FAIRCHILD KA3842

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KA3842B/KA3843B/KA3844B/KA3845B
SMPS Controller
Features
Description
•
•
•
•
The KA3842B/KA3843B/KA3844B/KA3845B are fixed
frequency current-mode PWM controller. They are specially designed for Off - Line and DC-to-DC converter
applications with minimum external components. These
integrated circuits feature a trimmed oscillator for precise
duty cycle control, a temperature compensated reference,
high gain error amplifier. current sensing comparator, and a
high current totempole output Ideally suited for driving a
power MOSFET. Protection circuity Includes built in
under-voltage lockout and current limiting. The KA3842B
and KA3844B have UVLO thresholds of 16V (on) and
10V (off) The KA3843B and KA3845B are 8.5V (on) and
7.9V (off) The KA3842B and KA3843B can operate within
100% duty cycle. The KA3844B and KA3845B can operate
with 50% duty cycle.
Low Start Up Current
Maximum Duty Clamp
UVLO With Hysteresis
Operating Frequency Up To 500KHz
8-DIP
1
14-SOP
1
Rev. 5.0
©2000 Fairchild Semiconductor International
KA3842B/KA3843B/KA3844B/KA3845B
Internal Block Diagram
Absolute Maximum Ratings
Parameter
Supply Voltage
Value
Unit
VCC
30
V
IO
±1
A
V(ANA)
-0.3 to 6.3
V
Error Amp Output Sink Current
ISINK (E.A)
10
mA
Power Dissipation (TA = 25°C)
PD
1
W
Output Current
Analog Inputs (Pin 2.3)
2
Symbol
KA3842B/KA3843B/KA3844B/KA3845B
Electrical Characteristics
(VCC=15V, RT=10KΩ, CT=3.3nF, TA= 0°C to +70°C, unless otherwise specified)
Parameter
Symbol
Conditions
Min.
Typ.
Max.
Unit
4.90
5.00
5.10
V
6
20
mV
REFERENCE SECTION
Reference Output Voltage
VREF
TJ = 25°C, IREF = 1mA
Line Regulation
∆VREF
12V≤VCC≤25V
-
Load Regulation
∆VREF
Short Circuit Output Current
1mA≤IREF≤20mA
-
6
25
mV
ISC
TA = 25°C
-
-100
-180
mA
f
TJ = 25°C
47
52
57
KHz
12V≤VCC≤25V
-
0.05
1
%
VOSC
-
-
1.6
-
VP-P
IBIAS
-
-
-0.1
-2
µA
2.42
2.50
2.58
V
2V≤ VO ≤4V
65
90
-
dB
OSCILLATOR SECTION
Oscillation Frequency
Frequency Change with Voltage
Oscillator Amplitude
∆f/∆VCC
ERROR AMPLIFIER SECTION
Input Bias Current
Input Voltage
Open Loop Voltage Gain
VI(E>A)
GVO
V1 = 2.5V
Power Supply Rejection Ratio
PSRR
12V≤ VCC ≤25V
60
70
-
dB
Output Sink Current
ISINK
V2 = 2.7V, V1 = 1.1V
2
7
-
mA
-0.6
-1.0
-
mA
Output Source Current
ISOURCE
V2 = 2.3V, V1 = 5V
High Output Voltage
VOH
V2 = 2.3V, RL = 15KΩ to GND
5
6
-
V
Low Output Voltage
VOL
V2 = 2.7V, RL = 15KΩ to Pin 8
-
0.8
1.1
V
GV
(Note 1 & 2)
2.85
3
3.15
V/V
V1 = 5V(Note 1)
0.9
1
1.1
V
-
70
-
dB
-
-3
-10
µA
ISINK = 20mA
-
0.08
0.4
V
ISINK = 200mA
-
1.4
2.2
V
ISOURCE = 20mA
13
13.5
-
V
ISOURCE = 200mA
12
13.0
-
V
CURRENT SENSE SECTION
Gain
Maximum Input Signal
VI(MAX)
Power Supply Rejection Ratio
PSRR
Input Bias Current
IBIAS
12V≤ VCC ≤25V (Note 1)
-
OUTPUT SECTION
Low Output Voltage
High Output Voltage
VOL
VOH
Rise Time
tR
TJ = 25°C, CL= 1nF (Note 3)
-
45
150
ns
Fall Time
tF
TJ = 25°C, CL= 1nF (Note 3)
-
35
150
ns
KA3842B/KA3844B
14.5
16.0
17.5
V
KA3843B/KA3845B
7.8
8.4
9.0
V
KA3842B/KA3844B
8.5
10.0
11.5
V
KA3843B/KA3845B
7.0
7.6
8.2
V
UNDER-VOLTAGE LOCKOUT SECTION
Start Threshold
Min. Operating Voltage
(After Turn On)
VTH(ST)
VOPR(MIN)
3
KA3842B/KA3843B/KA3844B/KA3845B
Electrical Characteristics (Continued)
(VCC=15V, RT=10KΩ, CT=3.3nF, TA= 0°C to +70°C unless otherwise specified)
Parameter
Symbol
Conditions
Min.
Typ.
Max.
Unit
PWM SECTION
Max. Duty Cycle
Min. Duty Cycle
D(max)
KA3842B/KA3843B
95
97
100
%
D
KA3844B/KA3845B
47
48
50
%
D(MIN)
-
-
-
0
%
IST
-
-
0.45
1
mA
TOTAL STANDBY CURRENT
Start-Up Current
Operating Supply Current
Zener Voltage
ICC(OPR)
V3=V2=ON
-
14
17
mA
VZ
ICC = 25mA
30
38
-
V
Adjust VCC above the start threshould before setting at 15V
Note:
1. Parameter measured at trip point of latch
2. Gain defined as:
∆V
A = ----------1
,0 ≤ V3 ≤ 0.8V
∆V 3
3.These parameters, although guaranteed, are not 100 tested in production.
Figure 1. Open Loop Test Circuit
High peak currents associated with capacitive loads necessitate careful grounding techniques Timing and bypass capacitors
should be connected close to pin 5 in a single point ground. The transistor and 5KΩ potentiometer are used to sample the
oscillator waveform and apply an adjustable ramp to pin 3.
4
KA3842B/KA3843B/KA3844B/KA3845B
Figure 2. Under Voltage Lockout
During Under-Voltage Lock-Out, the output driver is biased to a high impedance state. Pin 6 should be shunted to ground
with a bleeder resistor to prevent activating the power switch with output leakage current.
Figure 3. Error Amp Configuration
Figure 4. Current Sense Circuit
Peak current (IS) is determined by the formula:
1.0V
I S ( MAX ) = -----------RS
A small RC filter may be required to suppress switch transients.
5
KA3842B/KA3843B/KA3844B/KA3845B
Figure 5. Oscillator Waveforms and Maximum Duty Cycle
Oscillator timing capacitor, CT, is charged by VREF through RT, and discharged by an internal current source. During the discharge time, the internal clock signal blanks the output to the low state. Selection of RT and CT therefore determines both
oscillator frequency and maximum duty cycle. Charge and discharge times are determined by the formulas:
tc = 0.55 RT CT
0.0063R T – 2.7
t D = R T C T I n  ----------------------------------------
0.0063R T – 4
Frequency, then, is: f=(tc + td)-1
1.8
ForRT > 5KΩ ,f = --------------RT CT
Figure 6. Oscillator Dead Time & Frequency
Figure 7. Timing Resistance vs Frequency
(Deadtime vs CT RT > 5kΩ)
Figure 8. Shutdown Techniques
6
KA3842B/KA3843B/KA3844B/KA3845B
Shutdown of the KA3842B can be accomplished by two methods; either raise pin 3 above 1V or pull pin 1 below a voltage
two diode drops above ground. Either method causes the output of the PWM comparator to be high (refer to block diagram).
The PWM latch is reset dominant so that the output will remain low until the next clock cycle after the shutdown condition at
pins 1 and/or 3 is removed. In one example, an externally latched shutdown may be accomplished by adding an SOR which
will be reset by cycling Voc below the lower UVLO threshold. At this point the reference turns off, allowing the SCR to reset.
Figure 9. Slope Compensation
A fraction of the oscillator ramp can be resistively summed with the current sense signal to provide slope compensation for
converters requiring duty cycles over 50%. Note that capacitor, C, forms a filter with R2 to suppress the leading edge switch
spikes.
TEMPERATURE (°C)
TEMPERATURE (°C)
Figure 10. TEMPERATURE DRIFT (Vref)
Figure 11. TEMPERATURE DRIFT (Ist)
TEMPERATURE (°C)
Figure 12. TEMPERATURE DRIFT (Icc)
7
KA3842B/KA3843B/KA3844B/KA3845B
Mechanical Dimensions
Package
1.524 ±0.10
#5
2.54
0.100
5.08
MAX
0.200
7.62
0.300
3.40 ±0.20
0.134 ±0.008
+0.10
0.25 –0.05
+0.004
0~15°
8
0.010 –0.002
3.30 ±0.30
0.130 ±0.012
0.33
0.013 MIN
0.060 ±0.004
#4
0.018 ±0.004
#8
9.60
MAX
0.378
#1
9.20 ±0.20
0.362 ±0.008
(
6.40 ±0.20
0.252 ±0.008
0.46 ±0.10
0.79
)
0.031
8-DIP
KA3842B/KA3843B/KA3844B/KA3845B
Mechanical Dimensions (Continued)
Package
14-SOP
MIN
#8
0.60 ±0.20
0.024 ±0.008
MAX0.10
MAX0.004
1.80
MAX
0.071
5.72
0.225
8°
3.95 ±0.20
0.156 ±0.008
0~
+0.10
0.20 -0.05
+0.004
0.008 -0.002
6.00 ±0.30
0.236 ±0.012
+0.10
0.406 -0.05
+0.004
0.016 -0.002
#7
1.27
0.050
#14
8.70
MAX
0.343
#1
8.56 ±0.20
0.337 ±0.008
(
0.47
)
0.019
1.55 ±0.10
0.061 ±0.004
0.05
0.002
9
KA3842B/KA3843B/KA3844B/KA3845B
Ordering Information
Product Number
Package
Operating Temperature
KA3842B
KA3843B
KA3844B
8 DIP
KA3845B
0 ~ + 70°C
KA3842BD
KA3843BD
KA3844BD
KA3845BD
10
14 SOP
KA3842B/KA3843B/KA3844B/KA3845B
11
KA3842B/KA3843B/KA3844B/KA3845B
LIFE SUPPORT POLICY
FAIRCHILD’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES
OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF FAIRCHILD SEMICONDUCTOR
INTERNATIONAL. As used herein:
1. Life support devices or systems are devices or systems
which, (a) are intended for surgical implant into the body,
or (b) support or sustain life, and (c) whose failure to
perform when properly used in accordance with
instructions for use provided in the labeling, can be
reasonably expected to result in a significant injury of the
user.
2. A critical component in any component of a life support
device or system whose failure to perform can be
reasonably expected to cause the failure of the life support
device or system, or to affect its safety or effectiveness.
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