R
EM MICROELECTRONIC -
MARIN SA
EM6152
5V Automotive Regulator with Windowed Watchdog
Description
The EM6152 offers a high level of integration by combining
voltage regulation, voltage monitoring and software
monitoring using a windowed watchdog.
A comparator monitors the voltage applied at the V
IN
input
comparing it with an internal voltage reference V
REF
. The
power-on reset function is initialized after V
IN
reaches V
REF
and takes the reset output inactive after a delay T
POR
depending on external resistance R
OSC
. The reset output goes
active low when the V
IN
voltage is less than V
REF
. The
RES
and
EN
outputs are guaranteed to be in a correct state for a
regulated output voltage as low as 1.2 V. The watchdog
function monitors software cycle time and execution.
If software clears the watchdog too quickly (incorrect cycle
time) or too slowly (incorrect execution) it will cause the
system to be reset. For enhanced security, the watchdog
must be serviced within an “open” time window. During the
remaining time, the watchdog time window is “closed” and a
reset will occur should a
TCL
pulse be received by the
watchdog during this “closed” time window. The ratio of the
open/closed window is either 33%/67% or 67%/33%.
The system ENABLE output prevents critical control functions
being activated until software has successfully cleared the
watchdog three times. Such a security could be used to
prevent motor controls being energized on repeated resets of
a faulty system.
When the microcontroller goes in stand-by mode or stops
working, no signal is received on the
TCL
input of the
EM6152 (version 55) and it goes into a stand-by mode in
order to save power (CAN-bus sleep detector).
In EM6152, the voltage regulator has a low dropout voltage
and a low quiescent current of 135
μA.
The quiescent current
increases only slightly in dropout prolonging battery life. Built-
in protection includes a positive transient absorber for up to
45 V (load dump) and the ability to survive an unregulated
input voltage of -42 V (reverse battery). The input may be
connected to ground or to a reverse voltage without reverse
current flowing from the output to the input.
Features
Low quiescent current 135
μA
-40°C to +125°C temperature range
Highly accurate 5 V, 400 mA guaranteed output (actual
maximum current depends on power dissipation)
Low dropout voltage, typically 250 mV at 250 mA
Unregulated DC input can withstand -42 V reverse battery
and +45 V power transients
Fully operational for unregulated DC input voltage up to
40 V and regulated output voltage down to 3.0 V
No reverse output current
Very low temperature coefficient for the regulated output
Current limiting
Windowed watchdog with an adjustable time windows,
guaranteeing a minimum time and a maximum time
between software clearing of the watchdog
Time base accuracy
±8%
(at 100ms)
Sleep mode function (V55)
Adjustable threshold voltage using external resistors
Adjustable power on reset (POR) delay using one
external resistor
Open-drain active-low RESET output
Reset output guaranteed for regulated output voltage
down to 1.2 V
System ENABLE output offers added security
Qualified according to AEC-Q100
Green SO-8 and PSOP2-16 packages (RoHS compliant)
Applications
Automotive systems
Industrial
Home security systems
Telecom / Networking
Computers
Set top boxes
Typical Operating Configuration
Unregulated
Voltage
INPUT
OUTPUT
+
100nF 22uF
Selection Table
5V
Part Number
V
DD
V
REF
Closed
Window
Open
Window
CAN-bus sleep
detector
Microprocessor
EM6152
22uF
+
R
1
EM6152
V30
EM6152
V50
EM6152
V53
EM6152
V55
1.17 V
1.52 V
1.52 V
1.275 V
67%
67%
33%
67%
33%
33%
67%
33%
R
OSC
V
IN
TCL
RES
I/O
RES
I/O
R
2
GND
No
No
No
Yes
R
OSC
V
SS
EN
Please refer to Fig. 4 for more information about the
open/closed window of the watchdog.
Fig. 1
Copyright © 2006, EM Microelectronic-Marin SA
rev. B / 06.06
1
www.emmicroelectronic.com
R
EM6152
Ordering Information
Part Number
Version
V
REF
Package
Delivery Form
Package
Marking
EM6152V30SO8A+
EM6152V30SO8B+
EM6152V30PS16B+
EM6152V50SO8A+
EM6152V50SO8B+
EM6152V50PS16B+
EM6152V53SO8A+
EM6152V53SO8B+
EM6152V53PS16B+
EM6152V55SO8A+
EM6152V55SO8B+
V30
1.17 V
SO-8
PSOP2-16
V50
1.52 V
SO-8
PSOP2-16
V53
V55
1.52V
1.275 V
SO-8
PSOP2-16
SO-8
Stick, 97 pcs
Tape & Reel, 2500 pcs
Tape & Reel, 2500pcs
Stick, 97 pcs
Tape & Reel, 2500 pcs
Tape & Reel, 2500pcs
Stick, 97 pcs
Tape & Reel, 2500 pcs
Tape & Reel, 2500pcs
Stick, 97 pcs
Tape & Reel, 2500 pcs
6152030
EM6152 030
6152050
EM6152 050
6152053
EM6152 053
6152055
Note:
the “+” symbol at the end of the part number means that this product is RoHS compliant (green).
SO8
Pin Assignment and Description
SO8
1
PSOP2-16
2
Name
Function
EN
1
2
3
4
8
7
6
5
V
IN
R
OSC
OUTPUT
INPUT
RES
TCL
EN
RES
Push-pull active low enable output
Open drain active low reset output.
RES
must be pulled up to V
OUTPUT
even if
unused
Watchdog timer clear input signal
GND terminal
Voltage regulator input
R
OSC
input for RC oscillator tuning
Voltage comparator input
No connect
Can be connected to Vss or left floating
EM6152
2
3
4
5
6
7
8
-
-
3
4
5
12
13
14
15
1, 6 to 11, 16
Heat Sink
Contact
V
SS
TCL
V
SS
PSOP2-16
NC
EN
RES
TCL
1
2
3
4
5
6
7
8
16
15
14
13
12
11
10
9
NC
V
IN
R
OSC
OUTPUT
INPUT
NC
NC
NC
INPUT
R
OSC
V
IN
NC
OUTPUT Voltage regulator output
V
SS
NC
NC
NC
EM6152
Block Diagram EM6152
INPUT
Voltage
Regulator
Enable
Logic
Voltage
Reference
V
REF
Comparator
OUTPUT
EN
Voltage
Reference
V
IN
-
+
Reset
Control
RES
R
OSC
Current
Controlled
Oscillator
Open drain
output RES
Timer
TCL
Fig. 3
Copyright © 2006, EM Microelectronic-Marin SA
rev. B / 06.06
2
www.emmicroelectronic.com
R
EM6152
Absolute Maximum Ratings
Parameter
Continuous voltage at INPUT
to V
SS
Transients on INPUT for
t < 100 ms and duty cycle 1%
Max. voltage at any signal pin
Min. voltage at any signal pin
Reverse supply voltage on
INPUT
Storage temperature
ESD
According to MIL-STD-883C
method 3015.7
Symbol
Conditions
V
INPUT
V
TRANS
V
MAX
V
MIN
V
REV
T
STO
V
Smax
-0.3 to +40V
Up to +45V
V
OUTPUT
+ 0.3V
V
SS
– 0.3V
-42V
-65 to +150 °C
2000V
Table 1
a low ESR value. Tantalum capacitors are recommended.
See the notes related to Table 2. Special care must be
taken in disturbed environments (automotive, proximity of
motors and relays, etc.).
Handling Procedures
This device has built-in protection against high static
voltages or electric fields; however, it is advised that normal
precautions be taken as for any other CMOS component.
Unless otherwise specified, proper operation can only occur
when all terminal voltages are kept within the voltage range.
At any time, all inputs must be tied to a defined logic voltage
level.
Operating Conditions
Parameter
Symbol
Operating junction
T
j
temperature
INPUT voltage (note 1)
V
INPUT
OUTPUT voltage (note 1, 2) V
OUTPUT
Min.
Max.
Units
Stresses above these listed maximum ratings may cause
permanent damages to the device. Exposure beyond
specified operating conditions may affect device reliability or
cause malfunction.
-40
2.3
1.2
1.2
+125
40
5.5
°C
V
V
V
Decoupling Methods
The input capacitor is necessary to compensate the line
influences. A resistor of approx. 1
Ω
connected in series
with the input capacitor may be used to damp the oscillation
of the input capacitor and input inductance. The ESR value
of the capacitor plays a major role regarding the efficiency of
the decoupling. It is recommended also to connect a
ceramic capacitor (100 nF) directly at the IC's pins. In
general the user must assure that pulses on the input line
have slew rates lower than 1 V/µs. On the output side, the
capacitor is necessary for the stability of the regulation
circuit. The stability is guaranteed for values of 22 µF or
greater. It is especially important to choose a capacitor with
V
OUTPUT
(note 3)
OUTPUT current (note 4)
I
OUTPUT
Comparator input voltage
V
IN
RC-oscillator programming
R
OSC
Package thermal resistance
from junction to ambient :
SO-8
R
th(j-a)
PSOP2-16 150 MILS
(note 5)
RES
and
EN
guaranteed
400
0
10
V
OUTPUT
1000
mA
V
k
Ω
30
160
90
°C/W
Table 2
Note 1:
Note 2:
Note 3:
Note 4:
Note 5:
full operation guaranteed. To achieve the load regulation specified in Table 3 a 22
μ
F capacitor or greater is required on the INPUT,
see Fig. 1b. The 22
μ
F must have an effective resistance
≤
5
Ω
and a resonant frequency above 500 kHz.
a 22
μ
F load capacitor and a 100 nF decoupling capacitor are required on the regulator OUTPUT for stability. The 22
μ
F must have
an effective series resistance of
≤
5
Ω
and a resonant frequency above 500 kHz.
RES
must be pulled up externally to V
OUTPUT
even if it is unused. ( RES and EN are used as inputs by EM test)
the OUTPUT current will not apply to the full range of input voltage. Power dissipation that would require the EM6152 to work above
the maximum junction temperature (+125°C) must be avoided.
the thermal resistance specified assumes the package is soldered to a PCB. A typical value of 51°C/W has been obtained with a dual
layer board, with the slug soldered to the heat-sink area of the PCB.
Copyright © 2006, EM Microelectronic-Marin SA
rev. B / 06.06
3
www.emmicroelectronic.com
R
EM6152
Electrical Characteristics
V
INPUT
= 13.5 V, C
L
= 22
μ
F + 100 nF, C
INPUT
= 22
μ
F, T
j
= -40 to +125°C, unless otherwise specified
Parameter
Supply current in standby mode and sleep
mode for V55
Symbol Test Conditions
R
OSC
= don’t care, TCL = V
OUTPUT
,
I
SS
V
IN
= 0 V, I
L
= 1 mA
R
OSC
= 100 k
Ω
, I/P
S
at V
OUTPUT
,
I
SS
Supply current (note1)
O/P
S
1 M
Ω
to V
OUTPUT
, I
L
= 1 mA
R
OSC
= 100 k
Ω
, I/P
S
at V
OUTPUT
,
I
SS
Supply current (note 1)
O/P
S
1 M
Ω
to V
OUTPUT
, I
L
= 250 mA
Output voltage
V
OUTPUT
5 mA
≤
I
L
≤
250 mA
V
LINE
12 V
≤
V
INPUT
≤
32 V, I
L
= 5 mA
Line regulation (note 2)
Load regulation (note 2)
V
L
5 mA
≤
I
L
≤
250 mA, V
INPUT
=6V
Dropout voltage (note 3)
V
DROPOUT
I
L
= 250 mA
Output voltage temperature coefficient (note 4) V
th(coeff)
Current limit
I
Lmax
OUTPUT tied to V
SS
, V
INPUT
=6V
RES
&
EN
V
OUTPUT
= 4.5 V, I
OL
= 8 mA
V
OL
Output Low Voltage
V
OUTPUT
= 2.0 V, I
OL
= 4 mA
V
OUTPUT
= 1.2 V, I
OL
= 0.5 mA
EN
V
OUTPUT
= 4.5 V, I
OH
= -1 mA
V
OH
Output High Voltage
V
OUTPUT
= 2.0 V, I
OH
= -100
μ
A
V
OUTPUT
= 1.2 V, I
OH
= -20
μ
A
TCL
Input Low Level
V
IL
TCL
Input High Level
V
IH
Leakage current
I
LI
V
SS
≤
V
TCL
≤
V
OUTPUT
Version V30
(replaces A6130)
Version V50
(replaces A6150 and A6250)
Comparator reference (note 5, 6)
V
REF
Version V53
Version V55
(replaces A6155)
Comparator hysteresis (note 6)
V
HY
V
IN
input resistance
R
VIN
Min.
Typ.
Max.
Unit
μ
A
μ
A
135
145
7
4.8
5
10
35
250
0.5
600
0.25
0.2
0.04
4.1
1.9
1.05
270
280
14
5.2
25
80
500
mA
V
mV
mV
mV
mV/°C
mA
V
V
V
V
V
V
V
V
μ
A
V
V
V
V
mV
M
Ω
Table 3
400
0.45
0.4
0.2
3.5
1.8
0.9
V
SS
2.5
1.135
1.475
1.475
1.235
0.5
V
OUTPUT
0.05
1.170
1.520
1.520
1.275
2
100
1.205
1.565
1.565
1.315
Note 1:
Note 2:
Note 3:
Note 4:
Note 5:
Note 6:
if INPUT is connected to V
SS
, no reverse current will flow from the OUTPUT to the INPUT, however the supply current specified will be
sank by the OUTPUT to supply the EM6152.
regulation is measured at constant junction temperature using pulse testing with a low duty cycle. Changes in OUTPUT voltage due to
heating effects are covered in the specification for thermal regulation.
the dropout voltage is defined as the INPUT to OUTPUT differential, measured with the input voltage equal to 5.0 V.
output voltage temperature coefficient is defined as the change in OUTPUT voltage after a change in power dissipation is applied,
excluding load or line regulation effects.
the comparator and the voltage regulator have separate voltage references (see “Block Diagram” Fig. 3).
the comparator reference is the power-down reset threshold. The power-on reset threshold equals the comparator reference voltage
plus the comparator hysteresis (see Fig. 5).
Copyright © 2006, EM Microelectronic-Marin SA
rev. B / 06.06
4
www.emmicroelectronic.com
R
EM6152
Timing Characteristics
V
INPUT
= 13.5 V, I
L
= 100
μ
A, C
L
= 22
μ
F + 100 nF, C
INPUT
= 22
μ
F, T
j
= -40 to + 125
°
C, unless otherwise specified
Parameter
Propagation delay
TCL
to Output Pins
V
IN
sensitivity
Watchdog Reset Pulse Period
Version V30
Power-on Reset delay
Closed Window Time
Open Window Time
Watchdog Time
Watchdog Reset Pulse Width if no
TCL
Version V50
Power-on Reset delay
Closed Window Time
Open Window Time
Watchdog Time
Watchdog Reset Pulse Width if no
TCL
Version V53
Power-on Reset delay
Closed Window Time
Open Window Time
Watchdog Time
Watchdog Reset Pulse Width if no
TCL
Version V55
Power-on Reset delay
Closed Window Time
Open Window Time
Watchdog Time
Watchdog Reset Pulse Width if no
TCL
Watchdog Reset Pulse Width in Sleep Mode
Watchdog Reset Pulse Period in Sleep Mode
Symbol Test Conditions
T
DIDO
T
SEN
V
INhigh
=1.1
x
V
REF
, V
INlow
=0.9
x
V
REF
T
WDRP
TCL
inactive
Min.
Typ. Max.
250
500
0.5
3
15
T
CW
+ T
OW
+ T
WDR
Units
ns
μ
s
ms
T
POR
T
CW
T
OW
T
WD
T
WDR
T
POR
T
CW
T
OW
T
WD
T
WDR
T
POR
T
CW
T
OW
T
WD
T
WDR
T
POR
T
CW
T
OW
T
WD
T
WDR
T
WDRS
T
WDRPS
R
OSC
= 116.9 k
Ω ±
1%
91.6
74
37
92.5
2.25
91.6
74
37
92.5
2.25
4.57
9.24
18.48
18.48
0.56
91.6
74
37
92.5
2.25
2.8
750
100
80
40
100
2.5
100
80
40
100
2.5
5.0
10
20
20
0.625
100
80
40
100
2.5
3.2
1100
108.3
85.76
42.88
107.2
2.75
108.3
85.76
42.88
107.2
2.75
5.44
10.77
21.54
21.54
0.69
108.3
85.76
42.88
107.2
2.75
3.6
1450
ms
R
OSC
= 121.6 k
Ω ±
1%
ms
R
OSC
= 23.2 k
Ω ±
1%
ms
R
OSC
= 107.5 k
Ω ±
1%
ms
R
OSC
off; R
INT
=1M
Ω
TCL
inactive
Table 4
For different values of T
WD
and R
OSC
, see figures 9 to 12.
Timing Waveforms
Watchdog Timeout Period
Version V50:
T
WD
For R
OSC
=121.6 kOhm
Version V53:
T
WD
For R
OSC
=23.2 kOhm
T
CW
(closed window)
T
OW
(open)
T
CW
(closed)
T
OW
(open)
Watchdog
timer reset
80
120
Time [ms]
Watchdog
timer reset
10
30
Time [ms]
( V30, V50 and V55 have similar ratios for T
CW
and T
OW
)
Fig. 4
Copyright © 2006, EM Microelectronic-Marin SA
rev. B / 06.06
5
www.emmicroelectronic.com
京公网安备 11010802033920号
EEWORLD
