MOTOROLA MC33099

Freescale Semiconductor, Inc.
MOTOROLA
Document order number: MC33099
Rev 4.0, 07/2004
SEMICONDUCTOR TECHNICAL DATA
33099
Freescale Semiconductor, Inc...
Adaptive Alternator Voltage
Regulator
ALTERNATOR VOLTAGE
REGULATOR
The 33099 is designed to regulate the output voltage in diode-rectified
alternator charging systems common to automotive applications. The 33099
provides either an analog or digital fixed frequency duty cycle (ON/OFF ratio)
control of an alternator’s field current. Load Response Control (LRC) of the
alternator field current is accomplished by selecting the duty cycle for
prevailing engine conditions to eliminate engine speed hunting and vibrations
caused by abrupt torque loading of the engine owing to sudden electrical loads
being applied to the system at low engine RPM. Four LRC rates are
selectable.
The 33099 uses a feedback voltage to establish an alternator field current
that is in harmony with system load currents. The output voltage is monitored
by an internal voltage divider scheme and compared to an internal voltage
ramp referenced to a bandgap voltage. This approach provides precision
output voltage control over a wide range of temperature, electrical loads, and
engine RPM.
DW SUFFIX
CASE 751G-04
16-TERMINAL SOICW
Features
• External High-Side MOSFET Control of a Ground-Referenced Field
Winding
• LRC Active During Initial Start
• Vset at ±0.1 V @ 25°C
• <0.1 V Variation Over Engine Speeds of 2,000 to 10,000 RPM
• <0.2 V Variation Over 10% to 95% of Maximum Field Current
• Controlled MOSFET and Field Flyback Diode Recovery Characteristics
for Minimum RFI
• Trimmed Devices Available at 14.6 V and 14.8 V (typical) Vset
ORDERING INFORMATION
Device
MC33099DW/R2
MC33099CDW/R2
33099Simplified
Simplified
Application
Diagram
Application
Diagram
33099
PHASE
GATE
FIELD
WINDING
SOURCE
PHASE FILTER
IGN
LAMP DRAIN
BAT
REMOTE
LRC1
LRC2
AGND
GND
© Motorola, Inc. 2004
IGNITION
SWITCH
CHASSIS
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Temperature
Range (TA)
Package
-40°C to 125°C
16 SOICW
Freescale Semiconductor, Inc.
REMOTE
Battery
BAT
Remote
Vrem
CB1
Vrs
0.6 V
Local
Local
Sense
Vo
Low
Pass
LB
Bandgap
Reference
Regulator
Vfb
Cf
(OTC)
1.25 V
Vls
S1
R1
PHASE
Phase
R4
Cuv
1.25 V
CB2
R5
R2
Freescale Semiconductor, Inc...
FB
RF
Crs
Vl
Over
Voltage
Detector
S2
Vhvl
Cph
F1
Osc
To
Logic
4 LSB
P16
Digital
Duty Cycle
Generator
4 MSB
Up/Down
Control
Switch
U/D
Counter
A
N
D
3
OR2
LRC TEST
IGN
IGN
VTigm
LCR1
LRC1
LRC2
LRC2
AGnd
AGND
Battery
VTdsc
Iign
Cds
Lam
LAMP
Drain
DRAIN
Z2
Lamp
Driver
Circuit
Lam
LAMP
Gate
GATE
Dtl
Current
Limit
Detector
Np
LCR Test
Z1
lpd
SOURCE
So
Thermal
Limit
Detector
Lamp
Polling
Circuit
u/d
VTssc
Drain
Polling
Circuit
A
N
D
2
GATE
Ga
Battery
1.25V
Cign
1
2
10
11
S3
Ign
Delay
Circuit
A
N
D
1
MUX
P256
u/d
Gate
Polling
Circuit
Css
OR1
OV
Vdac
8-Bit Counter
A/D Duty Cycle
Comparator
& Tracking
Circuit
Min Duty
Cycle
Generator
Cdc
DAC
F2
1.25 V
101 kHz
A
N
D
4
LD
R3
PHASE
Phase
Filter
FILTER
UV
Vg
lpu
VDD
(5.0 V)
Vref
(2.0 V)
Charge
Pump
Regulator
Internal
V reg
and Bias
Current
Regulator
VDD
Regulator
Rs
Gnd
GND
Figure 1. 33099 Simplified Internal Block Diagram
33099
2
MOTOROLA ANALOG INTEGRATED CIRCUIT DEVICE DATA
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GATE
1
16
SOURCE
BAT
2
15
PHASE
GND
3
14
NC
LAMP DRAIN
4
13
PHASE FILTER
LAMP GATE
5
12
LRC TEST
IGNITION
6
11
NC
LRC2
7
10
REMOTE
LRC1
8
9
AGND
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TERMINAL FUNCTION DESCRIPTION
Terminal
Terminal
Name
Formal Name
1
GATE
Gate Drive
2
BAT
Battery
Primary power connection to the system battery.
3
GND
Ground
Source lamp current and digital ground.
4
LAMP
DRAIN
Lamp Drain
Controls the Fault Lamp current.
5
LAMP
GATE
Lamp Gate
Controls the Fault Lamp internal driver as an override function.
6
IGN
Ignition
7
8
LRC2
LRC1
Load Response Control 2
Load Response Control 1
9
AGND
Analog Ground
10
REMOTE
Remote
11, 14
NC
No Connect
12
LRC TEST
Load Response Control Test
13
PHASE
FILTER
Phase Filter
15
PHASE
Phase Sense Input
16
SOURCE
Source
Definition
Controls the GATE of the MOSFET to control the alternator field current.
Controls the ON or OFF function of the regulator.
Inputs for selecting the LRC rate.
Ground connection for analog circuitry.
Provides for external Kelvin connection to system battery.
No internal connection to this terminal.
Provides acceleration of LRC rate for testing.
Provides access to Phase Resistive Divider for External Phase Filter capacitance.
Input for phase voltage.
Coupled to source of MOSFET to provide a GATE voltage reference and to monitor for
source shorts to ground.
MOTOROLA ANALOG INTEGRATED CIRCUIT DEVICE DATA
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33099
3
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.
MAXIMUM RATINGS
All voltages are with respect to ground unless otherwise noted.
Rating
Symbol
Value
Unit
V
ELECTRICAL RATINGS
Vbat
24
+Vmax
-Vmin
40
-2.5
Human Body Model (Note 3)
VESD1
±2000
Machine Model (Note 4) (Note 5)
VESD2
±200
Operating Junction Temperature
TJ
150
°C
Operating Ambient Temperature Range
TA
-40 to 125
°C
TSTG
-45 to 150
°C
Power Supply Voltage
Load Dump Transient Voltage (Note 1)
Negative Voltage (Note 2)
V
ESD Voltage
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THERMAL RATINGS
Storage Temperature Range
Power Dissipation and Thermal Characteristics
Maximum Power Dissipation @ TA = 125°C
Thermal Resistance, Junction-to-Ambient
Terminal Soldering Temperature (Note 6)
PD
640
mW
RθJA
85
°C/W
TSOLDER
220
°C
Notes
1. 125ns wide square wave pulse.
2. Maximum time = 2 minutes.
3. ESD1 testing is performed in accordance with the Human Body Model (CZAP =100 pF, RZAP =1500 Ω).
4.
ESD2 testing is performed in accordance with the Machine Model (CZAP =200 pF, RZAP =0 Ω).
5.
6.
ESD2 voltage capability of PHASE FILTER terminal is greater than 150 V. All other device terminals are as indicated.
Terminal soldering temperature is for 10 seconds maximum duration. Not designed for immersion soldering. Exceeding these limits may
cause malfunction or permanent damage to the device.
33099
4
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STATIC ELECTRICAL CHARACTERISTICS TA = 25°C unless otherwise noted.
Characteristic
Symbol
Vset
Regulation Voltage @ 50% Duty Cycle
Vrem = Vset or Vrem < VTrem
MC33099
Vrem = Vset or Vrem < VTrem
MC33099C
Min
Typ
Max
14.55
14.8
15.05
14.3
14.6
14.85
–
210
300
V
dVset
Regulation Voltage Range
mV
10% < DC < 95%
TC(Vset)
Regulation Voltage Temperature Coefficient (TC)
mV/°C
-13
-11
-9
VTign
0.9
1.25
1.6
Vign > VTign, Vrem = Vph = Vset, TA = 25°C
IQ1(on)
–
6.5
8.0
Vign > VTign, Vrem = Vph = Vset, -40°C ≤ TA ≤ 125°C
IQ2(on)
–
6.5
8.4
Vign < VTign, Vph = 0 V, Vrem = Vbat = 12.6 V, TA = 25°C
IQ1(off)
–
0.6
1.5
Vign < VTign, Vph = 0 V, Vrem = Vbat = 12.6 V, -40°C ≤ TA ≤ 125°C
IQ2(off)
–
1.0
3.4
Remote Loss Voltage Threshold
VTrem
4.2
4.5
4.8
V
Phase Detection Threshold Voltage
VTph
3.75
4.0
4.25
V
10.9
11.35
11.6
10.35
10.95
11.55
16.15
16.65
17.15
15.8
16.4
17.0
–
-12.4
–
18.9
19.25
19.8
18.45
19.15
19.85
–
-14.3
–
18.0
18.5
18.8
17.65
18.15
18.75
–
-13.4
–
23.5
24
25
23.5
23.85
24.65
–
-17.9
–
Vrem = Vbat or Vrem < VTrem
Power Up/Down IGN Threshold Voltage
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Unit
V
mA
Operating Drain Current (Ignition ON)
mA
Standby Drain Current (Ignition OFF)
VTuv
Undervoltage Threshold Voltage
Vset = 14.8 typical
MC33099
Vset = 14.6 typical
MC33099C
VTov
Overvoltage Threshold Voltage
Vset = 14.8 typical
MC33099
Vset = 14.6 typical
MC33099C
V
V
TC(VTov)
Overvoltage Threshold Voltage TC
VTld
Load Dump Threshold Voltage
Vset = 14.8 typical
MC33099
Vset = 14.6 typical
MC33099C
V
TC(VTld)
Load Dump Threshold Voltage TC
Vset2
Secondary Regulation
Vset = 14.8 typical
MC33099
Vset = 14.6 typical
MC33099C
VTld2
Secondary Load Dump Threshold Voltage
Vset = 14.8 typical
MC33099
Vset = 14.6 typical
MC33099C
Secondary Load Dump Threshold Voltage TC
MOTOROLA ANALOG INTEGRATED CIRCUIT DEVICE DATA
mV/°C
V
TC(Vset2)
Secondary Regulation TC
mV/°C
mV/°C
V
TC(VTld2)
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mV/°C
33099
5
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STATIC ELECTRICAL CHARACTERISTICS (continued) TA = 25°C unless otherwise noted.
Characteristic
Lamp Drain Short Circuit Threshold Voltage (Note 7)
Lamp Drain Short Circuit Current
Symbol
Min
Typ
Max
Unit
VTdsc
1.8
2.25
2.85
V
Idsc
2.0
2.5
3.0
Amps
–
0.3
2.5
Vd(sat)
Lamp Drain ON Voltage
I lamp = 0.4 A
Lamp Drain-to-GATE Clamping Voltage
Vdg
–
48.48
55
V
Lamp GATE Override Resistance
Rlg
–
4.6
–
kΩ
TLim
–
185
–
°C
GATE Drive Source Current
Ipu
240
300
340
µA
GATE Drive Sink Current
Ipd
400
480
560
µA
GATE Drive GATE-to-Source Clamping Voltage
Vgs
10
12
15
V
21.5
23.4
–
1.85
2.3
2.75
–
68
–
Lamp Driver Thermal Shutdown Temperature Limit (Note 7)
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V
Minimum Charge Pump GATE Drive Voltage
Vg(min)
Vbat = Vsource = Vset
Source Short Circuit Threshold Voltage
VTssc
Remote Input Resistance
Rrem
Vrem = Vset
Phase Input Resistance
LRC Input Current
Vlrc = 0 V
kΩ
–
60
–
Iign
µA
40
Vign = 1.25 V
V
kΩ
Rph
Vph = Vset
IGN Input Pull-Down Current
V
73
90
Ilrc
µA
35
45
55
Notes
7. Not 100% tested.
33099
6
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DYNAMIC ELECTRICAL CHARACTERISTICS TA = 25°C unless otherwise noted.
Characteristic
Symbol
Typ
Max
300
375
440
f dc
Duty Cycle Regulation Output Frequency
Unit
Hz
f osc /256
Phase Rotation Detection Frequency
f1
44.28
49
53.8
Hz
Low/High RPM Transition Phase Frequency
f2
267.5
296
325
Hz
DC start
GATE Duty Cycle at Startup and WOT
%
30
f ph > f2
31.25
34.5
DC (LRC)min
Minimum GATE LRC Duty Cycle
%
29
f ph < f2
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Min
31.25
33.5
DC min
Minimum GATE Duty Cycle
%
2.1
Vbat > Vreg(max)
3.1
3.3
%/s
LRC Increasing GATE Duty Cycle Rate
Low RPM Mode (f ph < f2)
LRC1 at GND, LRC2 at GND
R lrc1
–
9.31
–
LRC1 Open, LRC2 at GND
R lrc2
–
12.45
–
LRC1 at GND, LRC2 Open
R lrc3
–
18.71
–
R lrc4
–
37.42
–
R lrc(max)
–
616
–
t id(off)
–
10.2
–
ms
Lamp Short Circuit ON Polling Frequency
f lsc
–
98.6
–
Hz
Lamp Short Circuit ON Duty Cycle
DC l
–
1.56
–
%
Lamp OFF Polling Frequency
f l(off)
–
98.6
–
Hz
Lamp Polling OFF Duty Cycle
DC l(off)
–
1.56
–
%
Field Short Circuit ON Polling Frequency
f fsc
–
98.6
–
Hz
Field Short Circuit Polling ON Duty Cycle
DC f
–
1.56
–
%
LRC1 Open, LRC2 Open
High RPM Mode (f ph > f2)
Ignition Turn OFF Delay (Lamp ON)
MOTOROLA ANALOG INTEGRATED CIRCUIT DEVICE DATA
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33099
7
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SYSTEM/APPLICATION INFORMATION
INTRODUCTION
The 33099 provides a regulated voltage feedback system to
activate the alternator field current in response to system load
current. The output voltage is monitored by an internal voltage
divider scheme and compared to an internal voltage ramp
referenced to a bandgap voltage. The 33099 regulates the
system voltage to 14.8 V for the DW suffix and to 14.6 V for the
CDW suffix by generating a pulse width modulation (PWM)
voltage waveform at the GATE of an external MOSFET to
provide an average alternator field coil current as a function of
the internal voltage comparison.
Freescale Semiconductor, Inc...
The 33099 is specifically designed for regulation of an
automotive system voltage using diode-rectified alternator
charging systems commonly found in automotive applications.
The 33099 provides either an analog or digital duty cycle control
of an ON/OFF ratio of an alternator field current at a fixed
frequency. This provides for a Load Response Control (LRC) of
the alternator field current at low engine RPM to eliminate
engine speed hunting and vibration owing to abrupt torque
loading of the engine when a sudden electrical load is applied
to the system. Four LRC rates are selectable using a
combination of terminals 7 and 8 being connected to ground.
33099
8
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APPLICATIONS
Introduction
rotating field winding. The system shown in Figure 2 includes
an alternator with its associated field coil, stator coils and
rectifiers, an automotive battery, a fault indicator lamp, an
ignition switch, a field flyback diode, and the 33099.
The 33099 is an alternator voltage regulator designed with
internal level shifting resistors to control the voltage in a 12 V
automotive system that uses a three-phase alternator with a
33099
Vrem
Remote
MC33099
CB1
Vrs
VDD
Regulator
0.6 V
S1
R1
Cf
Cuv UV
CB2
Over
Voltage
Detect
S2
Vhvl
Cph
F1
To
Logic
OV
4 LSB
P16
u/d
Z1
SOURCE
Source
1.25V
IGN
VTigm
A
N
D
3
OR2
A
N
D
2
Lamp
Polling
LAMP
DRAIN
Ignition
Cds
Lamp
Drain
Z2
Lamp
Driver
Circuit
500
Lamp
Gate
Thermal
Limit
LCR1 LCR2
LRC2
LCR1
Battery
Rs
Stator
Gnd
AGnd
AGND
LAMP
GATE
Dtl
Current
Limit
Np
Boundry for IC
Batt
VTdsc
Iign
MR850
Up/Down
Control
Switch
MUX
U/D
Counter
LCR Test
LCR TEST
Alternate S tator
Configuration
Cign
Field
l
VTssc pd
IGN
A
N
D
1
Figure .
fmsb
u/d
P 256
Gate
GATE
Ign
Delay
Cdc
Digital
Duty Cycle
Generator
4MSB
S3
Batt
Css
Drain
Polling
8-Bit Counter
A/D
Comparator
& Tracking
OR1
F2
1.25 V
Osc
Vdac
DAC
A
N
D
4
Gate
Polling
LD
R3
PHASE
Phase
Filter
FILTER
lpu
(5.0 V)
Min Duty
Cycle
1.25 V
Vg
VDD
Vref
(OTC)
1.25 V (2.0 V)
R5
R2
Phase
PHASE
R4
fmsb
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V
Local ls
Sense
Bandgap
Reference
Vfb
Charge
Pump
Regulator
Internal
V reg
and Bias
Current
MTB36N06E
Low
Pass
LB
Local
FB
RF
Vo
Crs
Vl
CF
VBat
Batt
BAT
REMOTE
GND
Ground
Remote
Phase
Figure 2. 33099 Simplified Application
The 12 V system voltage (Vbat) is connected to a REMOTE
input by a remote wire, which provides the IC regulator with an
external Kelvin connection directly to the battery to provide
REMOTE voltage, Vrem. The system voltage at the BAT
terminal is also sensed by an internal Local IC connection as
Local voltage Vl. The Local connection is provided in the event
the remote wire or remote connection becomes faulty such as
being resistive, an open, or shorted to ground.
The PHASE input is normally connected to a tap on one
corner of the alternator's stator winding, which provides an AC
phase voltage (Vph) for the IC to determine the rotational
frequency (fph) of the alternator rotor. Two frequency
comparators (F1 and F2) monitor voltage Vph to determine a
phase rotation detection frequency (f1) and a Low/High RPM
transition phase frequency (f2), respectively. A PHASE FILTER
MOTOROLA ANALOG INTEGRATED CIRCUIT DEVICE DATA
terminal is provided for externally providing a filter capacitance
for filtering phase input noise.
The regulated DC system set voltage (Vset) is achieved by
employing feedback to compare a ratioed value of Vset to an
internal IC bandgap voltage reference having a negative
temperature coefficient (TC). The GATE drive of an external
N-channel MOSFET is regulated by the IC to control the field
current in the alternator field coil as an alternating ON or OFF
state dependent on load current conditions affecting voltage
Vset. The external MOSFET receives GATE-to-source voltage
drive from between the GATE and SOURCE output terminals of
the IC. The GATE-to-source voltage is a Pulse Width
Modulated (PWM) waveform having a variable ON/OFF duty
cycle ratio that is determined by an analog or a digital duty cycle
control circuitry that responds to variations in the system
voltage due to variations in system load current. The PWM
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33099
9
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waveform has a duty cycle regulation output frequency of about
395 Hz (fdc) defined by an 8-bit division of an internal 101 kHz
oscillator clock frequency (fosc). The GATE voltage at the GATE
terminal is due to a charge pump GATE voltage (Vg) generated
by voltage multiplication using an internal charge pump voltage
regulator. The high GATE-to-source voltage applied to the
external MOSFET during the ON cycle of the PWM waveform
minimizes a low drain-to-source ON resistance (RDS(ON) ) and
associated drain-to-source voltage Vd(SAT) to maximize the field
current while minimizing the associated power dissipation in the
MOSFET.
A unique feature of the 33099 is the combinational use of
analog and digital duty cycle controllers to provide a Load
Response Control (LRC) duty cycle function when rotor
frequency fph is less than frequency f2. A classic analog duty
cycle function is provided at the GATE output when frequency
fph is greater than frequency f2. During the LRC mode when f1
< fph < f2, a sudden decrease in the system voltage due to a
sudden increase in system load current will cause the analog
duty cycle to rapidly increase to as great as 100%. However,
the LRC circuitry causes the digital duty cycle to increase to
100% at a controlled predetermined LRC rate and overrides the
analog duty cycle. Thus the alternator response time is
decreased in the LRC mode and prevents the alternator from
placing a sudden high torque load on the automobile engine
during this slow RPM mode. This can occur when a high current
accessory is switched on to the 12 V system, producing a
sudden drop in system voltage. When frequency fph is greater
than frequency f2, the slow LRC response is not in effect and
the analog duty cycle controller controls the PWM voltage
waveform applied to the external MOSFET to regulate the
system voltage. By selectively coupling the LRC1 and LRC2
terminals to ground or leaving them open, the user can program
four different LRC rates (Rlrc1-Rlrc4) from 9.37%/sec to 37.4%/
sec. During an initial ignition ON and engine start-up, the LRC
rate is also in effect to minimize alternator torque loading on the
engine during start, even when a Wide Open Throttle (WOT)
condition (fph > f2) occurs.
An internal N-Channel MOSFET is provided on the IC to
directly drive lamp current as a fault indicator. The fault lamp is
connected between the low side of the ignition switch and the
LAMP DRAIN terminal of the IC. A fault is indicated during an
undervoltage battery condition when frequency fph is greater
than frequency f2, during an overvoltage battery condition, and
when frequency fph is less than frequency f1. Frequency fph < f1
when an insufficient alternator output voltage results or a slow
or non-rotating rotor occurs due to a slipping or broken belt. An
external LAMP GATE terminal is also provided for the internal
lamp driver to allow the user to override the internal IC fault logic
and externally drive the internal lamp drive MOSFET.
When a loose wire or battery terminal corrosion causes the
Remote voltage to decrease but is not a Remote Open
condition, the system voltage will increase, causing an
overvoltage Lamp fault indication, and is regulated at a
secondary value of about 18.5 V.
33099
10
During a system load dump condition, load dump protection
circuitry prevents GATE-to-source drive to the external
MOSFET and to the internal lamp drive MOSFET. This ensures
that neither the field current nor the lamp current is activated
during load dump conditions. A drain-to-GATE voltage clamp is
also provided for the internal lamp driver for further protection of
this driver during load dump.
An ignition terminal (IGN) is provided to activate the regulator
from the standby mode into a normal operating mode when the
ignition switch is ON and an ignition voltage (Vign) is greater
than a power up/down ignition threshold voltage (VTign). When
the ignition switch is OFF, voltage Vign is less than voltage
VTign, and the regulator is switched into a low current standby
mode, when frequency fph < f1. The IGN terminal can either be
coupled to the low side of the ignition switch or to the low side
of the lamp. When the IGN terminal is connected to the low side
of the lamp, the lamp must be shunted by a resistor to ensure
that ignition ON is sensed, even with an OPEN lamp fault
condition. When the lamp in ON, lamp current is polled OFF
periodically at an ignition polling frequency in order for the IGN
terminal to periodically sense that the ignition voltage is high
even though the lamp is ON. An ignition input pull-down current
(Iign) is provided to pull voltage Vign to ground when the IGN
terminal is OPEN or terminated on a high resistance.
Two ground terminals are provided by the 33099 to separate
sensitive analog circuit ground (AGND) from noisy digital and
high-current ground (GND).
Alternator Regulator Biasing and Power Up/Down
The biasing of the regulator is derived from the BAT terminal
voltage Vbat. In the normal operating mode when the ignition
switch is ON and voltage Vign is greater than VTign (about
1.25 V), a 5.0 V VDD voltage regulator biases the IC logic and
provides bias to a bandgap shunt voltage regulator. The
bandgap regulator maintains a reference voltage (Vref) of
approximately 2.0 V with an internal negative temperature
coefficient (-TC) as well as a 1.25 V Zero Temperature
Coefficient (OTC) reference voltage. Additional bias currents
and reference voltages, including a charge pump GATE voltage
Vg, are also generated from voltage Vbat. The typically ignition
ON drain current (IQ1(on) ) is about 6.5 mA at 25°C. When the
ignition switch is OFF and voltage Vign is less than VTign, the
regulator is in a low current standby mode, having a standby
drain current of about 0.7 mA (IQ1(off) ) at 25°C. During the
sleep mode, some internal voltage regulators and bias currents
are either terminated or minimized. However, the VDD regulator
and the bandgap voltage regulator continue to maintain
voltages VDD for the logic, the 2.0 V Vref, and the 1.25 V
reference voltage. In addition, all logic is reset in the standby
mode.
After switching the ignition switch to the ON position, voltage
Vign will exceed voltage VTign, causing comparator Cign to
switch states, providing an ignition-ON signal to the Ignition
Delay circuit. After an Ignition start Delay Time of 500 ms, the
Ignition Delay circuit activates additional current for the VDD
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regulator and activates all other voltage regulators and bias
currents. After engine start, the LRC mode is activated,
independent of the phase frequency or independent of a Wide
Open Throttle condition. When the battery system voltage
increases to Vset, the regulator resumes the normal operational
mode. After switching the ignition switch to the OFF position,
voltage Vign decreases below voltage VTign, causing the
comparator Cign to provide an ignition-OFF signal to the Ignition
Delay Circuit. After phase frequency fph < f1 due to ignition turn
OFF, supply currents and voltages are reduced in the regulator
to provide the standby drain current drain. However, voltage
VDD for logic and voltage Vref for reference voltages remain
active to be able to sense an ignition input voltage.
buffered and coupled to the output of a unity-gain Local Buffer
(LB) and ratioed by the R5/(R4+R5) resistor divider to provide
an input voltage to a unity-gain combiner/buffer CB2. Thus the
voltage at the input of the combiner CB2 is normally 0.8 Vls (or
1.6 V typically), while voltage Vrs on the input of CB1 is typically
2.0 V. Because voltage Vo reflects the highest voltage at the
input of either combiner, voltage Vo will be voltage Vrs in
Remote operation with Remote connected to Vbat. For this
case, voltage Vrs is filtered by a 300 Hz low-pass filter and
translated to the FB buffer output. Voltage Vrs at the FB buffer
output is then compared to a digital-to-analog converter output
voltage ramp (Vdac) for duty cycle regulation.
In some applications, the ignition input is connected to the
low side of the fault lamp as shown in Figure 2, page 9. When
the lamp driver circuitry is generating a lamp ON signal, a lamp
polling signal causes the Lamp Drain output to be periodically
GATED OFF. As a result, voltage Vign > VTign during the lamp
OFF polling period, causing comparator Cign to periodically
provides an ignition-ON signal to the Ignition Delay Circuit.
During the Lamp On condition, the Ignition Delay Circuit
provides a minimum ignition turn-off delay (tid(off)) such that all
currents and regulator voltages remain ON between the Lamp
Off polling pulses.
During a Remote fault condition when the remote sense line
is OPEN or grounded, voltage Vrs at the Remote Sense input
will be zero, causing comparator Crs to activate switches S1
and S2 to a CLOSED position. As a result, voltage Vls is
coupled through buffer LB directly to the input of combiner CB2.
Because the voltage Vls on the input of combiner CB2 is greater
than voltage Vrs (= 0 V) on the input of combiner CB1, voltage
Vls is coupled to the output of the combiners as voltage Vo.
Thus in this fault case, voltage Vls is filtered and translated to
the FB buffer output for being compared to voltage ramp Vdac
for regulation.
Battery and Alternator Output Voltage Sensing
During a remote fault condition in which the resistance of the
Remote sense wire increases due to the corrosion or a loose
connection, a finite external remote fault resistance occurs
causing voltage Vrem to decrease, but voltage Vrem remains
greater than voltage VTrem. As a result, switches S1 and S2
remain in an OPEN condition, while the system voltage will
increase due to the effective increase in the Remote resistor
divider ratio. As a result, voltage Vl increases until the voltage
at the input of combiner CB2 is approximately 2.0 V, or Vls is
about 1.2 (2.0 V), or 2.25 V due to the R4 /R5 divider ratio.
Because the local divider ratio translates voltage Vls to Vbat by
about factor 7.4, the final regulated output voltage for this
condition is 7.4 (2.25), or 18.5 V. This is the secondary
regulation voltage (Vset2). When the system voltage increases
to the Overvoltage Threshold (VTov), a fault indication occurs
by the lamp. Thus this particular Remote fault condition
produces a fault indication, but regulates to prevent an extreme
system overvoltage condition. When the Remote fault
resistance becomes great enough to cause voltage
Vrem < VTrem, the regulated system voltage returns to the local
regulation as described for an OPEN or grounded Remote
input.
The system battery voltage is directly sensed by the
REMOTE input using a remote wire as a Kelvin connection. The
Remote input resistance (Rrem) at the REMOTE input is
typically 68 kΩ. The voltage at the Remote Sense input (Vrs) is
a ratioed value of the Remote voltage (Vrem). The intended
ratio of Vrem /Vrs is about 7.45. The BAT terminal voltage (Vbat)
is also sensed as an internal Local voltage (Vl). A Local Sense
voltage (Vls) is a ratioed value of voltage Vl, where the intended
ratio of Vl /Vls is also 7.45. The Local internal connection is
provided for fault protection against the remote wire being
grounded or exhibiting a high remote wire resistance due to
being disconnected or due to a corrosive or loose connection.
Thus the Local connection ensures that alternator regulation of
the system voltage continues in well-defined states for all
possible Remote input fault conditions.
Local and Remote Voltage Processing and Switching
During Remote operation both the external Remote input
connection and internal Local connection senses approximately
the same regulated system voltage of Vset = 14.8 V. For this
case, voltages Vrs and Vls are approximately 2.0 V. Because
the remote switching comparator Crs is referenced to 0.6 V,
both switches S1 and S2 are OPEN and remain open when
voltage Vrs > 0.6 V or when voltage Vrem is greater than the
remote loss threshold voltage (VTrem). Voltage Vrs is coupled
to the input of a unity-gain combiner/buffer CB1. Voltage Vls is
MOTOROLA ANALOG INTEGRATED CIRCUIT DEVICE DATA
Internal Clock Oscillator and 8-Bit Counter
An internal clock oscillator is provided having a typical
oscillation frequency (fosc) of 101 kHz. The output of the
oscillator is coupled to an 8-bit counter that provides 8 counting
bits to the logic and the four most significant counting bits
(MSB) to the LRC circuitry and to a digital-to-analog converter
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(DAC) waveform generator. The output MSB frequency (fmsb)
of the 8-bit divider is about 395 Hz (fmsb = fosc /256), which
determines the PWM frequency at the GATE output. An
external LRC TEST terminal is provided for accelerating
internal testing of the LRC function and logic. Under normal
operation, the LRC TEST terminal is grounded by an internal
10 kΩ resistance to ground. Under accelerated test conditions,
the LRC TEST voltage is 5.0 V, and a fourth bit (fosc /16) from
the 8-bit divider is used to determine the PWM GATE
frequency. Thus, the rates are accelerated by a factor of 16.
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Low-Pass Filter, DAC, and Analog Duty Cycle
Regulator Comparator
The output voltage Vo of combiners CB1 and CB2 is coupled
to an input of a 300 Hz low-pass filter (Rf, Cf) to remove highfrequency components of system noise at Vbat and thus
associated with voltages Vls, or Vrs. The output of the low-pass
filter is coupled to a unity-gain buffer FB that provides a filter
buffer FB output.
The 4 MSBs of the 8-bit counter causes the DAC to generate
a 4-bit 395 Hz voltage waveform having 16 descending
1.75 mV steps, ramping from Vref to [Vref - 28 mV], where Vref
is the 2.0 V reference voltage.
An analog duty cycle comparator (Cdc) compares the DAC
output voltage waveform to the voltage at the FB output (Vfb).
When voltage Vfb is less then voltage [Vref - 28 mV],
comparator Cdc outputs a logic [1], for a 100% duty cycle.
When voltage Vfb is greater than Vref, comparator Cdc outputs
a logic [0] for a 0% duty cycle. When (Vref - 28 mV) < Vfb < Vref,
comparator Cdc outputs a duty cycle defined by the High/Low
output voltage ratio for each period (about 2.54 ms) of the DAC
output voltage waveform.
Basic System Voltage Regulation
From a system voltage regulation viewpoint, the voltages
Vrem and Vl from the Remote or Local connections,
respectively, are scaled to the Remote Sense and Local Sense
inputs as voltages Vrs and Vls respectively and transferred to
the FB output as voltage Vfb. Voltage Vfb is compared to the
DAC output voltage waveform to generate the ON and OFF
time of the analog duty cycle waveform. When voltage Vfb is
less than Vref - 28 mV, the output of comparator Cdc is in a high
state. This high state propagates through an AND3 GATE, an
OR1 GATE, and an AND4 GATE to activate switch S3,
generating a fully ON or High GATE drive voltage. When
voltage Vfb is greater than Vref, the output of comparator Cdc is
in a low state. This low state propagates through the AND3
GATE, the OR1 GATE, and the AND4 GATE to activate switch
S3 to generate a fully OFF or low GATE drive voltage.
Assuming voltage Vref is 2.0 V and Vfb = Vrs, and the local or
remote input resistive scale factor is 7.45, the external
MOSFET provides a fully ON field current when the system
voltage is less than 7.45 (Vref - 28 mV), or 14.6 V. The field
33099
12
current is also fully OFF when the system voltage is greater
than 7.45 (Vref), or 14.9 V. When voltage Vfb is less than any
portion of the DAC waveform voltage, comparator Cdc output is
high to produce an ON field current. When voltage Vfb is greater
than any portion of the DAC waveform voltage, comparator Cdc
output is low to produce an OFF field current. Thus the system
feedback will regulate the PWM duty cycle of the field current
from 0% to 100% over about a 210 mV system regulation
voltage range (dVreg). The system voltage is centered at
14.8 V, where a 50% duty cycle field current results for an
average system load current, and the duty cycle regulation
frequency is (fosc /256), or 395 Hz. Since voltage Vref has a
negative TC, voltage Vset will also have a regulation voltage
temperature coefficient (TCVreg) of about -11 mV/°C.
Input Phase and Frequency Switch Response
The phase voltage Vph results from the alternator's stator AC
output voltage being applied to the PHASE input terminal.
A phase detection threshold voltage (VTph) is approximately
4.0 V due to the 1.25 V phase reference voltage for the phase
comparator (Cph) and the 3.22 voltage ratio associated with the
phase input resistor divider. The phase input resistance (Rph) is
typically 60 kΩ. A PHASE FILTER terminal is coupled to the
input of Comparator Cph, providing for an external phase filter
capacitance when filtering of high frequency phase noise is
desired. A typical value of .003 µF to AGND provides for an
input phase 3.0 db roll-off frequency of about 10 kHz.
Comparator Cph also provides about 480 mV of hysteresis at
the PHASE input terminal. Comparator Cph further provides a
phase signal binary output voltage having a phase frequency of
fph and is applied to digital frequency switches F1 and F2.
Switch F1 outputs a logic [1] when frequency fph is less then
phase detection frequency f1. Frequency f1 is equal to
frequency fmsb /8, or 49.3 Hz for a 101 kHz oscillator frequency.
Switch F2 outputs a logic [1] when the frequency fph is greater
then the low/high transition frequency f2. Frequency f2 is equal
to frequency 3fmsb /4, or 296 Hz for a 101 kHz oscillator
frequency. These frequency switches are used to define the
Load Response Control region of operation, an undervoltage at
a high RPM fault condition, and a low RPM fault condition due
to a broken or loose belt.
Load Response Control (LRC)
The LRC circuit consists of a digital duty cycle generator, an
analog/digital (A/D) duty cycle comparator and tracking circuit,
an up/down control switch, an up/down (U/D) counter, a
programmable divider (Np), and a multiplexer (MUX). During
normal operation, the LRC circuit becomes active and
generates digital duty cycle control of the GATE drive when
frequency fph is less than frequency f2 (f1 < fph < f2). The slow
LRC response becomes inactive and the analog duty cycle
controls the GATE drive when frequency fph is greater than
frequency f2 (f1 < fph < f2). During initial ignition and initial
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engine start, the LRC response is in effect, independent of
frequency fph, until system voltage is regulating at voltage Vset.
terminations. For a down state on the u/d line, the digital duty
cycle will count down at a rate of about 10 ms/step change.
The digital duty cycle generator receives the 4 MSBs from
the 8-bit counter as input and generates 11 discrete digital duty
cycles on 11 output lines. The frequency of each duty cycle
waveform is about 395 Hz (fmsb), which results from the MSB
of the 8-bit division of the 101 kHz OSC clock frequency. The
minimum duty cycle on the first output line is 31.25% and the
maximum duty cycle on the eleventh output line is 93.75%. The
duty cycle difference between each incremental duty cycle is
6.25%. All 11 duty cycle generator output lines are coupled as
data inputs to the MUX.
The A/D duty cycle comparator and tracking circuit receives
the analog duty cycle from comparator Cdc and the digital duty
cycle from the MUX output. The A/D duty cycle comparator
provides a high, or up (u), output when the analog duty cycle is
greater than the digital duty cycle, and a low, or down (d), output
when the analog duty cycle is less than the digital duty cycle.
Normally the programmable divider Np divides frequency
fmsb by a counter divide ratio N and applies the fmsb /N
frequency as input to the U/D counter. Divide ratio N can be preselected by the user for four different divide ratios by switching
a combination of the LRC1 and LRC2 normally open terminals
to ground. An LRC input current (Ilrc) from each LRC terminal to
ground is about 45 µA. The phase frequency fph and an up/
down (u/d) state on a u/d line from the up/down control switch
determines ratio N. In the LRC mode when fph < f2, a high, or
up, state on the u/d line causes divider Np to output a frequency
of fmsb /N, or 395 Hz/N. The LRC1 and LRC2 terminal
combinations produce N divide ratios of 66, 132, 198, and 264.
When the u/d line is in the down, or low, state, divider Np
provides a divide ratio of fmsb /4, or 395 Hz/4. When fph > f2, the
output frequency of divider Np is always fmsb /4 = 395 Hz/4,
independent of the state of the u/d input line.
The u/d line from the up/down control switch determines the
direction of the count as well as the divide ratio N. For an up
state on the u/d line, the output of the 4-bit U/D counter
increments up at a rate of 5.98 Hz (count change every 167 ms)
for N=66, 2.99 Hz (count change every 334 ms) for N=132,
1.99 Hz (count change every 502 ms) for N = 198, or 1.496 Hz
(count change every 671 ms) for N = 264. For a down state on
the u/d line, the output of the 4-bit U/D counter decrements at a
rate of about 99 Hz (count decrement about every 10 ms). The
4-bit output lines of the up/down counter are coupled as control
inputs of the MUX.
The MUX couples one of the 11 digital duty cycle input lines
to the MUX output dependent upon the 4-bit control inputs from
the U/D counter. When the MUX control input count is 0, the first
31.25% digital duty cycle is selected and provided at the MUX
output. When the control input count is 10, the eleventh 93.75%
digital duty cycle is selected at output of the MUX. A MUX
control input of 11 produces a 100% duty cycle at the MUX
output. Thus each of the MUX input lines is selected and
provided at the MUX output and incremented to the next line at
a rate dependent on the rate the MUX control inputs increment.
For an up state on the u/d line, the digital duty cycle at the
output of the MUX will increment from 31.24% to 100% in
11 steps at a rate from 167 ms/step (or a fourth LRC rate (Rlrc4)
of 37.42%/sec) to 671 ms/step (or a first LRC rate (Rlrc1) of
9.31%/sec) dependent on the LRC1 and LRC2 terminal
MOTOROLA ANALOG INTEGRATED CIRCUIT DEVICE DATA
In the LRC mode when frequency f1 < fph < f2, the up/down
control switch enables the u/d output of the A/D duty cycle
comparator to be coupled to the u/d line. In the steady state, the
A/D duty cycle comparator will provide an u/d input to the U/D
counter and Np divider to increase or decrease the digital duty
cycle to track the analog duty cycle. If the analog duty cycle
increases to a value greater than the digital duty cycle at a rate
that is greater than the selected LRC digital duty cycle rate, the
A/D duty cycle comparator will output an up signal on the
u/d line to cause the digital duty cycle to increase to the analog
duty cycle at the selected LRC digital duty cycle rate. If the
analog duty cycle decreases to a value less than the digital duty
cycle, the A/D duty cycle comparator will output a down signal
on the u/d line to cause the digital duty cycle to decrease to the
analog duty cycle at a fixed rate of about 10 ms/step. For an
analog duty cycle less than 31.25%, the down count at the
output of the U/D counter will remain at 0 and the digital duty
cycle will remain at 31.25%.
If frequency fph is less than frequency f1 (fph < f1), then the
up/down control switch will provide a down signal on the u/d line
independent of the duty cycle comparator u/d output. The
resulting down count of 0 to the MUX control input for fph < f1
will cause the digital duty cycle to be constant at 31.25% and
provides a divide ratio of fmsb /4 as the input frequency to the
U/D counter.
When approximately 5.0 V is applied to the LRC TEST
terminal, divider Np utilizes the fosc /16 frequency as input to the
divider instead of the normal fosc /256 frequency. As a result,
the LRC function is accelerated by a factor of 16, which allows
the testing of all LRC associated rates to be accelerated by a
factor of 16. During normal LRC operation, the LRC terminal is
in a low ground state, having an internal 10 kΩ pull-down
resistor.
The duty cycle output of the AND3 GATE reflects the
minimum duty cycle at the AND3 GATE inputs. Thus when the
analog duty cycle exceeds the digital duty cycle, the digital duty
cycle becomes the controlling duty cycle at the AND3 GATE
output. When the analog duty cycle is less than the digital duty
cycle, the analog duty cycle becomes the controlling duty cycle
at the AND3 GATE output. Thus in the LRC mode when
f1 < fph < f2, an increasing step response in the analog duty
cycle from 0% to 100% will cause the duty cycle at the output of
the AND3 GATE to increase rapidly from 0% to 31.25% and
then increase slowly at the LRC rate from 31.25% to 100%. If
the analog duty cycle provides a step increase from a duty cycle
greater than 31.25%, then the resulting LRC duty cycle
increase from the initial analog duty cycle at the output of the
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AND3 GATE. For a decreasing step response in the analog
duty cycle, the output of the AND3 GATE will rapidly follow the
decreasing analog duty cycle. The output of the AND3 GATE
drives the GATE output (and the field current) through an OR1
GATE, an AND4 GATE, and switch S3. Thus the minimum
GATE LRC duty cycle (DC(LRC)min ) is 31.25%.
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A 0% analog duty cycle will produce a 0% duty cycle at the
output of the AND3 GATE. However, the output of the AND3
GATE is ORed with a 3.1% minimum duty cycle signal from the
minimum duty cycle generation at the OR1 GATE input to
provide a minimum 3.1% duty cycle to the AND4 GATE input.
This provides the resulting minimum GATE duty cycle (DCmin)
of 3.1% at the GATE output, even though the analog duty cycle
is 0%.
When the phase frequency is greater than frequency
f2 (fph > f2), the N divide factor is reduced to 4. As a result, the
LRC circuitry still functions as previously described, but the rate
of digital duty cycle increase or decrease is a maximum LRC
rate (Rlrc(max) ) of about 10 ms/step. Thus a step increase in the
analog duty cycle from 31.25% to 100% will cause about a
110 ms delay before the digital duty cycle provides a 100% duty
cycle at the output of the AND3 GATE (and GATE drive).
The conditions for LRC response also occur during an initial
engine start up period after engine cranking even when a WOT
condition occurs (fph > f2). When the ignition switch is turned
ON, comparator Cign is activated, activating all biasing into the
normal state and activating the start-up LRC mode. After engine
cranking and immediately after initial engine start up, the
system BATTERY voltage is generally low while a WOT
condition occurs. For this case, the slow LRC response is in
effect to prevent excessive torque loading on the engine by the
alternator during engine start up. The GATE duty cycle at startup with WOT (DCstart) is the minimum LRC duty cycle and will
increase at the LRC rate. Once the system voltage returns to
voltage Vset, the normal LRC response will occur as previously
described.
Field Coil Drive and Device Protection
The external MOSFET provides PWM drive current from the
system BATTERY to the field coil for system voltage regulation.
The GATE-to-Source voltage for this MOSFET is provided by
the IC's GATE-to-SOURCE terminal drive voltage. During the
ON state, the AND4 GATE activates switch S3 to couple the
GATE drive pull-up source current (Ipu) to the GATE output.
Current Ipu drives the GATE of the MOSFET to the charge
pump GATE voltage Vg (typically 23 V), causing the MOSFET
to drive the field coil terminal to near the system BATTERY
voltage. Voltage Vg has a minimum charge pump GATE voltage
(Vg(min) ) of 21.5 V. This high GATE-to-Source voltage
minimizes power dissipation in the external MOSFET by
minimizing a Drain-to-Source ON resistance (RDS(ON) ) of the
MOSFET during the ON state. This results in a typical Lamp
Drain ON voltage (Vd(sat) ) of about 0.3 V at a Lamp Drain
current of 400 mA as measured from the LAMP DRAIN terminal
to ground. During the OFF state, the AND4 GATE activates
33099
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switch S3 to couple a GATE drive pull-down sink current (Ipd) to
the GATE output. Current Ipd pulls the GATE voltage to the
Source voltage, turning OFF the MOSFET and its associated
field coil current. The limited GATE current drive of the
MOSFET GATE capacitance reduces the magnitude and
frequency of the high-frequency components associated with
the GATE duty cycle waveform, minimizing RFI. Zener diode Z1
is employed to provide a GATE-to-Source clamping voltage
(Vgs), which limits and protects the GATE-to-Source voltage of
the external MOSFET.
When the external MOSFET fails to increase the source (or
field coil terminal) voltage to within a source short circuit
threshold voltage (VTssc) of the BATTERY terminal voltage
(VTssc < [Vbat - Vsource]), a shorted-source comparator Css
outputs a short circuit signal to a GATE polling circuit. A shorted
field coil to ground is an example of this fault condition. This
GATE polling circuit provides short GATE polling pulses to the
AND4 GATE to allow the IC to test for an unshorted condition
without damaging the external MOSFET. The polling duty cycle
is 1.56%, or about a 158 µs ON pulse at a frequency of fmsb /4,
or 98.6 Hz. When the source shorting condition is removed,
comparator Css provides a no-short signal to the GATE polling
circuitry, which provides a logic [1] to the AND4 GATE, which
then operates normally.
The AND4 GATE is also driven by the no load dump (LD) line
from the Overvoltage Detector circuitry. Thus during a load
dump system overvoltage condition, a logic [0] is provided to
the AND4 GATE from the Overvoltage Detector circuit and all
GATE drive is terminated.
A flyback diode MR850 is externally provided to limit the
negative source voltage on the field terminal (and the SOURCE
terminal) caused by a turn-OFF transition of the field current.
The forward current through this diode is approximately the
peak field current prior to field current turn OFF.
Fault Lamp Indicator—Drive and Protection
The fault indicator lamp is driven by an internal N-channel
MOSFET lamp driver, which controls the lamp current. The
lamp is coupled between the ignition switch and the LAMP
DRAIN terminal of the lamp driver. The Lamp GATE of the lamp
driver is driven by the lamp driver circuitry or from an external
LAMP GATE terminal. Inputs to the lamp driver circuitry are
from an output of an AND2 GATE, an output of a thermal limit
circuit, and an output of a current limit circuit. By applying an
external Lamp GATE override voltage (Vgo) to the LAMP GATE
terminal (5), the Lamp Drain current will increase, providing
lamp current independent of the lamp driver logic state. When
the lamp driver circuity is forcing the lamp driver OFF, the LAMP
GATE terminal resistance to ground will be about 4.6 kΩ. The
source of the lamp driver is coupled to ground through an
internal current sense resistor RS. When the lamp is ON, the
Lamp Drain ON voltage (Vd(sat)) is the Lamp Drain-to-ground
voltage measured at 400 mA of Lamp Drain current.
Normally, current flows through the lamp driver (and lamp),
indicating a fault when the output of the AND2 GATE is a
logic [1]. Assuming the lamp is not shorted, is not being current
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limited, is not in the thermal shut down mode, and the system is
not in a load dump mode, the lamp ON current is controlled by
the output of the OR2 GATE. The output of the OR2 GATE is a
logic [1] and the lamp will normally be ON when the UV
(undervoltage) line and the F2 output line are both a logic [1]
state, indicating an undervoltage condition when frequency
fph > f2. The output of the OR2 GATE is also a logic [1] when
the output of the OV (overvoltage) line is a logic [1], indicating
an overvoltage condition, or the output of the F1 line is also a
logic [1], indicating a loss of phase signal (fph < f1) due to a
broken phase wire, broken or slipping belt, or otherwise failed
alternator or open field circuit.
When the lamp current exceeds a lamp drain short circuit
current (Idsc), the voltage across resistor Rs will exceed a
current limit threshold voltage associated with the current limit
circuitry. As a result, a signal is sent to the lamp driver circuitry
to limit the lamp drive and regulates the lamp current to current
Idsc. When the power dissipation of the lamp driver causes the
temperature of the lamp driver to exceed a thermal shut-down
temperature limit (TLim), a temperature sensing diode (Dtl)
causes the thermal limit circuitry to send a signal to the lamp
driver circuitry to limit the lamp drive current and reduce the
power dissipation and resulting device temperature. When the
lamp driver is ON, but the Lamp Drain terminal voltage is not
below the BAT terminal voltage Vbat by at least a lamp drain
short circuit threshold voltage (VTdsc) or ([Vbat - Vdrain] <
VTdsc), comparator Cds will output a lamp short circuit signal to
the Drain Polling circuit to indicate a lamp shorted condition.
The Drain Polling circuit provides a low duty cycle polling output
to the input of the AND2 GATE to poll the lamp driver ON,
continuously testing for a lamp short without damaging the lamp
driver. The polling duty cycle is 1.56%, (or about a 158 µs ON
pulse) at a frequency of fmsb /4, or 98.6 Hz. After the lamp short
has been removed, the comparator Cds outputs a lamp notshorted signal to the Drain Polling circuitry, which provides a
logic [1] to the AND2 GATE, which then operates normally.
Lamp polling is also present when the lamp is ON. In this
case, lamp polling turns OFF the lamp for a short period of time
with the lamp being ON for the remainder of the time. In this
case the lamp ON duty cycle is 98.44% (or OFF for 158 µs) at
a frequency of fmsb /4, or 98.6 Hz. This causes the lamp voltage
on the lamp drain terminal to be greater than ignition threshold
voltage VTign for at least 158 µs of a 10.1 ms period. During the
lamp ON mode, the Ignition Turn Off Delay of the Ignition Delay
circuit is greater then the 10.1 ms period. As a result, the
regulator biasing remains ON even when the IGN terminal is
coupled to the LAMP DRAIN terminal and the lamp drain
voltage is less than voltage VTign most of the time when the
lamp is ON.
Undervoltage, Overvoltage, and Load Dump
Protection
An undervoltage, overvoltage and load dump condition is
sensed by the regulator to generate fault indications and to
protect the regulator and associated external devices. As
previously discussed, a load dump signal during load dump will
prevent GATE drive to the external MOSFET and prevent
GATE drive to the lamp driver. Thus the external and internal
MOSFETs will turn OFF during a system load dump. As
previously discussed, the undervoltage and overvoltage signals
are also provided for fault indications.
The undervoltage signal is provided on the UV line by an
undervoltage comparator Cuv having a voltage reference of
1.25 V and a resistor divider voltage transfer of 1.26 from the
FB output to comparator Cuv input. When voltage Vfb on the FB
output becomes less than 1.52 V, the voltage at input to
comparator Cuv becomes less than 1.25 V, causing comparator
Cuv to output an undervoltage UV signal. Because voltage Vfb
is ideally voltage Vrs (or voltage Vls), and the ratio of Vr /Vrs
(or Vl /Vls) is 7.45, the UV signal will occur when the system
voltage at the Remote input (or Local input) is less than an
undervoltage threshold voltage (VTuv), or 11.35 V. However,
GATE AND1 ensures that frequency fph must be greater than f2
before an undervoltage Fault is indicated by the lamp.
The load dump and overvoltage detection also utilizes similar
resistor dividers and voltage comparators in an Overvoltage
Detect circuitry where all comparators are referenced to voltage
Vref, or about 2.0 V. When voltage Vfb on the FB output is
greater than 2.58 V, or 1.29 Vref (Vfb /Vref = 1.29), an output
load dump signal of a logic [0] is generated on the LD line. Thus
during load dump, voltage Vrs (or Vlocal) will be about 2.58 V,
and the actual load dump threshold voltage (VTld) will be about
19.25 V, or 1.3 Vset. When voltage Vfb on the FB output is
greater than 1.117 Vref (Vfb /Vref = 1.117), an output
overvoltage signal is generated on the OV line. Thus voltage
Vrs (or Vl) will be about 2.235 V, and the actual overvoltage
threshold voltage (VTov) will be about 16.65 V, or 1.125 Vset.
The regulator also indicates an overvoltage condition on the
system during the Remote fault condition when the remote wire
resistance increases to a finite value and the system voltage is
being regulated by secondary regulation at Vset2. When a load
dump occurs during secondary regulation, the load dump
threshold increases to 1.3 Vset2, or about 24 V.
The lamp driver is also protected from load dump, since
during load dump, the LD signal is a logic [0], preventing the
AND2 GATE from activating the lamp driver. In addition, a
drain-to-GATE clamp device Z2 limits the drain-to-GATE
clamping voltage (Vdg) to about 40 V typically.
MOTOROLA ANALOG INTEGRATED CIRCUIT DEVICE DATA
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PACKAGE DIMENSIONS
.
DW SUFFIX
16-TERMINAL SOICW
PLASTIC PACKAGE
CASE 751G-04
ISSUE D
0.25
M
B
A
10.55
8X
10.05
PIN'S
NUMBER
1
2.65
2.35
0.25
0.10
16
PIN 1 INDEX
Freescale Semiconductor, Inc...
16X
4
A
A
8
0.49
0.35 6
0.25 M T A B
14X
10.45
10.15
1.27
9
7.6
7.4
T
B
SEATING
PLANE
16X
0.1 T
5
0.75
0.25
X45°
0.32
0.23
1.0
0.4
SECTION A-A
33099
16
7°
0°
NOTES:
1. DIMENSIONS ARE IN MILLIMETERS.
2. DIMENSIONING AND TOLERANCING PER ASME
Y14.5M, 1994.
3. DATUMS A AND B TO BE DETERMINED AT THE PLANE
WHERE THE BOTTOM OF THE LEADS EXIT THE
PLASTIC BODY.
4. THIS DIMENSION DOES NOT INCLUDE MOLD FLASH,
PROTRUSION OR GATE BURRS. MOLD FLASH,
PROTRUSION OR GATE BURRS SHALL NOT EXCEED
0.15mm PER SIDE. THIS DIMENSION IS DETERMINED
AT THE PLANE WHERE THE BOTTOM OF THE LEADS
EXIT THE PLASTIC BODY.
5. THIS DIMENSION DOES NOT INCLUDE INTER-LEAD
FLASH OR PROTRUSIONS. INTER-LEAD FLASH AND
PROTRUSIONS SHALL NOT EXCEED 0.25mm PER
SIDE. THIS DIMENSION IS DETERMINED AT THE
PLANE WHERE THE BOTTOM OF THE LEADS EXIT
THE PLASTIC BODY.
6. THIS DIMENSION DOES NOT INCLUDE DAMBAR
PROTRUSION. ALLOWABLE DAMBAR PROTRUSION
SHALL NOT CAUSE THE LEAD WIDTH TO EXCEED
0.62mm.
MOTOROLA ANALOG INTEGRATED CIRCUIT DEVICE DATA
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Go to: www.freescale.com
Freescale Semiconductor, Inc.
Freescale Semiconductor, Inc...
NOTES
MOTOROLA ANALOG INTEGRATED CIRCUIT DEVICE DATA
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Freescale Semiconductor, Inc...
NOTES
33099
18
MOTOROLA ANALOG INTEGRATED CIRCUIT DEVICE DATA
For More Information On This Product,
Go to: www.freescale.com
Freescale Semiconductor, Inc.
Freescale Semiconductor, Inc...
NOTES
MOTOROLA ANALOG INTEGRATED CIRCUIT DEVICE DATA
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