STMICROELECTRONICS L4972AD013TR

L4972A
2A SWITCHING REGULATOR
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Features
2A OUTPUT CURRENT
5.1V TO 40V OUTPUT VOLTAGE RANGE
0 TO 90% DUTY CYCLE RANGE
INTERNAL FEED-FORWARD LINE REG.
INTERNAL CURRENT LIMITING
PRECISE 5.1V ± 2% ON CHIP REFERENCE
RESET AND POWER FAIL FUNCTIONS
INPUT/OUTPUT SYNC PIN
UNDER VOLTAGE LOCK OUT WITH
HYSTERETIC TURN-ON
PWM LATCH FOR SINGLE PULSE PER
PERIOD
VERY HIGH EFFICIENCY
SWITCHING FREQUENCY UP TO 200KHz
THERMAL SHUTDOWN
CONTINUOUS MODE OPERATION
Description
The L4972A is a stepdown monolithic power
switching regulator delivering 2A at a voltage variable from 5.1 to 40V.
Realized with BCD mixed technology, the device
Figure 1. Packages
PowerDIP20 (16+2+2)
SO20
Table 1. Order Codes
Part Number
Package
L4972A
DIP20 (16+2+20)
L4972AD
SO20
L4972AD013TR
SO20 in Tape & Reel
uses a DMOS output transistor to obtain very high
efficiency and very fast switching times. Features
of the L4972 include reset and power fail for microprocessors, feed forward line regulation, soft start,
limiting current and thermal protection. The device
is mounted in a Powerdip 16 + 2 + 2 and SO20
large plastic packages and requires few external
components. Efficient operation at switching frequencies up to 200KHz allows reduction in the
size and cost of external filter component.
Figure 2. Block Diagram
May 2005
Rev. 3
1/22
L4972A
Table 2. Pin Description
N°
Pin
1
BOOTSTRAP
A Cboot capacitor connected between this terminal and the output allows to drive
properly the internal D-MOS transistor.
Function
2
RESET DELAY
A Cd capacitor connected between this terminal and ground determines the reset
signal delay time.
3
RESET OUT
Open Collector Reset/power Failand the output voltages are safe. Signal Output.
This output is high when the supply
4
RESET INPUT
Input of Power Fail Circuit. The threshold is 5.1V. It may be connected via a divider
to the input for power fail function. It must be connected to the pin 14 an external
30KΩ resistor when power fail signal not required.
5, 6 15,
16
GROUND
7
FREQUENCY
COMPENSATION
8
SOFT START
9
FEEDBACK INPUT
The Feedback Terminal of the Regulation Loop. The output is connected directly to
this terminal for 5.1V operation; It is connected via a divider for higher voltages.
10
SYNC INPUT
Multiple L4972A’s are synchronized by connecting pin 10 inputs together or via an
external syncr. pulse.
Common Ground Terminal
A series RC network connected between this terminal and ground determines the
regulation loop gain characteristics.
Soft Start Time Constant. A capacitor is connected between the sterminal and
ground to define the soft start time constant.
11
SUPPLY VOLTAGE
12, 19
N.C.
Unregulated Input Voltage.
Not Connected.
13
Vref
5.1V Vref Device Reference Voltage.
14
Vstart
Internal Start-up Circuit to Drive the Power Stage.
17
OSCILLATOR
Rosc. External resistor connected to ground determines the constant charging
current of Cosc.
18
OSCILLATOR
Cosc. External capacitor connected to ground determines (with Rosc) the switching
frequency.
20
OUTPUT
Regulator Output.
Figure 3. Pin Connection (Top view)
BOOTSTRAP
1
20
OUTPUT
RESET DELAY
2
19
N.C.
RESET OUT
3
18
C OSC
P. FAIL INPUT
4
17
R OSC
GND
5
16
GND
GND
6
15
GND
FREQ. COMP.
7
14
Vstart
SOFT START
8
13
Vref
FEEDBACK IN.
9
12
N.C.
10
11
Vi
SYNC INPUT
DIP20
2/22
L4972A
Table 3. Absolute Maximum Ratings
Symbol
Parameter
Value
Unit
V11
Input Voltage
55
V
V11
Input Operating Voltage
50
V
V20
Output DC Voltage
Output Peak Voltage at t = 0.1µs f = 200kHz
-1
-5
V
V
I20
Maximum Output Current
VI
Boostrap Voltage
Boostrap Operating Voltage
65
V11 + 15
V
V
V4, V8
V3
Internally Limited
Input Voltage at Pins 4, 12
12
V
Reset Output Voltage
50
V
Reset Output Sink Current
50
mA
Input Voltage at Pin 2, 7, 9, 10
7
V
I2
Reset Delay Sink Current
30
mA
I7
Error Amplifier Output Sink Current
1
A
I8
Soft Start Sink Current
30
mA
Total Power Dissipation at TPINS ≤ 90°C
at Tamb = 70°C (No copper area on PCB)
5 / 3.75(*)
1.3/1 (*)
W
W
Junction and Storage Temperature
-40 to 150
°C
I3
V2, V7, V9,
V10
Ptot
TJ, Tstg
(*) SO-20
Table 4. Thermal Data
Symbol
3
PowerDIP
SO20
Unit
Rth j-pins
Thermal Resistance Junction-Pins
Parameter
max,
12
16
°C/W
Rth j-amb
Thermal Resistance Junction-ambient
max,
60
80
°C/W
Circuit Operation
The L4972A is a 2A monolithic stepdown switching regulator working in continuous mode realized in the
new BCD Technology. This technology allows the integration of isolated vertical DMOS power transistors
plus mixed CMOS/Bipolar transistors.
The device can deliver 2A at an output voltage adjustable from 5.1V to 40V and contains diagnostic and
control functions that make it particularly suitable for microprocessor based systems.
3.1 BLOCK DIAGRAM
The block diagram shows the DMOS power transistors and the PWM control loop. Integrated functions
include a reference voltage trimmed to 5.1V ± 2%, soft start, undervoltage lockout, oscillator with feedforward control, pulse by pulse current limit, thermal shutdown and finally the reset and power fail circuit. The
reset and power fail circuit provides an output signal for a microprocessor indicating the status of the system.
Device turn on is around 11V with a typical 1V hysterysis, this threshold porvides a correct voltage for the
driving stage of the DMOS gate and the hysterysis prevents instabilities.
An external bootstrap capacitor charge to 12V by an internal voltage reference is needed to provide correct gate drive to the power DMOS. The driving circuit is able to source and sink peak currents of around
0.5A to the gate of the DMOS transistor. A typical switching time of the current in the DMOS transistor is
50ns. Due to the fast commutation switching frequencies up to 200kHz are possible.
The PWM control loop consists of a sawtooth oscillator, error amplifier, comparator, latch and the output
3/22
L4972A
stage. An error signal is produced by comparing the output voltage with the precise 5.1V ± 2% on chip
reference. This error signal is then compared with the sawtooth oscillator in order to generate frixed frequency pulse width modulated drive for the output stage. A PWM latch is included to eliminate multiple
pulsing within a period even in noisy environments.
The gain and stability of the loop can be adjusted by an external RC network connected to the output of
the error amplifier. A voltage feedforward control has been added to the oscillator, this maintains superior
line regulation over a wide input voltage range. Closing the loop directly gives an output vol-tage of 5.1V,
higher voltages are obtained by inserting a voltage divider.
At turn on, output overcurrents are prevented by the soft start function (fig. 5). The error amplifier is initially
clamped by an external capacitor, Css, and allowed to rise linearly under the charge of an internal constant
current source.
Output overload protection is provided by a current limit circuit. The load current is sensed by a internal
metal resistor connected to a comparator. When the load current exceeds a preset threshold, the output
of the comparator sets a flip flop which turns off the power DMOS. The next clock pulse, from an internal
40kHz oscillator, will reset the flip flop and the power DMOS will again conduct. This current protection
method, ensures a constant current output when the system is overloaded or short circuited and limits the
switching frequency, in this condition, to 40kHz. The Reset and Power fail diagram (fig. 7), generates an
output signal when the supply voltage exceeds a threshold programmed by an external voltage divider.
The reset signal, is generated with a delay time programmed by a external capacitor on the delay pin.
When the supply voltage falls below the threshold or the output voltage goes below 5V, the reset output
goes low immediately. The reset output is an open drain.
Fig. 7A shows the case when the supply voltage is higher than the threshold, but the output voltage is not
yet 5V.
Fig. 7B shows the case when the output is 5.1V, but the supply voltage is not yet higher than the fixed
threshold. The thermal protection disables circuit operation when the junction temperature reaches about
150°C and has a hysterysis to prevent unstable conditions.
Figure 4. Feedforward Waveform.
Figure 5. Soft Start Function.
4/22
L4972A
Figure 6. Limiting Current Function.
Figure 7. Reset and Power Fail Functions
A
B
5/22
L4972A
4
Electrical Characteristcs
Table 5. Electrical Characteristcs
Refer to the test circuit, TJ = 25°C, Vi = 35V, R4 = 30KΩ, C9 = 2.7nF, fSW = 100KHz typ, unless otherwise
specified.
Symbol
Parameter
Test Condition
Min.
Typ.
Max.
Unit
Fig.
50
V
8
5.1
5.2
V
8
DYNAMIC CHARACTERISTICS
Vi
Input Volt. Range (pin 11)
Vo = Vref to 40V Io = 2A (**)
15
Vo
Output Voltage
Vi =15V to 50V Io= 1A;
Vo = Vref
5
∆Vo
Line Regulation
Vi =15V to 50V
Io = 0.5A; Vo= Vref
12
30
mV
∆Vo
Load Regulation
Vo = Vref Io= 0.5A to 2A
7
20
mV
Vd
Dropout Voltage between Pin
11 and 20
Io = 2A
0.25
0.4
V
I20L
Max Limiting Current
Vi = 15V to 50V
Vo= Vref to 40V
2.5
2.8
3.5
A
Efficiency (*)
Io = 2A, f = 100KHz
Vo = Vref
Vo = 12V
75
85
90
%
%
Supply Voltage Ripple Rejection Vi = 2VRMS; Io= 1A
f = 100Hz; Vo= Vref
56
60
dB
8
Switching Frequency
90
100
110
KHz
8
6
%
8
%
8
KHz
8
η
SVR
f
∆f/∆Vi
Voltage Stability of Switching
Frequency
Vi = 15V to 45V
2
∆f/Tj
Temperature Stability of
Switching Frequency
Tj = 0 to 125°C
1
fmax
Maximum Operating Switching
Frequency
Vo= Vref R4 = 15KΩ
Io = 2A C9= 2.2nF
200
(*) Only for DIP version (**) Pulse testing with a low duty cycle
Vref SECTION (pin 13)
V13
Reference Voltage
∆V13
Line Regulation
∆V13
Load Regulation
∆V13 /∆T Average Temperature
Coefficient Reference Voltage
I13 short
Short Circuit Current Limit
5
Vi = 15V to 50V
5.1
5.2
V
10
10
25
mV
10
40
I13 = 0 to 1mA
20
mV
10
Tj = 0°C to 125°C
0.4
mV/°C
10
V13 = 0
70
mA
10
V
10
VSTART SECTION (pin 15)
V14
Reference Voltage
∆V14
Line Regulation
Vi = 15 to 50V
0.6
1.4
V
10
∆V14
Load Regulation
I14 = 0 to 1mA
50
200
mV
10
Short Circuit Current Limit
V15 = 0V
80
mA
10
12
V
12
I14 short
11.4
12
12.6
DC CHARACTERISTICS
V11on
Turn-on Threshold
10
V11 Hyst Turn-off Hysteresys
11
V
12
I11Q
Quiescent Current
V8 = 0; S1 = D
13
19
mA
12
I11OQ
Operating Supply Current
V8 = 0; S1 = B; S2 = B
16
23
mA
12
6/22
1
L4972A
Table 5. Electrical Characteristcs (continued)
Refer to the test circuit, TJ = 25°C, Vi = 35V, R4 = 30KΩ, C9 = 2.7nF, fSW = 100KHz typ, unless otherwise
specified.
Symbol
I20L
Parameter
Out Leak Current
Test Condition
Min.
Typ.
Vi = 55V; S3 = A; V8= 0
Max.
Unit
Fig.
2
mA
12
150
µA
13
1
0.7
V
V
13
13
V
14
SOFT START (pin 8)
I8
Soft Start Source Current
V8 = 3V; V9= 0V
V8
Output Saturation Voltage
I8 = 20mA; V11= 10V
I8= 200µA; V11= 10V
80
115
ERROR AMPLIFIER
V7H
High Level Out Voltage
I7 = 100µA; S1 = C; V9 = 4.7V
6
V7L
Low Level Out Voltage
I7 = 100µA; S1 = C; V9= 5.3V
I7H
Source Output Current
V7 = 1V; V7 = 4.7V
100
150
1.2
100
150
Sink Output Current
V7 = 6V; V9 = 5.3V
I9
Input Bias Current
S1 = B; RS = 10KΩ
GV
DC Open Loop Gain
S1 = A; RS= 10Ω
60
60
-I7L
SVR
Supply Voltage Rejection
15 < Vi < 50V
VOS
Input Offset Voltage
RS= 50Ω S1 = A
0.4
3
80
V
14
µA
14
µA
14
µA
14
dB
14
dB
14
mV
14
1.5
V
12
2.5
5.5
V
V
12
12
2
10
RAMP GENERATOR (pin 18)
V18
Ramp Valley
S1 = B; S2 = B
V18
Ramp Peak
S1 = B; S2 = B
Vi = 15V
Vi = 45V
1.2
I18
Min. Ramp Current
S1 = A; I17= 100µA
I18
Max. Ramp Current
S1 = A; I17= 1mA
2.4
270
300
2.7
µA
12
mA
12
SYNC FUNCTION (pin 10)
V10
Low Input Voltage
Vi = 15V to 50V; V8 = 0;
S1 = B; S2 = B; S4 = B
–0.3
0.9
V
12
V10
High Input voltage
V8 = 0; S1 = B; S2 = B; S4 = B
2.5
5.5
V
12
I10L
Sync Input Current with Low
Input Voltage
V10= V18= 0.9V; S4 = B;
S1 = B; S2 = B
0.4
mA
12
I10H
Input Current with High
Input Voltage
V10= 2.5V
1.5
mA
12
V10
Output Amplitude
V
–
tW
Output Pulse Width
Vthr = 2.5V
4
5
0.3
0.5
0.8
µs
–
RESET AND POWER FAIL FUNCTIONS
V9R
Rising Thereshold Voltage (pin 9) Vi = 15 to 50V
V4 = 5.3V
Vref
-130
Vref
-100
Vref
-80
V
mV
15
V9F
Falling Thereshold Voltage (pin 9) Vi = 15 to 50V
V4 = 5.3V
4.77
Vref
-200
Vref
-160
V
mV
15
V2H
Delay High Threshold Volt.
Vi = 15 to 50V
V4 = 5.3V; V9 = V13
4.95
5.1
5.25
V
15
V2L
Delay Low Threshold Volt.
Vi = 15 to 50V;V4 = 4.7V; V9 = V13
1
1.1
1.2
V
15
I2SO
Delay Source Current
V4 = 5.3V; V2 = 3V
30
60
80
µA
15
I2SI
Delay Source Sink Current
V4 = 4.7V; V2 = 3V
10
mA
15
V3S
Output Saturation Voltage
I3 = 15mA; S1 = B V4 = 4.7V
0.4
V
15
Output Leak Current
V3 = 50V; S1 = A
100
µA
15
I3
7/22
L4972A
Table 5. Electrical Characteristcs (continued)
Refer to the test circuit, TJ = 25°C, Vi = 35V, R4 = 30KΩ, C9 = 2.7nF, fSW = 100KHz typ, unless otherwise
specified.
Symbol
Parameter
V4R
Rising Threshold Voltage
V4H
Hysteresis
I4
Test Condition
V9 = V13
Input Bias Current
Min.
Typ.
Max.
Unit
4.95
5.1
5.25
V
15
0.4
0.5
0.6
V
15
1
3
µA
15
Figure 8.
TYPICAL PERFORMANCES (using evaluation board) :
n = 83% (Vi = 35V ; Vo = VREF ; Io = 2A ; fsw = 100KHz)
Vo RIPPLE = 30mV (at 1A)
Line regulation = 12mV (Vi = 15 to 50V)
Load regulation = 7mV (Io = 0.5 to 2A)
for component values Refer to the fig. 8 (Part list).
Figure 9. Component Layout of fig. 8. Evaluation Board Available (only for DIP version)
8/22
Fig.
L4972A
PART LIST
R1 = 30KΩ
R2 = 10KΩ
R3 = 15KΩ
R4 = 30KΩ
R5 = 22Ω
R6 = 4.7KΩ
R7 = see table 6
R8 = OPTION
R9 = 4.7KΩ
* C1 = C2 = 1000mF 63V EYF (ROE)
C3 = C4 = C5 = C6 = 2,2µF 50V
C7 = 390pF Film
C8 = 22nF MKT 1837 (ERO)
C9 = 2.7nF KP 1830 (ERO)
C10 = 0.33µF Film
C11 = 1nF
** C12 = C13 = C14 = 100µF 40V EKR (ROE)
C15 = 1µF Film
D1 = STPS5L60
L1 = 150µH
core 58310 MAGNETICS
45 TURNS 0.91mm (AWG 19)
COGEMA 949181
* 2 capacitors in parallel to increase input RMS current capability.
* * 3 capacitors in parallel to reduce total output ESR.
Table 6.
V0
R9
R7
12V
4.7kΩ
6.2kΩ
15V
4.7kΩ
9.1kΩ
18V
4.7kΩ
12Ω
24V
4.7kΩ
18Ω
Note:
In the Test and Application Circuit for L4972D are not
mounted C2, C14 and R8.
Table 7. Suggested Boostrap Capacitors
Operating Frequency
Boostrap Cap.c10
f = 20KHz
≥680nF
f = 50KHz
≥470nF
f = 100KHz
≥330nF
f = 200KHz
≥220nF
f = 500KHz
≥100nF
9/22
L4972A
Figure 10. P.C. Board and Component Layout of the Circuit of Fig. 8.
Figure 11. DC Test Circuits
Figure 12.
10/22
L4972A
Figure 13.
Figure 14.
Figure 15.
Figure 16. Quiescent Drain Current vs. Supply
Voltage (0% duty cycle - see fig. 12).
Figure 17. Quiescent Drain Current vs.
Junction Temperature (0% duty cycle).
11/22
L4972A
Figure 18. Quiescent Drain Current vs. Duty
Cycle.
Figure 21. Reference Voltage (pin 14) vs. Vi
(see fig. 11).
Figure 19. Reference Voltage (pin 13) vs. Vi
(see fig. 11).
Figure 22. Reference Voltage (pin 14) vs.
Junction Temperature (see fig. 11).
Figure 20. Reference Voltage (pin 13) vs.
Junction Temperature (see fig. 11).
Figure 23. : Ref. Voltage 5.1V (pin 13) Supply
Voltage Ripple Rejection vs. Frequency
12/22
L4972A
Figure 24. Switching Frequency vs. Input
Voltage (see fig. 8).
Figure 27. Maximum Duty Cycle vs. Frequency.
Figure 25. Switching Frequency vs. Junction
Temperature (see fig. 8).
Figure 28. Supply Voltage Ripple Rejection vs.
Frequency (see fig. 8).
Figure 26. Switching Frequency vs. R4 (see
fig.8).
Figure 29. Efficiency vs. Output Voltage.
13/22
L4972A
Figure 30. Line Transient Response (see fig. 8).
Figure 33. .Dropout Voltage between Pin 11
and Pin 20 vs. Junction Temperature.
Figure 31. Line Transient Response (see fig. 8).
Figure 34. Power Dissipation (device only) vs.
Input Voltage.
Figure 32. Dropout Voltage between Pin 11 and
Pin 20 vs. Current at Pin 20.
Figure 35. Power Dissipation (device only) vs.
Input Voltage.
14/22
L4972A
Figure 36. Power Dissipation (device only) vs.
Output Voltage.
Figure 39. Power Dissipation (device only) vs.
Output Current
Figure 37. Power Dissipation (device only) vs.
Output Voltage
Figure 40. Efficiency vs. Output Current.
Figure 38. Power Dissipation (device only) vs.
Output Current
Figure 41. Test PCB Thermal Characteristic.
15/22
L4972A
Figure 42. Rth j-amb vs. Area on Board
Heatsink (DIP 16+2+2)
Figure 45. Maximum Allowable Power
Dissipation vs. Ambient Temperature (SO20)
Figure 43. Rth j-amb vs. Area on Board
Heatsink (SO20)
Figure 46. Open Loop Frequency and Phase of
Error Amplifier (see fig. 14).
Figure 44. Maximum Allowable Power
Dissipation vs. Tamb (Powerdip)
16/22
L4972A
Figure 47. 2A – 5.1V Low Cost Application Circuit.
Figure 48. A 5.1V/12V Multiple Supply. Note the Synchronization between the L4972A and L4970A.
Figure 49. L4972A’s Sync. Example.
17/22
L4972A
Figure 50. 1A/24V Multiple Supply. Note the synchronization between the L4972A and L4962
18/22
L4972A
5
Package Information
Figure 51. PowerDIP20 Mechanical Data & Package Dimensions
mm
DIM.
MIN.
a1
0.51
B
0.85
b
b1
TYP.
inch
MAX.
MIN.
TYP.
MAX.
0.020
1.40
0.033
0.50
0.38
0.055
0.020
0.50
D
0.015
0.020
24.80
0.976
E
8.80
0.346
e
2.54
0.100
e3
22.86
0.900
F
7.10
0.280
I
5.10
0.201
L
OUTLINE AND
MECHANICAL DATA
3.30
0.130
Powerdip 20
Z
1.27
0.050
19/22
L4972A
Figure 52. SO20 Mechanical Data & Package Dimensions
mm
inch
DIM.
MIN.
TYP.
MAX.
MIN.
TYP.
MAX.
A
2.35
2.65
0.093
0.104
A1
0.10
0.30
0.004
0.012
B
0.33
0.51
0.013
0.200
C
0.23
0.32
0.009
0.013
D (1)
12.60
13.00
0.496
0.512
E
7.40
7.60
0.291
0.299
e
1.27
0.050
H
10.0
10.65
0.394
0.419
h
0.25
0.75
0.010
0.030
L
0.40
1.27
0.016
0.050
k
ddd
OUTLINE AND
MECHANICAL DATA
0˚ (min.), 8˚ (max.)
0.10
0.004
(1) “D” dimension does not include mold flash, protusions or gate
burrs. Mold flash, protusions or gate burrs shall not exceed
0.15mm per side.
SO20
0016022 D
20/22
L4972A
6
Revision History
Table 8. Revision History
Date
Revision
Description of Changes
June 2000
2
First Issue
May 2005
3
Modified look & feel layout.
Changed the name of D1 in the Part list to page 9/22.
21/22
L4972A
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22/22