiency degradation occurs.
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
January 1999 TOKO, Inc.
VIN
300 kΩ
IOUT
ROF
VOUT
L = 95 µF
CS
220 pF
D
RS
+
15
CU
10 µF
+
CD
10 µF
1K
FIGURE 2: FILTERED TEST CIRCUIT
Page 13
TK651xx
SINGLE-CELL APPLICATION (CONT.)
Compared to the simple boost circuit, this Filtered Test
Circuit adds the following circuitry: the RC filter into the VIN
pin, the RC snubber, the RC filter at the converter output,
and the pull-up resistor to the LOI pin.
The RC filter at the VIN pin is used only to prevent the ripple
voltage at the battery terminals from prematurely causing
undervoltage 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 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 latch-up, this ringing may be
undesirable due to radiated noise. To be effective, the
snubber capacitor should be large (e.g., 5 ~ 20 times) in
comparison to the parasitic capacitance. If it is unnecessarily
large, 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), the
snubber capacitance just adds to the ringing energy. If the
resistor is too large (e.g., infinite), it effectively disengages
the snubber capacitor from fighting the ringing.
The RC filter at the converter output attenuates the
conducted noise; the converter may not require this.
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 TK651xx
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 TK651xx operates by Pulse Burst Modulation
(PBM), the switching pattern can be a subharmonic of the
oscillator frequency. The simplest example, and the one to
be avoided the most, is that of the converter causing every
other oscillator pulse to be skipped. This means that the
switching pattern would have a fundamental frequency of
one-half the oscillator frequency, or 41.5 kHz. This is the
eleventh harmonic, which lands at 456.5 kHz, right in the
IF band. Fortunately, the energy is rather weak at the
eleventh harmonic. Even more fortunate is the ease with
which that regulation mode is avoided.
The internal regulator comparator has a finite hysteresis.
When an additional output filter is used (e.g., the RC filter
of the test circuit, or an LC filter), the ripple at the regulation
node is minimized. This 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 the same
number of 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.
Finally, the pull-up resistors at the LOI pin are needed only
if this 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 TK651xx has been trimmed and
stabilized to 83 +/- 4 kHz with the intention of greatly
Page 14
January 1999 TOKO, Inc.
TK651xx
SINGLE-CELL APPLICATION (CONT.)
HIGHER-ORDER DESIGN EQUATION
VBB2 D
IOUT =
( 2ƒD L )[1- 2ƒD L (R
S + RL + RSW)
]
2
(
D
D
VOUT + ROFIOUT(TGT) +
(VBBRU) + VF - VBB 1 (R + RL)
2ƒ L S
2ƒ L
ƒCS [VBB2+ (VOUT+ VF)2 + (VOUT + VF - VBB)2 ]
)
-
2(VOUT + VF)
The equation above was developed as a closed form approximation. In order to allow for a closed form, the design variable
that requires the least approximation was “IOUT,” 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:
IOUT
VOUT
VBB
f
RS
RSW
RU
Output current capability
Output voltage
Battery voltage, unloaded
Oscillator frequency
Source resistance (battery + filter)
Switch on-state resistance
ESR of upstream output capacitor
IOUT(TGT)
VF
D
L
RL
ROF
CS
Targeted output current capability
Diode forward voltage
Oscillating duty ratio of main switch
Inductance value
Inductor winding resistance
Output filter resistance
Snubber capacitance
Deriving a design solution with this equation is necessarily an iterative process. Use worst-case tolerances as described
for inductor selection, using different values for “L” to approximately achieve an “IOUT” equal to the targeted value. Then,
fine tune the parasitic values as needed and, if necessary, readjust “L” again and reiterate the process.
January 1999 TOKO, Inc.
Page 15
TK651xx
DUAL-CELL APPLICATION
There are special considerations involved in designing a
converter with the TK651xx for use with two battery cells.
With two battery cells, the TK651xx 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
current capability in accordance with the maximum peak
current that could be calculated using Equation 4. For a
two-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 Equation 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 increases in the inductor
during the on-time is faster than the rate of decay than
during the off-time. This is because there is more voltage
applied across the switching during the on-time (two
battery cells) than during the off-time (3 volts plus a diode
minus two 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.
inductor value. The Toko D73 and D75 series inductors
are partially 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 rating
equal to the converter output current rating plus the single
cycle ripple current peak given Equation 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.
Start-up 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. Hence,
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.
Continuous mode operation implies that the inductor value
no longer restricts the output current capability. With
discontinuous mode operation, it is necessary to choose a
lower inductor value to achieve a higher output current
rating (Equation 6 specifically shows “IOUT” as a function of
“L”). This also implies 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 higher inductance
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 be for a single-cell input using the same
Page 16
January 1999 TOKO, Inc.
TK651xx
STEP-DOWN CONVERTER APPLICATION
HOW TO MAKE A STEP-DOWN CONVERTER USING THE TK651xx AND AN IRF7524D1 “FETKY” PART
The TK651xx can be used as a controller in a step-down converter with the following two additional changes. See Fig 3.
U2
IRF7524D1
VBATT
L1
5,6,
7,8
3
VOUT
10 µH
R3
1k
4
1,2
R7
1k
R1
10 k
R4
150
U1
TK65130
3
+
SW
2
VIN
1
VOUT 4
R2
3.9 k
GND
LOI 6
5
GND
R5
300 k
C1
220 pF
C2
47 µF
+
C3
47 µF
Note: L = 10 µH
Toko P/N: 636CY-100M
D73C Coil
R6
300 k
FIGURE 3: STEP-DOWN CONVERTER USING THE TK651xx SCHEMATIC
1) Change the main switch orientation for use in a step-down converter. An external P-channel power MOSFET is
used as the main switch in a step-down converter configuration. The gate of FET is turned on through a resistor divider
being pulled down to GND by the internal output transistor of the TK651xx. This application requires both a logic level
P-channel MOSFET and a Schottky diode. An IRF7524D1 “FETKY” part contains both in a small micro 8 package.
2) Change the voltage seen at the VIN pin of the TK651xx to below the regulation voltage at the VOUT pin. A resistor
divider between the converter VIN and the chip VIN pin drops the voltage seen at the VIN pin. If the VIN pin is a higher voltage
than the VOUT pin, the TK651xx will not regulate the output, but will continue to pulse its output transistor.
WHERE TO USE THIS STEP-DOWN CONVERTER
The TK65130 is a Pulse Burst Modulation (PBM) controller with a fixed duty cycle of approximately 50%. Therefore, only
if VBATT is more than twice the voltage of VOUT can the converter run in CCM (continuous current mode). The converter
can and does regulate in DCM (discontinuous current mode) for lighter output current loads with VIN less than twice the
voltage of VOUT. But DCM produces more peak current and more ripple current than CCM. Below is a table giving some
examples of where this type of step-down converter might be used.
Type Battery
Li-ion
NiMH
NiMH
# of Cells
2 (Note 1)
4 (Note 2)
6 (Note 2)
VBATT Range
5.4 to 8.4 V
4.4 to 5.2 V
6.6 to 7.8 V
VOUT
3.0 V
3.0 V
3.0 V
Typ. Max. IOUT
500 mA
500 mA
500 mA
Oper. Mode
DCM
DCM
CCM
Inductor
10 µH
10 µH
120 µH
Note 1: Li-ion cell voltage range 2.7 V to 4.2 V
Note 2: NiMH cell voltage range 1.1 V to 1.3 V
January 1999 TOKO, Inc.
Page 17
TK651xx
STEP-DOWN CONVERTER APPLICATION (CONT.)
THE AMOUNT OF BOARD SPACE NEEDED TO IMPLEMENT THIS STEP-DOWN CONVERTER
An evaluation board for this converter has been made using a TOKO 3DF, D73 or D75 series inductor, using only 0.96
sq. inches of board space. The artwork for the surface-mount circuit board is shown below in Figure 4.
VOUT
G
LOI
.8 "
Actual Size
G
LBI
VIN
1.2 "
Note: Short pin 2 to 5 for use with TK651xx
FIGURE 4: TK651xx STEP-DOWN CONVERTER EVALUATION BOARD ARTWORK
Page 18
January 1999 TOKO, Inc.
TK651xx
PULSED LOAD APPLICATION
Often in the world of power conversion, the current draw of the load circuit is not constant, but rather pulsed. It is common
in power supply design to size the power path large enough, and make the feedback loop fast enough to support these
pulsed maximum currents. For applications where the pulse width is long or unpredictable, this approach may be
warranted. However, in applications where the pulse width and maximum frequency of occurrence is predictable, such
as digital cell phones or two-way pagers, it may be easier and wiser to increase the energy storage in the output filter
of the power supply and keep the power path small. This leads to the need for a very large value output capacitor.
Panasonic makes a series AL gold cap “super cap” which is a low voltage, large value capacitor in the one farad range.
Before designing a low power DC-DC converter with a “super cap” in its output filter, it is necessary to know the loading
profile (the waveform of the current going into the load from the output of the converter) of the application in which it is
to be used. The converter can then be designed so that the “super cap” can be recharged in the time before the next big
discharge current pulse comes along.
Figure 5 is an example “super cap” charge/discharge diagram showing that the charge into the cap needs to equal the
charge leaving the cap during discharge. This diagram comes from the loading and unloading profile information. In
reality, some extra charge needs to go into the cap to make up for the losses caused by ESR of the cap.
1A
Note: Equal charge into and out of “supercap”
2 s (30 mA) = 60 ms (1A)
60 ms
Drawing not to scale
IOUT
30 mA
2s
time
FIGURE 5: “SUPER CAP” CHARGE/DISCHARGE DIAGRAM
Figure 6 is a schematic for this “super cap” example application.
RN
1k
CN
10 µF
VIN
LOI
GND
GND
-
CD
+ 10 µF
VOUT
IND
IOUT
IB
VIN
VOUT
L = 39 µF
D
CS
220 pF
+
"SUPERCAP"
1F
GOLD CAP
RS
1k
FIGURE 6: PULSED LOAD “SUPER CAP” APPLICATION SCHEMATIC
January 1999 TOKO, Inc.
Page 19
TK651xx
PACKAGE OUTLINE
Marking Information
SOT-23L-6
TK65127
TK65130
TK65133
Marking
27M
30M
33M
0.6
6
5
4
e1 3.0
1.0
Marking
1
2
3
0.32
e
+0.15
- 0.05
0.1
e 0.95
M
e 0.95
e
0.95
3.5
0.95
Recommended Mount Pad
+0.3
- 0.1
2.2
max
15
1.2
0.4
0.15
0.1
+0.15
- 0.05
0 - 0.1
1.4 max
0.3
(3.4)
+ 0.3
3.3
Dimensions are shown in millimeters
Tolerance: x.x = ± 0.2 mm (unless otherwise specified)
Toko America, Inc. Headquarters
1250 Feehanville Drive, Mount Prospect, Illinois 60056
Tel: (847) 297-0070
Fax: (847) 699-7864
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
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
Visit our Internet site at http://www.tokoam.com
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.
Page 20
© 1999 Toko, Inc.
All Rights Reserved
January 1999 TOKO, Inc.
IC-xxx-TK651xx
0798O0.0K
Printed in the USA