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Application Note
Surface Mount Chopper Type Switching Regulator IC
SI-8000JD Series
1st Edition January 2010
SANKEN ELECTRIC CO., LTD.
SI-8000JD
－－－
Contents
－－－
1. General Description
1-1 Features
－－－－－－－－－－
3
1-2 Applications
－－－－－－－－－－
3
1-3 Type
－－－－－－－－－－
3
2-1 Package Information
－－－－－－－－－－
4
2-2 Ratings
－－－－－－－－－－
5
2-3 Circuit Diagram
－－－－－－－－－－
7
－－－－－－－－－－
8
－－－－－－－
9
2. Specification
3. Operational Description
3-1 PWM Output Voltage Control
3-2 Input /Output Current and Choke Coil Current
3-3 Overcurrent Protection / Thermal Shutdown
4
－－－－－－－－
10
4-1 Phase Margin
－－－－－－－－－－
11
4-2 Phase Characteristics of LC Filter
－－－－－－－－－－
12
Power Supply Stability
4-3 Relation of Phase Characteristics of Regulator IC and LC Filter
－－－－－－－－－－
13
5-1 External Components
－－－－－－－－－－
15
5-2 Pattern Design Notes
－－－－－－－－－－
20
5-3 Operation Waveform Check
－－－－－－－－－－
21
5-4 Thermal Design
－－－－－－－－－－
23
6-1 Output ON / OFF Control
－－－－－－－－－－
24
6-2 Controllable Output Voltage
－－－－－－－－－－
24
6-3 Spike Noise Reduction
－－－－－－－－－－
26
6-4 Reverse Bias Protection
－－－－－－－－－－
27
－－－－－－－－－－
28
5. Cautions
6. Applications
7. Terminology
２
SI-8000JD
1. General Description
The SI-8000JD is a chopper type switching regulator IC which is provided with various functions required for
the buck switching regulator and protection functions. By using four external components, a highly efficient
switching regulator can be composed.
●1-1 Features
-
Compact size and large output current of 1.5A
The maximum output current of 1.5A for the outline of TO263-5
-
High efficiency of 82%
(SI-8050JD Vin=20V/Io=0.5A)
Heat dissipation is small due to high efficiency to allow for the downsizing of a heat sink.
-
Four external components
The regulator can be composed of input / output capacitor, diode and coil.
-
Internal adjustment of output voltage and phase compensation having been done in production
Troublesome adjustment of output voltage and phase compensation by means of external components
is no longer required.
-
Reference oscillation by a built-in timing capacitor
No external capacitor for setting the oscillation frequency is required.
-
Built-in functions for overcurrent and thermal shutdown
The foldback type overcurrent protection and thermal shutdown circuit are built in.
(automatic recovery type)
-
Output ON / OFF function (rise time delay setting can be made.)
The ON / OFF control function of output is also possible. Current consumption is decreased at OFF time. It
is possible to delay the rising speed of output voltage at start-up by adding external capacitors.
●1-2 Applications
For on-board local power supplies, power supplies for OA equipment, stabilization of secondary output voltage
of regulator and power supply for communication equipment
●1-3 Type
-
Type: Semiconductor integrated circuits (monolithic IC)
-
Structure: Resin molding type (transfer molding)
３
1
2
5-0.80±0.10
φ 1.50 Dp : ±0.20
3
4
5
4-[1.70±0.25]
9.20±0.20
4.90±0.20
(15°)
(3°)
(3°)
2.00±0.10
(0.75)
15.30±0.30
9.90±0.20
(0.50)
(R0.30)
3-(R0.30)
4.50±0.20
15.30±0.30
0～6°
2.54
±0.30
(R0.30)
2.40±0.20
(3°)
+0.15
-0.10
+0.10
-0.05
0.10
1.30
(1.75)
(4.60)
(0.40)
4-[1.70±0.25]
4.90±0.20
9.20±0.20
(6.80)
5) Unit: mm
Notes:
1) Dimensions do not include molding burr.
) are shown
2) Figures in parentheses (
only for reference.
3) Figures in parentheses [
] are
dimensions after lead forming.
4) Backside bumps: 0.8 mm at maximum
5-0.80±0.10
2x(R0.45)
(4.40)
(8.00)
10.00±0.20
SI-8000JD
2. Specification
●2-1 Package Information (surface mount: TO263-5)
Pin assignment
1. Vin
2. SWOut
3. GND
4. Vos
5. ON/OFF
Products Weight：Approx.1.48g
４
SI-8000JD
●2-2 Ratings
Lineup
Product Name
Vout(V)
SI-8033JD
3.3
SI-8050JD
5
SI-8090JD
9
SI-8120JD
12
Absolute Maximum Ratings
Parameter
Symbol
Rating
Unit
Input Voltage
Vin
43
V
Allowable Power Dissipation
Pd1
16.6
W
Pd2
1.5
W
Junction Temperature
Tj
125
°C
Storage Temperature
Tstg
-40 - +125
°C
in Infinite Radiation
Allowable Power Dissipation
without Heat sink
Recommended Conditions
Parameter
DC Input Voltage
Symbol
SI-8033JD
SI-8050JD SI-8090JD SI-8120JD Unit
Vin1
5.3 - 6.3
7-8
11 - 12
14 - 15
V
Io=0 - 1A
Vin2
6.3 - 40
8 - 40
12 - 40
15 - 40
V
Io=0 - 1.5A
Vin≧Vo+3V
Output Current
Io
0 - 1.5
A
Junction
Tjop
-30 - +125
°C
Conditions
Temperature in
Operation
５
SI-8000JD
Electrical Characteristics
(Ta=25 ﾟ C)
SI-8033JD
Parameter
Symbol
Vin
Set Output Voltage
Conditions
SI-8050JD
SI-8090JD
SI-8120JD
min typ max min typ max min typ max min
typ
max
3.17 3.30 3.43 4.90 5.00 5.10 8.82 9.00 9.18 11.76 12.0 12.24
V
Vin=15V/Io=0.5A Vin=20V/Io=0.5A
η
77
Vin=21V/Io=0.5A
Vin=24V/Io=0.5A
86
88
Vin=21V/Io=0.5A
Vin=24V/Io=0.5A
125
125
Vin=21V/Io=0.5A
Vin=24V/Io=0.5A
50
60
82
Efficiency
%
Conditions
Vin=15V/Io=0.5A Vin=20V/Io=0.5A
f
Operation Frequency
Input Voltage – Output
Unit
Conditions
125
125
kHz
Vin=15V/Io=0.5A Vin=20V/Io=0.5A
25
⊿VLi
80
40
100
120
130
Voltage
mV
(Iout=0.5A)
Conditions
Vin=8～30V
Vin=10～30V
Vin=15～30V
Vin=18～30V
Output Current -
⊿VLo
10
10
10
10
30
40
40
Output Voltage
40
mV
(Iout=0.2 - 0.8A)
Conditions
Overcurrent Protection
Is
Start Current
Conditions
Vin=15V
Vin=20V
Vin=21V
Vin=24V
Output Voltage
Kt
±0.5
±0.5
±1.0
±1.0
Vin=15V
1.6
Vin=20V
1.6
Vin=21V
1.6
Vin=24V
1.6
A
mV/ﾟ C
Temperature Variation
６
SI-8000JD
●2-3 Circuit Diagram
2-3-1 Internal Equivalent Circuit
-
SI-8033JD,SI-8050JD,SI-8090JD,SI-8120JD
Vin
1
SW
OUT
Vin
L
2
Vout
Di
C1
Overcurrent
Protection
PReg
5
過電流保護
ON/
OFF
Latch
ﾗｯﾁ &and
Reset
ﾘｾｯﾄ
ON/OFF
DelayStart
C3
C2
ﾄﾞﾗｲﾊﾞ
Driver
Oscillator
発振器
Vos
Thermal
過熱保護
Protection
Comparator
ｺﾝﾊﾟﾚｰﾀ
4
Error
Amplifier
ｴﾗｰｱﾝﾌﾟ
Reference
基準電圧
Voltage
GND
3
2-3-2 Typical Connection Diagram
-
SI-8033JD,SI-8050JD,SI-8090JD,SI-8120JD
1
VIN
VIN
SWOUT
SI-8000JD
220uF
GND
ON/OFF GND
5
3
Vos
2
100uH
VOU
T
4
Di
470uF
GND
７
SI-8000JD
3. Operational Description
●3-1 PWM Output Voltage Control
In the SI-8000JD series, the output voltage is controlled by the PWM system and the IC incorporates the PWM
comparator, oscillator, error amplifier, reference voltage, output transistor drive circuit etc. The triangular wave
output (≒125KHz) from the oscillator and the output of the error amplifier are given to the input of the PWM
comparator. The PWM comparator compares the oscillator output with the error amplifier output to turn on the
switching transistor for a time period when the output of the error amplifier exceeds the oscillator output.
PWM Control Chopper Type Regulator Basic Configuration
Switching
Transistor
PWM
Comparator
Drive
Circuit
Oscillator
Error Amplifier
The error amplifier output and
the oscillator output are
compared by the PWM
comparator to generate the drive
signal of rectangular wave and
to drive the switching transistor.
Reference
Voltage
PWM Comparator Operation Diagram
Oscillator Output
Error Amplifier Output
Switching Transistor Output
On the assumption that the output voltage attempts to rise, the output of the error amplifier is lowered, because
the error amplifier is of inverting type. As the output of the error amplifier is lowered, the time period where it
falls below the triangular wave level of the oscillator is increased to shorten the ON time of the switching
transistor and as a result, the output voltage is maintained constant. As described above, the output voltage is
controlled by varying the ON time of the switching transistor with the switching frequency fixed (the higher is
VIN, the shorter is the ON time of the switching transistor.)
The rectangular wave output of the switching transistor is smoothed by the LC low pass filter composed of a
choke coil and a capacitor to supply stabilized DC voltage to the load.
８
SI-8000JD
●3-2 Input / Output Current and Choke Coil Current
The rectangular output which is produced by the switching transistor of the SI-8000JD is converted into DC
output voltage by being smoothed by the LC filter composed of a choke coil and an output capacitor. The
operation of this LC filter significantly affects the stable operation of the chopper type regulator. The relation
between the choke coil and the current and the relation between the current and the ripple voltage are shown
below.
Emitter Voltage
(Switching Output)
The current IL flowing across the choke coil is of triangular wave shape. This triangular wave is composed of
two kinds of current components, Itr and Idi. The current Itr is supplied from the input side through the transistor
when the transistor is ON and its average value is input current Iin. The current Idi is the current that the energy
stored in the choke coil is commutated via the flywheel diode Di when the transistor is OFF. The total of Itr and
Idi is the current IL of choke coil. In addition, the average value of IL is the DC output current Io since the
triangular wave component superimposed on the IL is smoothed by charging and discharging of the capacitor C.
９
SI-8000JD
●3-3 Overcurrent Protection / Thermal Shutdown
出力電圧
Output
Voltage 過電流時出力電圧特性
The SI-8000JD includes the foldback type overcurrent
The oscillating
こ
こ で 周 波is数lowered
が低下
frequency
protection circuit. The overcurrent protection circuit detects
the peak current of a switching transistor and when the peak
current exceeds the set value, the ON time of the transistor is
compulsorily shortened to limit the current by lowering the
Output
Current
出力電流
output voltage. In addition, when the output voltage is
lowered up to the 50% of the rated value, the increase of
current at low output voltage is prevented by dropping linearly the switching frequency to about 40kHz. When
the overcurrent condition is released, the output voltage will be automatically restored.
Output Voltage Characteristics in Thermal Shutdown
The
thermal
shutdown
circuit
detects
the
semiconductor junction temperature of the IC and
Output Voltage
when the junction temperature exceeds the set
Restoration Setting
Temperature
Protection
Setting
Temperature
value, the output transistor is stopped and the
output is turned OFF. When the junction
temperature drops from the set value for overheat
protection by around 15°C, the output transistor is
Junction Temperature
automatically restored.
* Note for thermal shutdown characteristic
This circuit protects the IC against overheat resulting from the instantaneous short circuit, but it should
be noted that this function does not assure the operation including reliability in the state that overheat
continues due to long time short circuit.
１０
SI-8000JD
4. Power Supply Stability
●4-1 Phase Margin
This block diagram shows that the chopper type regulator is a negative feedback amplifier which controls the
output voltage by constantly comparing with the output voltage and the reference voltage which is set in advance.
Therefore, it has a negative feedback loop to control the output by detecting the variation of output voltage with
the error amplifier.
Reference
Voltage
Error
Amplifier
Output Voltage
Control
Block
Load
Detection
Block
Negative Feedback Loop
The phase within the negative feedback loop is displaced by 180° to negate the variation of the output voltage,
but in the event that the phase is further delayed by 180° in the state that the amplification degree (gain) is 1 or
more, the total phase delay amounts to 360° to deviate from the stable operation zone to cause abnormal
oscillation. This is called Barkhausen oscillation conditions. Therefore, the oscillation conditions should not be
accrued in the actual stabilized power supply.
It is possible to judge whether the Barkhausen oscillation conditions are accrued or not by means of frequency
and gain/phase characteristics of the negative feedback loop. The frequency-gain/phase characteristics are called
Bode diagram.
1-step Differential Amplifier
1-step differential Amplifier
Bode Diagram Example
Gain
Frequency
Phase
１１
SI-8000JD
In the Bode diagram, the frequency at which the gain is 1 (0 dB) is called gain intersection and the frequency at
which the phase of feedback loop is -180° is called phase intersection.
Unless the phase reaches -180° at the frequency of gain intersection, the oscillation conditions are not met.
In this respect, the phase at gain intersection - (-180°) is equal to the phase at gain intersection +180° and this
value is used as a margin to -180° which is called phase margin. The more the phase margin is, the less likely the
abnormal oscillation is to occur against the variation of environmental conditions such as input / output
conditions and temperature. Therefore, sufficient phase margin should be taken into consideration in order to
maintain the stable operation.
Stability Judgment at Bode Diagram
Gain Characteristics
Gain Characteristics
Frequency
Gain
Intersection
Phase Characteristics
Frequency
Gain
Intersection
Phase Characteristics
Phase Margin
Phase
Intersection
Phase Intersection
Phase Margin
Stable
Unstable
●4-2 Phase Characteristics of LC Filter
The phase margin of the chopper type regulator depends largely on the phase characteristics of the LC filter for
output smoothing. The phase characteristic of the LC filter theoretically shows the characteristics of a secondary
delay factor. Resonance is caused at a specific frequency due to the combination of inductance L of coil and of
capacitance C of the capacitor and at frequency higher than the resonance point, the phase is delayed by 180°at a
maximum.
The resonance frequency fLC is expressed as shown in the equation:
ｆLC 
1
2 LC
The phase characteristics are 0° if they are lower than the resonance frequency fLC.
The phase characteristics are 180° if they are higher than the resonance frequency fLC.
Accordingly, when the LC filter for output smoothing shows the theoretical phase characteristics, the phase
delay reaches -180° in this filter portion and the phase margin will be zero for this regulator.
However, in the actual LC filter, the phase delay of the LC filter is less than 180°because of influence of the
equivalent series resistance (ESR) of capacitor. Consequently, the phase margin can be secured for the regulator
１２
SI-8000JD
because of this phase compensation effect of the equivalent series resistance (ESR).
If the ESR is large, the phase delay of the LC filter becomes shorter.
However, the phase margin may be lowered due to the rising gain resulting from the lowered attenuation rate of
the LC filter, and abnormal oscillation may occur due to increased output ripple voltage, therefore care should be
taken of these two events.
LC Filter Phase Characteristics
Phase Delay
ESR: High
ESR: Low
ESR: 0
Frequency
Generally speaking, when such capacitors as tantalum capacitors or laminated capacitors are used for the output
LC filter, the phase delay of filters will be large.
Therefore, from the view point of securing the phase margin, use of the electrolytic capacitor is preferable.
●4-3 Relation of phase characteristics of regulator IC and IC filter
The phase characteristic of the chopper type regulator IC is determined by the phase of the regulator IC and the
phase characteristic of the LC filter. In this respect, the relationship between these two characteristics is
important. The cause of phase delay of the regulator is generally regarded as the delay of the output stage or the
error amplifier, and the higher is the frequency, the longer is the delay time.
In the meantime, in the case of the LC filter, above the resonant frequency fLC of the LC filter, the higher is the
frequency, the shorter is the phase delay.
Therefore, when the gain lowering start frequency fp and the resonant frequency fLC of the LC filter are close
each other, the phase margin of the regulator is decreased, because both phase delays are concentrated.
Generally, as the fLC is lower, the phase margin tends to be increased.
In order to lower the fLC, it is required to increase the capacitance of a coil or capacitor as shown in the
following equation:
Resonant frequency fLC
fLC 
1
2π LC
１３
SI-8000JD
Phase
Phase Characteristics:
when fp and fLC are close
Phase
Phase Characteristics:
when fp and fLC are distant
Regulator IC
ﾚｷﾞｭﾚｰﾀ IC
Amplification
Section
Regulator IC
Amplification
Section
LC Filter
LC Filter
Synthesized
Characteristics
Long Phase Delay
Synthesized
Characteristics Short Phase Delay
Frequency
Frequency
With respect to the constants of LC filters described in the applications of each regulator IC, if the inductance of
coil or capacitance of the capacitor is set to be less than the recommended values, the resonant frequency fLC of the
LC filter may rises to decrease the phase margin. Care should be taken for this phenomenon.
１４
SI-8000JD
5. Cautions
●5-1 External Components
5-1-1 Choke coil L
The choke coil L supplies current to the load side when the switching transistor is OFF, and plays a main role in
the chopper type switching regulator. In order to maintain the stable operation of the regulator, such dangerous
state of operation as saturation state and operation at high temperature due to heat generation must be avoided.
The following points should be taken into consideration for the selection of the choke coil.
a) The choke coil should be fit for the switching regulator.
The coil for a noise filter should not be used because of large loss and generated heat.
b) The inductance value should be appropriate.
The larger is the inductance of the choke coil, the less is the ripple current flowing across the choke coil, and the
output ripple voltage drops and as a result, the overall size of the coil becomes larger.
On the other hand, if the inductance is small, the peak current flowing across the switching transistor and diode is
increased to make the ripple voltage higher and this operation state is not favorable for maintaining the stable
operation.
Large Inductance
Small Inductance Large Ripple Voltage/ Current
Small Ripple Voltage/ Current
The larger is the inductance, the smaller will be the
The smaller is the inductance, the larger will be the
ripple current/voltage. But the outer size of the coil
ripple curtent/voltage. Although the outer size of the
becomes larger.
coil is smaller, the operation is likely to be unstable.
The inductance value shown in the specifications should be considered as a reference value for the stable
operation and the appropriate inductance value can be obtained by the following equation.
ΔIL shows the ripple current value of the choke coil, and the lower limit of inductance is set as described in the
following.
-
In the case that the output current to be used is nearly equal to the maximum rating (1.5A) of the
SI-8050JD: output current × 0.2- 0.3
-
In the case that the output current to be used is approximately 0.5A or less: output current × 0.5 - 0.6
L
(Vin  Vout )  Vout
IL  Vin  f
－－－(1)
１５
SI-8000JD
For example, where VIN = 25V, VOut = 5V, ΔIL = 0.3A, frequency = 125KHz,
L
(25  5)  5
≒106uH
0.3  25  125  10 3
As shown above, the coil of about 100μH may be selected.
c) The rated current shall be met.
The rated current of the choke coil must be higher than the maximum load current to be used. When the load
current exceeds the rated current of the coil, the inductance is sharply decreased to the extent that it causes
saturation state at last. Please note that overcurrent may flow since the high frequency impedance becomes low.
d) Excellent DC superimposition characteristic
Inductance
DC Superimposed
Current
The current waveform that flows across the choke coil is a waveform that the triangular wave is
superimposed to the DC current equivalent to the load current. The inductance of a coil tends to be
decreased in accordance with the increase of superimposed current. The coil may be used until the
inductance of the coil is decreased up to 50% of the rated value. This information is useful for the
selection of coils.
e) Noise shall be low.
In the open magnetic circuit core which is of drum shape, since magnetic flux passes outside the coil, the
peripheral circuit may be damaged by noise. It is recommended to use the toroidal type, EI type or EE type coil
which has a closed magnetic circuit type core as much as possible.
5-1-2 Input Capacitor C1
The input capacitor is operated as a bypass capacitor of the input circuit to supply steep current to the regulator
during switching and to compensate the voltage drop of the input side. Therefore, the input capacitor should be
placed as close as to the regulator IC.
In addition, in the case that the smoothing capacitor of the AC rectifier circuit is located in the input circuit, the
input capacitor may be also used as a smoothing capacitor, but similar attention should be paid.
The selection of C1 shall be made in consideration of the following points:
a) The requirement of withstand voltage shall be met.
b) The requirement of the allowable ripple voltage shall be met.
１６
SI-8000JD
Current Flow of C1
Current Waveform of C1
Ripple
Current
The ripple current of the input
capacitor is increased in accordance
with the increase of the load
current.
If the withstanding voltages or allowable ripple voltages are exceeded or used without derating, it is in danger of
causing not only the decreasing the capacitor lifetime (burst, capacitance decrease, equivalent impedance
increase, etc) but also the abnormal oscillations of regulator. Therefore, the selection with sufficient margin is
needed. The effective value of ripple current flowing across the input capacitor can be obtained by the following
equation:
Irms  1.2 
Vo
 I o u t－－(2)
V i n
For instance, where Io=1.5A, VIN=20V, Vo=5V,
I r m s1.2 
5
 1.5  0.45 A
20
Therefore, it is necessary to select the capacitor with the allowable ripple current of 0.45A or higher.
5-1-3 Output Capacitor C2
The output capacitor C2 composes a LC low pass filter together with a choke coil L and functions as a rectifying
capacitor of switching output. The current equivalent to the pulse current ΔIL of the choke coil current is charged
and discharged in the output capacitor. Therefore, it is necessary to meet the requirements of withstand voltage
and allowable ripple current with sufficient margin like the input capacitor. Additional points to be checked are
DC equivalent series resistance (ESR) and capacitance.
The following points should be taken into consideration.
１７
SI-8000JD
Current Flow of C2
Current Waveform of C2
Ripple
Current
The ripple current of the output
capacitor is equal to the ripple
current of the choke coil and does not
vary even if the load current
increases or decreases.
-
Allowable Ripple Current
The ripple current effective value of the output capacitor is obtained by the equation.
Irms 
IL
2 3
－－－(3)
When ΔIL = 0.5A,
Irms 
0.5
≒ 014
. A
2 3
Therefore a capacitor having the allowable ripple current of 0.14A or higher is required.
-
DC equivalent series resistance (ESR)
It is necessary for the stable operation to select the ESR properly. When the ESR is too large or too small,
abnormal oscillation due to increase of ripple voltage or insufficient phase margin occurs respectively.
The output ripple voltage is determined by a product of the pulse current ΔIL (=C2 discharge and charge
current) of the choke coil current and the ESR, and the output ripple voltage which is 0.5 % - 1% of the output
voltage (for example, where 0.5% at Vout = 5V, 25mV) is good for the stable operation. Please refer to the
equations (4) and (5) to obtain the output ripple voltage. It should be noted that the ESR is changeable subject
to temperature and it is especially lowered at high temperature.
Vrip 
Vin  Vout Vout ESR　- - - (4)
L Vin  f
Vrip  IL  ESR　- - - (5)
When the ESR is too low (approx. 10 - 20Ω or lower), the phase delay becomes larger, resulting in abnormal
oscillation.
Therefore, it is not appropriate that a tantalum capacitor or a laminated ceramic capacitor is used for the output
capacitor as an independent component. However, connecting a tantalum capacitor or a laminated ceramic
capacitor in parallel with an electrolytic capacitor is effective in reducing the output ripple voltage only when it
is used at low temperature (< 0°C).
１８
SI-8000JD
In addition, in order to further decrease the ripple voltage, as shown below, it is also effective to add one stage of
the LC filter to form the π type filter.
SI-8000JD
L2: 20uH
Co2: 200uF
It should be noted that the operating stability is more influenced by the ESR than the capacitance as described
above if the requirements of withstand voltage and allowable ripple current are met.
With respect to the layout of the output capacitor, if it is located far from the IC, it will give same effect as the
increase of ESR due to wiring resistance etc., therefore it is recommended to place it near the IC.
１９
SI-8000JD
5-1-4 LC Filter Constants Selection Example
Based on the above description, the calculation methods of the inductance of choke coil, the capacitance of
output capacitor and the ESR are shown below. The following values are deemed as a target and in many cases,
the larger are the inductance and capacitance of output capacitor, the more stable operation will be achieved.
Samples: SI-8050JD, conditions: input voltage VIN: 20V, output voltage Vo: 5V, output current Io: 0.5A
-
Inductance L of choke coil L
Choke coil ripple current ΔIL = Io × 0.5 – 0.6 = 0.3A
L
-
Vin  Vo Vo 
IL  Vin  f
24  55
0.3  25  125000
 101H　L : 100H
Output capacitor ESR
The output ripple voltage Vrip shall be: 5V × 0.5% = 25 mV.
Vrip  IL  ESR　ESR 
Vrip
 83.3m　IL
5-1-5 Flywheel Diode Di
The flywheel diode Di is to discharge the energy which is stored in the choke coil at switching OFF.
For the flywheel diode, the Schottky barrier diode must be used. If a general rectifying diode or fast recovery
diode is used, the IC may be destroyed by applying reverse voltage due to the recovery and ON voltage.
●5-2 Pattern Design Notes
5-2-1 High Current Line
Since high current flows in the bold lines in the connection diagram, the pattern should be as wide and short as
possible.
SI-8000JD
5-2-2 Input/ Output Capacitor
The input capacitor C1 and the output capacitor C2 should be placed to the IC as close as possible. If the
rectifying capacitor for AC rectifier circuit is on the input side, it can be used as an input capacitor. However, if
it is not close to the IC, the input capacitor should be connected in addition to the rectifying capacitor.
Since high current is discharged and charged through the leads of input / output capacitor at high speed, the leads
should be as short as possible.
A similar care should be taken for the patterning of the capacitor.
２０
SI-8000JD
Improper Pattern Example
Proper Pattern Example
5-2-3 Sensing Terminal
The output voltage sensing terminal Vos shall be connected near the output capacitor C2 as much as possible.
(Vos terminal flow-in current is approx. 0.5mA.) If it is connected far from C2, it should be noted that abnormal
oscillation may happen due to the low regulation and increased switching ripple.
Recommended land pattern
Recommended board pattern
11±0.2
9±0.2
6.8±0.1
9±0.1
3.7±0.05
4±0.1
1±0.05
1.7±0.1
Top View
●5-3 Operation Waveform Check
It can be checked by the waveform between the pin 2 and 3 (SWOut waveform) of the SI-8000JD whether the
switching operation is normal or not.
The examples of waveforms at normal and abnormal operations are shown below:
２１
SI-8000JD
1. Normal Operation (continuous area)
2. Normal Operation (discontinuous area)
3. When C1 is distant from IC
4. When C2 is distant from IC
The continuous area is an area where the DC component of the triangular wave is superimposed on the current
flowing across the choke coil and the discontinuous area is an area where the current flowing across the choke
coil is intermittent (a period of zero current may happen.) because the current flowing across the choke coil is
low.
Therefore, when the load current is high, the area is a continuous area and when the same current is low, the area
is a discontinuous area.
In the continuous area, the switching waveform is formed in the normal rectangular waveform (waveform 1) and
in the discontinuous area, damped oscillation is caused in the switching waveform (waveform 2), but this is a
normal operation without any problem.
In the meantime, when the IC is far from C1 and C2, jitter which disturbs the ON – OFF time of switching will
happen as shown in the waveforms (3, 4). As described above, C1 and C2 should be connected close to the IC.
２２
SI-8000JD
●5-4 Thermal Design
In the case of the surface mounting type SI-8000JD, the heat is dissipated toward the copper foil on the mounting
board, therefore the thermal design should be made in consideration of copper foil area, board material and
number of copper foil layers.
The stem part of the backside of the SI-8000JD is connected with pin 3 (GND) by the inner frame and heat
dissipation performance is improved by taking the larger GND pattern which is directly connected with the stem
part.
In order to confirm the junction temperature, the temperature of the stem spot shown below should be measured
to calculate the temperature by the following equation.
Tj = Tc + Pd × 3°C/W
* Tc = Actually measured stem temperature
Temperature measurement point
Junction thermal resistance: 3°C /W
Reference data (Copper foil are vs Thermal resistance on single side copper foil board)
２３
SI-8000JD
6. Application
●6-1 Output ON / OFF Control
The output ON-Off control is possible using the SS (No.5) terminal. The output is turned OFF when the terminal
5 voltage falls to a low level by such as open collector. It is possible to use the rising delay time setting together.
Since the ON / OFF terminal has been already pulled up, no voltage shall be applied from the external side.
SI-8000JD
SI-8000JD
ON/OFF
ON/OFF
●6-2 SI-8033JD, SI-8050JD, SI-8090JD, SI-8120JD Controllable Output Voltage
The output voltage can be increased by adding a resistor to the Vos terminal (pin 4) (not applicable for voltage
fall).
●6-2-1 Variable Output Voltage by One External Resistor
Ivos
SI-8000JD
The output voltage adjustment resistance Rex is obtained by the following equation.
Re x 
Vout 'Vos
IVos
－－－(1)
Vos: Set output voltage for product
Vout: Variable output voltage
Ivos: Vos terminal in-flow current ≒ 527uA
* Since no temperature compensation is made for Rex, the temperature characteristic of output voltage is
lowered. Ivos is variable at maximum ±20% depending on each IC product. Therefore, as the variation range of
the output voltage becomes wider, the semi-fixed type resistor is required for the adjustment of accurate output
voltage.
The variation range of the output voltage including the variation of Rex, Ivos and Vos is shown as follows:
-
Maximum output voltage (Vout MAX)
Vout' MAX＝VosMAX＋RexMAX  IvosMAX
２４
SI-8000JD
VosMAX: The maximum value of set output voltage. The MAX value of the set output voltage should be put,
shown in the electrical characteristics of the specifications.
RexMAX: The maximum value of Rex. It is obtained from the allowable tolerance.
IvosMAX: The maximum in-flow current of Vos terminal. 658uA
-
The minimum output voltage (Vout’MIN)
Vout' MIN＝VosMIN＋RexMIN  IvosMIN
VosMIN: The minimum value of set output voltage. The MIN value of the set output voltage should be put,
shown in the electrical characteristics of the specifications.
RexMAX: The minimum value of Rex. It is obtained from the allowable tolerance of resistance.
IvosMIN: The minimum in-flow current of Vos terminal. 439uA
●6-2-2 Variable Output Voltage by Two External Resistors
SI-8000JD
Ivos
The output voltage adjustment resistors Rex1 and 2 are obtained by the following equation.
Vout 'Vos
S  IVos
Vos
Re x2 
( S  1)  IVos
Re x1 
－－－(3)
－－－(4)
S: Stability coefficient
The tolerance of temperature characteristics and output voltage is improved more by bypassing the current to
Rex2 than the method 6-2-1.
Stability coefficient S means the ratio of Rex 2 to the Vos terminal in-flow current Ivos. The larger is S, the
more is the variation of temperature characteristic and output voltage improved. (Normally, about 5 - 10)
The tolerance of the output voltage including variation of Rex 1, Rex 2, Ivos, Vos is shown below.
-
Maximum output voltage (Vout MAX)
Vout' MAX＝VosMAX＋Rex1MAX(
VosMAX
＋IvosMAX）
Rex2MIN
VosMAX: The maximum value of set output voltage. The MAX value of set output voltage should be put, shown
in the electrical characteristics of the specifications.
Rex1MAX: The maximum value of Rex1. It is obtained from the tolerance of the resistor.
Rex2 MIN: The minimum value of Rex2. It is obtained from the tolerance of the resistor.
IvosMAX: The maximum in-flow current of Vos terminal. 658uA
２５
SI-8000JD
-
The minimum output voltage (VoutMIN)
Vout' MIN＝VosMIN＋Rex1MIN(
VosMIN
＋IvosMIN）
Rex2MAX
VosMIN: The minimum value of the set output voltage. Please fill in the MIN value of the set output voltage
which is shown in the electrical characteristics of the specifications.
Rex1 MIN: The minimum value of Rex1. It is obtained from the tolerance of the resistor.
Rex2MAX: The maximum value of Rex2. It is obtained from the tolerance of the resistor.
IvosMIN: The minimum in-flow current of Vos terminal. 439uA
●6-2-3 Cautions for variation of output voltages
The degradation of regulation and the increase in the output voltage temperature coefficient are assumed when
the output voltage is varied.
If it is varied drastically, the increase of coil capacitance value may be required since the overcurrent
protection current is assumed to be lowered due to the increase in coil current.
Therefore, the use within the set output voltage +5V is recommended as for the upper limit of output voltage
variation.
In addition, the MAX value of the set output voltage is recommended as for the lower limit of output voltage
variation.
●6-3 Spike Noise Reduction
In order to reduce the spike noise, it is possible to compensate the output waveform of the SI-8000JD and the
recovery time of the diode by a capacitor, but it should be noted that the efficiency is also slightly reduced.
0～ 20Ω
1.VIN
100～ 3000pF
2.SWOUT
SI-8000JD
0～ 20Ω
3.GND
100～ 4000pF
Without noise reduction circuit
With noise reduction circuit
A resistor of 10Ω and a capacitor of 2200pF
are connected to external resistor
２６
SI-8000JD
*When the spike noise is observed with an oscilloscope, the lead wire may function as an antenna and the spike
noise may be observed extremely higher than usual if the probe GND lead wire is too long. In the observation of
spike noise, the probe lead wire should be made as short as possible and be connected with the root of the output
capacitor.
●6-4 Reverse Bias Protection
A diode for reverse bias protection is required between input and output when the output voltage is higher than
the input terminal voltage, such as in battery chargers.
SI-8000JD
２７
SI-8000JD
7. Terminology
-
Jitter
It is a kind of abnormal switching operations and is a phenomenon that the switching pulse width varies in
spite of the constant condition of input and output. The output ripple voltage peak width is increased when a
jitter occurs.
-
Recommended Conditions
It shows the operation conditions required for maintaining normal circuit functions. It is required to meet the
conditions in actual operations.
-
Absolute Maximum Ratings
It shows the destruction limits. It is required to take care so that even one item does not exceed the pacified
value for a moment during instantaneous or normal operation.
-
Electrical Characteristics
It is the specified characteristic value in the operation under the conditions shown in each item. If the
operating conditions are different, it may be out of the specifications.
-
PWM (Pulse Width Modulation)
It is a kind of pulse modulation systems. The modulation is achieved by changing the pulse width in
accordance with the variation of modulation signal waveform (the output voltage for chopper type switching
regulator).
-
ESR (Equivalent Series Resistance)
It is the equivalent series resistance of a capacitor. It acts in a similar manner to the resistor
series-connected to the capacitor.
２８
SI-8000JD
Notice
・The contents of this description are subject to change without prior notice for improvement etc. Please
make sure that any information to be used is the latest one.
・Any example of operation or circuitry described in this application note is only for reference, and we are
not liable to any infringement of industrial property rights, intellectual property rights or any other rights
owned by third parties resulting from such examples.
・In the event that you use any product described here in combination with other products, please review
the feasibility of combination at your responsibility.
・Although we endeavor to improve the quality and reliability of our product, in the case of semi-conductor
components, defects or failures which occur at a certain rate of probability are inevitable.
The user should take into adequate consideration the safety design in the equipment or the system in order
to prevent accidents causing death or injury, fires, social harms etc..
・Products described here are designed to be used in the general-purpose electronic equipment (home
appliances, office equipment, communication terminals, measuring equipment etc.).
If used in the equipment or system requiring super-high reliability (transport machinery and its control
equipment, traffic signal control equipment, disaster/crime prevention system, various safety apparatus
etc.), please consult with our sales office. Please do not use our product for the equipment requiring
ultrahigh reliability (aerospace equipment, atomic control, medical equipment for life support etc.) without
our written consent.
・The products described here are not of radiation proof type.
・The contents of this brochure shall not be transcribed nor copied without our written consent.
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