STMICROELECTRONICS L4936EH

L4936E

ADVANCED VOLTAGE REGULATOR
ENABLE AND SENSE INPUTS (EN, SI) PROTECTED AGAINST NEGATIVE TRANSIENTS
DOWN TO -5V
RESET THRESHOLD ADJUSTABLE FROM
3.8 TO 4.7V
EXTREMELY LOW QUIESCENT CURRENT,
65µA (LESS THAN 90µA) IN STANDBY
MODE
OPERATING DC SUPPLY VOLTAGE RANGE
5V - 28V
OPERATING TRANSIENT SUPPLY VOLTAGE UP TO 40V
HIGH PRECISION STANDBY OUTPUT VOLTAGE 5V ± 1% WITH 100mA CURRENT CAPABILITY
OUTPUT 2 VOLTAGE 5V ± 2% WITH 400mA
CURRENT CAPABILITY (ADJ WIRED TO
VOUT2)
OUTPUT 2 VOLTAGE ADJUSTABLE BY EXTERNAL VOLTAGE DIVIDER
OUTPUT 2 DISABLE FUNCTION FOR
STANDBY MODE
MULTIWATT 11
MULTIWATT 15
ORDERING NUMBERS: L4936E (Multiwatt 11)
L4936EH (Multiwatt 15)
DESCRIPTION
The L4936E is a monolithic integrated dual voltage regulator with two very low dropout outputs
and additional functions as power-on reset and input voltage sense. It is designed for supplying the
microcomputer controlled systems especially in
automotive applications.
PIN CONNECTIONS (Top views)
11
OUT2
10
ADJ
15
OUT2
14
ADJ
13
OUT1
12
SO
11
N.C.
10
N.C.
9
OUT1
8
SO
7
RES
9
RES
6
GND
8
GND
5
EN
7
EN
4
CT
6
N.C.
3
PR
5
CT
2
SI
4
PR
1
VS1/VS2
3
SI
2
VS1
1
VS2
TAB CONNECTED TO PIN 6
D94AT077
TAB CONNECTED TO PIN 6
Multiwatt11
June 2000
D94AT078A
Multiwatt15
1/11
L4936E
ABSOLUTE MAXIMUM RATINGS
Symbol
VINDC
V INTR
IO
VSI
ISI
V EN
IEN
VRES , VSO
IRES , ISO
PO
Tstg
Tj
TJSD
Note:
Parameter
DC Operating Supply Voltage
Transient Operating Supply Voltage (T < 400ms)
Output Current
Sense Input Voltage (Voltage Forced) (note 2)
Sense Input Current (Current Forced) (note 2)
Enable Input Voltage (Voltage Forced) (note 2)
Sense Input Current (Current Forced) (note 2)
Output Voltages
Output Currents (Output Low)
Power Dissipation at Tamb = 80°C (note 3)
Multiwatt 11 (R th heatsink = 9K/W)
Storage Temperature
Operating Junction Temperature
Thermal shutdown junction temperature Output 2 will shut-down
typically at Tj 10K lower than output 1
Value
28
-14 to 40
internally limited
-20 to 20
±1
-20 to 20
±1
-0.3 to 20
5
5
Unit
V
V
-65 to 150
-40 to 150
165
°C
°C
°C
V
mA
V
mA
V
mA
W
The circuit is ESD protected according to MIL-STD-883C
Note 2: Current forced means voltage unlimited but current limited to the specified value
Voltage forced means voltage limi ted to the specified valueswhile the current is not limited
Note 3: Typical value soldered on a PC board with 8 cm2 copper ground plane (35mm thick)
BLOCK DIAGRAM
OUT1
VS1
1.23V
REFERENCE
REG1
OUT2
VS2
ADJ
EN
1.23V
REG2
1.23V
CT
RES
PR
1.4V
RESET
SO
SI
1.23V
GND
SENSE
D94AT074A
2/11
L4936E
THERMAL DATA
Symbol
Parameter
MW 11
Thermal Resistance Junction-case
Rth j-case
MW 15
Unit
°C/W
3
Note 3: Typical value soldered on a PC board with 8 cm2 copper ground plane (35mm thick)
PIN FUNCTIONS
PIN (MW 11)
1
1
2
3
4
5
6
7
8
9
10
11
PIN (MW 15)
1
2
3
4
5
7
8
9
12
13
14
15
6, 10, 11
Name
VS1
VS2
S1
PR
CT
EN
GND
RES
SO
OUT 1
ADJ
OUT 2
NC
Function
Supply Voltage (400mA Regulator)
Supply Voltage (100mA Regulator, Reset, Sense)
Sense Input
Reset Theresold Programming
Reset Delay Capacitor
Enable (low will activate the 400mA regulator)
Ground
Reset Output
Sense Output
100mA Regulator Output
Feedback of 400mA Regulator
400mA Regulator Output
Not Connected
ELECTRICAL CHARACTERISTICS (VS = 14V; Tj = -40 to 150°C unless otherwise specified.)
Symbol
Parameter
Test Condition
Min.
Typ.
Max.
Unit
4.9
5
5.1
V
4.8
5
0.1
0.2
5.2
0.2
0.4
25
V
V
V
mV
100
200
65
400
90
mA
µA
OUT 1
V O1
Supply Output Voltage
VDP1
Dropoutput Voltage 1
VOL01
Load Regulation 1
VLIM1
IQSB
Current Limit 1
Quiescent Current in Standby
Mode
VS = 6 to 28V;
IO1 = 400µA to 100mA
Tj ≤125°C; IO1 = 50 to 400µA
IOUT1 = 10mA
IOUT1 = 100mA; VS = 4.8V
IOUT1 = 1 to 100mA
(after regulation setting)
VOUT1 = 0.8 to 4.5V
IEN ≥ 2.4V (output 2 disabled)
IO1 = 0.1mA; VSI > 1.3V
TJ < 85°C; R PR = 0
µA
75
OUT 2
V O2
VDP2
Output Voltage 2
ADJ connected to OUT 2
Dropoutput Voltage 2
VOL02
Load Regulation 2
RADJ
ILIM2
IQ
Adjust Input Resistance
Current Limit 2
Quiescent Current
Enable = LOW; VS = 6 to 28V;
I02 = 5 to 400mA
IOUT2 = 100mA; VS = 4.8V
IOUT2 = 400mA; VS = 4.8V
IOUT1 = 5 to 400mA
(after regulation setting)
V02 = 0.8 to 4.5V
IOUT1 = 100mA; IOUT2 = 400mA
4.9
60
450
5.1
V
0.2
0.3
0.3
0.6
50
V
V
mV
100
650
150
1300
20
KΩ
mA
mA
20
mV
OUT1, OUT 2
VOLi 1,2
Line Regulation
VS = 6 to 28V; IO1 = 1mA,
IO2 = 5mA,
(after regulation setting)
3/11
L4936E
ELECTRICAL CHARACTERISTICS (Continued.)
Symbol
Parameter
Test Condition
Min.
Typ.
Max.
Unit
1
V
ENABLE INPUT
VENL
Enable Input Low Voltage
(Output 2 Active)
-20
VENH
Enable Input High Voltage
1.4
20
V
VENhyst
Enable Hysteresis
20
30
60
mV
IEN LOW
Enable Input Current Low
VEN = 0
-20
-8
-3
µA
IEN HIGH
Enable Input Current High
VEN = 1.1 to 7V; TJ < 130°C;
-1
0
1
µA
VEN = 1.1 to 7V;
TJ = 130 to 150°C;
-10
0
10
µA
RESET CIRCUIT
Reset Theresold Voltage
(note4)
R PR = ∞
R PR = 0
3.65
3.8
3.95
V
VRTH
Reset Theresold Hysteresis
R PR = ∞
15
40
100
mV
tRD min
Reset Pulse Delay
C RES = 47nF; t r ≤ 30µs; (note 5)
40
60
100
ms
tRD nom
Reset Pulse Delay
C RES = 47nF; (note 6)
60
100
140
ms
tRR
Reset Reaction Time
C RES = 47nF
10
50
150
ICT
Pull Down Capability of the
Discharge circuit
VOUT1 < VRT
3
6
15
µs
mA
ICT
Charge Current
VOUT1 > VRT
-1.3
-1
0.7
µA
VRESL
Reset Output Low Voltage
R RES = 10KΩ to VOUT1
VOUT1 ≥ 1.5V
0.4
V
VRESH
Reset Output High Leakage
current
VRES = 5V
1
µA
20
V
V
V RT
4.5
VO1-0.3 VO1-0.2
V
SENSE COMPARATOR
VSI
Functional Range
VSIT
Sense Threshold Voltage
-20
Falling Edge; TJ <130°C
1.08
1.16
1.24
Falling Edge; TJ 130 to 150°C
1.05
1.16
1.29
V
10
30
60
mV
0.4
V
VSITH
Sense Threshold Hysteresis
VSOL
Sense Output Low Voltage
V SI ≤ 1.05V; RSO =10KΩ
connected to 5V; V S ≥ 5V
ISOH
Sense Output Leakage
VSO = 5V; VSI ≥ 1.5V
VSI = 1.1 to 7V; TJ <130°C
-1
VSI = 1.1 to 7V; TJ 130 to 150°C
VSI = 0V
ISI HIGH
Sense Input Current High
ISI LOW
Sense Input Current Low
1
µA
0
1
µA
-10
0
10
µA
-20
-8
-3
µA
Note :
4) The reset threshold can be programmed continuously from typ 3.8V to 4.7V by changing a value of an external resistor from pin PR to GN
5) This is a minimum reset time according to the hysteresis of the comparator. Delay time starts with VOUT1 exceeding VRT
6) This is the nominal reset time depending on the discharging limit of C T (saturation voltage) and theupper threshold of the timer comparator.
Delay time starts with VOUT1 exceeding VRT
7) The leakage of CT must be less than 0.5mA (2V). If an external resistor between C T and VOUT1 is applied, the leakage current may be
increased. The external resistor should have more than 30KΩ.
for stability: Cs ≥ 1µF, C01 ≥ 10µF, C02 ≥ 10µF, ESR ≤ 5Ω (designed target for resistive load) For details see application note.
8) For transients exceeding 20V or -20V external protection is required at the Pins SI and EN as shown at Pin EN. The protection proposed will
provide proper function for transients in the range of ±200V. If the zener diode is omitted the external resistor should be raised to 200KΩ
to limit the current to 1mA. Without the zener diode, the function 20V or -20V can not be guaran teed.
4/11
L4936E
APPLICATION CIRCUIT
VS1
OUT1
CS
CO1
1.23V
REFERENCE
REG1
(Note 8)
OUT2
VS2
100K
15V
CO2
ADJ
EN
1.23V
REG2
CT
1.23V
for example
BZX97C15
CT (Note 7)
RES
VOUT1
PR
1.4V
RESET
R SO
SO
SI
1.23V
GND
SENSE
D94AT079A
FUNCTIONAL DESCRIPTION
The L4936E is a monolithic integrated dual voltage regulator, based on the STM modulator voltage regulator approach. Several outstanding features and auxiliary functions are implemented to
meet the requirements of supplying microprocessor systems in automotive applications. Nevertheless, it is suitable also in other applications where
two stabilized voltages are required. The modular
approach of this device allows to get easly also
other features and functions when required.
Standby Regulator
The standby regulator uses an Isolated collector
Vertical PNP transistor as a regulating element.
With this structure very low dropout voltage at
currents up to 100mA is obtained. The dropout
operation of the standby regulator is maintained
down to 3V input supply voltage. The output voltage is regulated up to the transient input supply
voltage of 40V. With this feature no functional interruption due to overvoltage pulses is generated.
In the standby mode when the output 2 is disabled, the current consumption of the device (qui-
escent current) is less than 90µA (14V supply
voltage).
To reduce the quiescent current peak in the undervoltage region and to improve the transient response in this region, the dropout voltage is controlled. A second regulation path will keep the
output voltage without load below 5.5V even at
high temperatures.
Output 2 Voltage
The output 2 regulator uses the same output
structure as the standby regulator but rated for
the output current of 400mA. The output voltage
is internally fixed to 5V if ADJ is connected to
VOUT2.
OUT2
ADJ
R1i
+
1.23V
R 1E
R 2E
RADJ
R2i
total 100K
typical
D94AT080
5/11
L4936E
The output 2 regulator can be switches OFF via
the enable input.
Connecting a resistor divider R1E, R2E to the ADJ,
OUT2 pin the output voltage 2 can be programmed to the value of

R1E(R2E + RADJ) 
VOUT2 = VOUT1 1 +
R2E • RADJ 

with RADJ = 60K to 150K and VOUT1 = 4.95 to
5.05V.
For an exact calculation the temperature coefficient (Tc -2000pprm) of the internal resistor
(RADJ) must be taken into account. Pin ADJ in this
mode should not have a capacitive burden because this would reduce the phase margin of the
regulator loop.
Reset circuit
The reset circuit supervises the standby output
voltage. The reset output (RES) is defined from
VOUT ≥ 1V.
Even if VS is lacking, the reset generator is supplied by the output voltage V OUT1.
The reset threshold of 4.7V is defined with the internal reference voltage (note 9) and standby output divider, when pin PR is left open. The reset
threshold voltage can be programmed in the
range from 3.8V to 4.7V by connecting an external resistor from pin PR to GND.
The value of the programming resistor RPR can
be calculated with:
RPR =
22K
−92.9K, 3.8V ≤ VRT ≤ 4.7V
4.7V
−1
VRT
The reset pulse delay time t RD, is defined with the
charge time of an external capacitor CT:
tRDmin =
CT •0.6V
(note 5)
1µA
tRDnom =
CT •1.4V
(note 6)
1µA
The reaction time of the reset circuit originates
6/11
from the noise immunity. Standby output voltage
drops below the reset threshold only a bit longer
than the reaction time results in a shorter reset
delay time. The nominal reset delay time will be
generated for standby output voltage drops longer
than approximately 50µs.
The minimum reset time is generated if reset condition only occures for a short time triggering a reset pulse but not completely discharging CT. The
reset can be related to output2 on request. If
higher charge currents for the reset capacitor are
required a resistors from Pin CT to OUT1, may be
used to increase the current. We recommended
the use of 10KΩ to 5V as an output pull up.
Sense Comparator
The sense comparator compares an input signal
with an internal voltage reference of typical 1.23V.
The use of an external voltage divider makes this
comparator very flexible in the application. It can
be used to supervise the input voltage either before or after the protection diode and to give additional information to the microprocessor like low
voltage warnings. We recommended the use of
10KΩ to 5V as an output pull up.
Note 9:
The reference is alternatively supplied from VS or VOUT1. If one supply
is present, the reference is operating.
Thermal Protection
Both outputs are provided with an overtemperature shut down regulation power dissipation down
to uncritical values.
Output 2 will shut down approximately 10K before
output 1.
Under normal conditions shut down of output 2
will allow the chip to cool down again. Thus output 1 will be unaffected.
The thermal shut down reduces the output voltages until power dissipation and the flow of thermal energy out of the chip balance.
Transient Sensitivity
In proper operation (VOUT > 4.5V) the reference is
supplied by V OUT1 thus reducing sensitivity to input transients.
Precise Data will be issued as soon as samples
are available.
L4936E
Figure 3: Reset Generator
OUT1
REF
1.23V
10...100K
1µA
17K
RES
74K
-
PR
+
VOUT1
Low threshold VBE at 1µA=0.5V at 25°C
REG
High threshold
=1.4
CT
CT
D94AT081
Figure 4:
7/11
L4936E
INPUT PROTECTION
The Inputs Enable (EN) and sense in(SI) are proFigure 5:
Input Characteristics of SI, EN:
8/11
tected against negative transients. Figure 5 is
showing the simplified schematic
L4936E
DIM.
A
B
C
D
E
F
MIN.
mm
TYP.
MAX.
MIN.
inch
TYP.
0.197
0.104
0.063
5
2.65
1.6
1
0.49
0.66
0.55
0.75
0.019
0.026
0.040
0.690
0.772
0.050
0.700
0.060
0.710
0.874
0.870
0.795
0.886
0.886
1.02
17.53
19.6
1.27
17.78
1.52
18.03
21.9
21.7
22.2
22.1
20.2
22.5
22.5
0.862
0.854
L2
L3
L4
L7
M
M1
17.65
17.25
10.3
2.65
4.25
4.63
18.1
17.75
10.9
2.9
4.85
5.53
0.695
0.679
0.406
0.104
0.167
0.182
S
S1
Dia1
1.9
1.9
3.65
2.6
2.6
3.85
0.075
0.075
0.144
4.55
5.08
OUTLINE AND
MECHANICAL DATA
0.039
G
G1
H1
H2
L
L1
17.5
10.7
MAX.
0.022
0.030
0.689
0.421
0.179
0.200
0.713
0.699
0.429
0.114
0.191
0.218
0.102
0.102
0.152
Multiwatt15 V
9/11
L4936E
DIM.
MIN.
mm
TYP.
A
B
C
MAX.
MIN.
inch
TYP.
5
2.65
1.6
MAX.
0.197
0.104
0.063
D
E
0.49
0.55
0.019
0.022
F
G
G1
0.88
1.45
16.75
1.7
17
0.95
1.95
17.25
0.035
0.057
0.659
0.067
0.669
0.037
0.077
0.679
H1
H2
L
19.6
21.9
22.2
20.2
22.5
0.862
0.874
0.795
0.886
L1
L2
L3
21.7
17.4
17.25
22.1
22.5
18.1
17.75
0.854
0.685
0.679
0.87
L4
L7
M
10.3
2.65
4.25
10.7
10.9
2.9
4.85
0.406
0.104
0.167
0.421
M1
S
S1
4.73
1.9
1.9
5.08
5.43
2.6
2.6
0.186
0.075
0.075
0.200
Dia1
3.65
3.85
0.144
10/11
1
OUTLINE AND
MECHANICAL DATA
0.039
0.772
17.5
4.55
0.689
0.179
0.886
0.713
0.699
0.429
0.114
0.191
0.214
0.102
0.102
0.152
Multiwatt11 V
L4936E
Information furnished is believed to be accurate and reliable. However, STMicroelectronics assumes no responsibility for the consequences
of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No license is
granted by implication or otherwise under any patent or patent rights of STMicroelectronics. Specification mentioned in this publication are
subject to change without notice. This publication supersedes and replaces all information previously supplied. STMicroelectronics products
are not authorized for use as critical components in life support devices or systems without express written approval of STMicroelectronics.
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11/11