FREESCALE 33988

Freescale Semiconductor
Advance Information
Document Number: MC33988
Rev. 4.0, 11/2009
Dual Intelligent High-current
Self-protected Silicon High Side
Switch (8.0mΩ)
33988
The 33988 is a dual self-protected 8.0mΩ silicon switch used to
replace electromechanical relays, fuses, and discrete devices in
power management applications. The 33988 is designed for harsh
environments, and it includes self-recovery features. The device is
suitable for loads with high inrush current, as well as motors and all
types of resistive and inductive loads.
Programming, control, and diagnostics are implemented via the
Serial Peripheral Interface (SPI). A dedicated parallel input is
available for alternate and pulse-width modulation (PWM) control of
each output. SPI-programmable fault trip thresholds allow the device
to be adjusted for optimal performance in the application.
The 33988 is packaged in a power-enhanced 12 x 12 nonleaded
PQFN package with exposed tabs.
HIGH SIDE SWITCH
BOTTOM VIEW
PNA SUFFIX
98ARL10521D
16-PIN PQFN
Features
•
•
•
•
Dual 8.0mΩ max high side switch with parallel input or SPI control
6.0V to 27V operating voltage with standby currents < 5.0μA
Output current monitoring with two SPI-selectable current ratios
SPI control of over-current limit, over-current fault blanking time,
output-OFF open load detection, output ON/OFF control,
watchdog timeout, slew rates, and fault status reporting
• SPI status reporting of overcurrent, open and shorted loads, overtemperature, under-voltage and over-voltage shutdown, fail-safe
pin status, and program status
• Enhanced -16V reverse polarity VPWR protection
VDD
VDD
VDD
ORDERING INFORMATION
Device
Temperature
Range (TA)
Package
MC33988CPNA
- 40°C to 125°C
16 PQFN
VPWR
33988
VDD
I/O
FS
I/O
WAKE
SO
SI
SCLK
MCU
GND
HS1
SCLK
CS
CS
SI
SO
I/O
RST
I/O
INO
I/O
IN1
A/D
VPWR
HS0
LOAD
LOAD
CSNS
FSI
GND
Figure 1. 33988 Simplified Application Diagram
* This document contains certain information on a new product.
Specifications and information herein are subject to change without notice.
© Freescale Semiconductor, Inc., 2009. All rights reserved.
INTERNAL BLOCK DIAGRAM
INTERNAL BLOCK DIAGRAM
VPWR
VDD
Internal
Regulator
IUP
VIC
Over-voltage
Protection
CS
Programmable
Switch Delay
0ms –525ms
SO
SPI
3.0 MHz
Selectable Slew
Rate Gate Drive
HS0
Selectable Over-current
High Detection
50A or 37.5A
SI
SCLK
FS
IN[0:1]
RST
WAKE
Logic
Selectable Overcurrent Low Detection
Blanking Time
0.15ms–155ms
Selectable Over-current
Low Detection
3.75A –12.5A
Open Load
Detection
IDWN
Over-temperature
Detection
RDWN
HS0
HS1
Programmable
Watchdog
310ms–2500ms
HS1
VIC
IUP
Selectable
Output Current
Recopy
1/10250 or 1/20500
FSI
CSNS
GND
Figure 2. 33988 Simplified Internal Block Diagram
33988
2
Analog Integrated Circuit Device Data
Freescale Semiconductor
PIN CONNECTIONS
PIN CONNECTIONS
CSNS
5
WAKE
6
IN0
FS
7
RST
CS
8
FSI
SI
SLCK
VDD
SO
IN1
12 11 10 9
4
3
2
1
13
GND
TRANSPARENT
TOP VIEW
14
VPWR
15
HS1
16
HS0
Figure 3. 33988 Pin Connections (Transparent Top View)
Table 1. Pin Definitions
Functional descriptions of many of these pins can be found in the Functional Pin Description section beginning on page 16.
Pin
Pin Name
Pin
Function
Formal Name
1
CSNS
Output
Output Current Monitoring
2
WAKE
Input
Wake
3
RST
Input
Reset (Active Low)
4
IN0
Input
Direct Input 0
5
FS
Output
Fault Status (Active Low)
This is an open drain configured output requiring an external pull-up
resistor to VDD for fault reporting.
6
FSI
Input
Fail-Safe Input
The value of the resistance connected between this pin and ground
determines the state of the outputs after a watchdog timeout occurs.
7
CS
Input
Chip Select (Active Low)
8
SCLK
Input
Serial Clock
This input pin is connected to the MCU providing the required bit shift
clock for SPI communication.
9
SI
Input
Serial Input
This is a command data input pin connected to the SPI Serial Data
Output of the MCU or to the SO pin of the previous device of a daisy
chain of devices.
10
VDD
Input
Digital Drain Voltage
(Power)
This is an external voltage input pin used to supply power to the SPI
circuit.
Definition
This pin is used to output a current proportional to the designated
HS0-1 output.
This pin is used to input a Logic [1] signal so as to enable the
watchdog timer function.
This input pin is used to initialize the device configuration and fault
registers, as well as place the device in a low-current Sleep mode.
This input pin is used to directly control the output HS0.
This input pin is connected to a chip select output of a master
microcontroller (MCU).
33988
Analog Integrated Circuit Device Data
Freescale Semiconductor
3
PIN CONNECTIONS
Table 1. Pin Definitions (continued)
Functional descriptions of many of these pins can be found in the Functional Pin Description section beginning on page 16.
Pin
Pin Name
Pin
Function
Formal Name
Definition
11
SO
Output
Serial Output
This output pin is connected to the SPI Serial Data Input pin of the
MCU or to the SI pin of the next device of a daisy chain of devices.
12
IN1
Input
Direct Input 1
This input pin is used to directly control the output HS1.
13
GND
Ground
Ground
This pin is the ground for the logic and analog circuitry of the device.
14
VPWR
Input
Positive Power Supply
This pin connects to the positive power supply and is the source input
of operational power for the device.
15
HS1
Output
High Side Output 1
Protected 8.0mΩ high side power output to the load.
16
HS0
Output
High Side Output 0
Protected 8.0mΩ high side power output to the load.
33988
4
Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
MAXIMUM RATINGS
ELECTRICAL CHARACTERISTICS
MAXIMUM RATINGS
Table 2. Maximum Ratings
All voltages are with respect to ground unless otherwise noted.
Rating
Symbol
Value
Unit
ELECTRICAL RATINGS
Operating Voltage Range
VPWR
Steady-State
VDD Supply Voltage
V
-16 to 41
VDD
-0.3 to 5.5
V
VIN[0:1], RST, FSI
- 0.3 to 7.0
V
VSO
- 0.3 to VDD + 0.3
V
WAKE Input Clamp Current
ICL(WAKE)
2.5
mA
CSNS Input Clamp Current
ICL(CSNS)
10
mA
Input/Output Voltage(1)
CSNS, SI, SCLK,
CS, FS
SO Output
Voltage(1)
Output Voltage
Positive
VHS
V
41
Negative
-15
Output Current(2)
IHS[0:1]
30
A
ECL[0:1]
0.37
J
Human Body Model (HBM)
VESD1
± 2000
Charge Device Model (CDM)
VESD3
Output Clamp
ESD Voltage
Energy(3)
(4)
Corner Pins (1, 12, 15, 16)
All Other Pins (2, 11, 13, 14)
V
±750
±500
Notes
1. Exceeding this voltage limit may cause permanent damage to the device.
2. Continuous high side output current rating so long as maximum junction temperature is not exceeded. Calculation of maximum output
current using package thermal resistance is required.
3. Active clamp energy using single-pulse method (L = 16mH, RL = 0, VPWR = 12V, TJ = 150°C).
4.
ESD1 testing is performed in accordance with the Human Body Model (HBM) (CZAP = 100pF, RZAP = 1500Ω); ESD3 testing is performed
in accordance with the Charge Device Model (CDM), Robotic (Czap=4.0pF).
33988
Analog Integrated Circuit Device Data
Freescale Semiconductor
5
ELECTRICAL CHARACTERISTICS
MAXIMUM RATINGS
Table 2. Maximum Ratings
All voltages are with respect to ground unless otherwise noted.
Rating
Symbol
Value
Ambient
TA
- 40 to 125
Junction
TJ
- 40 to 150
TSTG
- 55 to 150
RθJC
<1.0
RθJA
30
TPPRT
Note 7
Unit
THERMAL RATINGS
°C
Operating Temperature
Storage Temperature
Thermal Resistance(5)
°C/W
Junction-to-Case
Junction-to-Ambient
Peak Package Reflow Temperature During
°C
Reflow(6), (7)
°C
Notes
5. Device mounted on a 2s2p test board according to JEDEC JESD51-2.
6. Pin soldering temperature limit is for 10 seconds maximum duration. Not designed for immersion soldering. Exceeding these limits may
cause malfunction or permanent damage to the device.
7. Freescale’s Package Reflow capability meets Pb-free requirements for JEDEC standard J-STD-020C. For Peak Package Reflow
Temperature and Moisture Sensitivity Levels (MSL), Go to www.freescale.com, search by part number [e.g. remove prefixes/suffixes
and enter the core ID to view all orderable parts. (i.e. MC33xxxD enter 33xxx), and review parametrics.
33988
6
Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 3. Static Electrical Characteristics
Characteristics noted under conditions 4.5V ≤ VDD ≤ 5.5V, 6.0V ≤ VPWR ≤ 27V, -40°C ≤ TA ≤ 125°C, unless otherwise noted.
Typical values noted reflect the approximate parameter mean at TA = 25°C under nominal conditions, unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
POWER INPUT
Battery Supply Voltage Range
VPWR
Full Operational
VPWR Operating Supply Current
6.0
–
27
–
–
20
IPWR(ON)
Output ON, IHS0 and IHS1 = 0 A
VPWR Supply Current
V
mA
IPWR(SBY)
Output OFF, Open Load Detection Disabled, WAKE > 0.7 x VDD,
RST = VLOGIC HIGH
mA
–
–
5.0
TJ = 25°C
–
–
10
TJ = 85°C
–
–
50
4.5
5.0
5.5
No SPI Communication
–
–
1.0
3.0MHz SPI Communication
–
–
5.0
Sleep State Supply Current (VPWR < 14V, RST < 0.5V, WAKE < 0.5V)
μA
IPWR(SLEEP)
VDD Supply Voltage
VDD(ON)
VDD Supply Current
IDD(ON)
V
mA
VDD Sleep State Current
IDD(SLEEP)
–
–
5.0
μA
Over-voltage Shutdown Threshold
VPWR(OV)
28
32
36
V
Over-voltage Shutdown Hysteresis
VPWR(OVHYS)
0.2
0.8
1.5
V
VPWR(UV)
5.0
5.5
6.0
V
Under-voltage Hysteresis(9)
VPWR(UVHYS)
–
0.25
–
V
Under-voltage Power-ON Reset
VPWR(UVPOR)
–
–
5.0
V
Under-voltage Output Shutdown
Threshold(8)
Notes
8. This applies to all internal device logic supplied by VPWR and assumes the external VDD supply is within specification.
9.
This applies when the under-voltage fault is not latched (IN[0 : 1] = 0).
33988
Analog Integrated Circuit Device Data
Freescale Semiconductor
7
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 3. Static Electrical Characteristics (continued)
Characteristics noted under conditions 4.5V ≤ VDD ≤ 5.5V, 6.0V ≤ VPWR ≤ 27V, -40°C ≤ TA ≤ 125°C, unless otherwise noted.
Typical values noted reflect the approximate parameter mean at TA = 25°C under nominal conditions, unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
VPWR = 6.0V
–
–
12.0
VPWR = 10V
–
–
8.0
VPWR = 13V
–
–
8.0
Unit
POWER OUTPUT
Output Drain-to-Source ON Resistance (IHS[0:1] = 7.5A, TJ = 25°C)
Output Drain-to-Source ON Resistance (IHS[0:1] = 7.5A, TJ = 150°C)
RDS(ON)
mΩ
RDS(ON)
mΩ
VPWR = 6.0V
–
–
20.4
VPWR = 10V
–
–
13.6
VPWR = 13V
–
–
13.6
Output Source-to-Drain ON Resistance IHS[0:1] = 7.5A, TJ = 25°C(10)
RDS(ON)
VPWR = -12V
mΩ
–
–
16.0
Output Over-current High Detection Levels (9.0V < VPWR < 16V)
A
SOCH = 0
IOCH0
40
50
60
SOCH = 1
IOCH1
30
37.5
45
000
IOCL0
10.5
12.5
14.5
001
IOCL1
9.0
11.25
13.5
IOCL2
8.0
10.0
12.0
IOCL3
7.0
8.75
10.5
IOCL4
6.0
7.5
9.0
IOCL5
5.0
6.25
7.5
IOCL6
4.0
5.0
6.0
IOCL7
3.0
3.75
4.5
DICR D2 = 0
CSR0
–
1/10250
–
DICR D2 = 1
CSR1
–
1/20500
–
Over-current Low Detection Levels (SOCL[2:0])
010
011
100
101
110
111
A
Current Sense Ratio (9.0V < VPWR < 16V, CSNS < 4.5V)
Current Sense Ratio (CSR0) Accuracy
–
CSR0_ACC
%
Output Current
2.5A
- 20
–
20
5.0A
-14
–
14
6.25A
-13
–
13
7.5A
-12
–
12
10.0A
-13
–
13
12.5A
-13
–
13
Notes
10. Source-Drain ON Resistance (Reverse Drain-to-Source ON Resistance) with negative polarity VPWR.
33988
8
Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 3. Static Electrical Characteristics (continued)
Characteristics noted under conditions 4.5V ≤ VDD ≤ 5.5V, 6.0V ≤ VPWR ≤ 27V, -40°C ≤ TA ≤ 125°C, unless otherwise noted.
Typical values noted reflect the approximate parameter mean at TA = 25°C under nominal conditions, unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
POWER OUTPUT (CONTINUED)
Current Sense Ratio (CSR1) Accuracy
CSR1_ACC
%
Output Current
2.5A
- 25
–
25
5.0A
-19
–
19
6.25A
-18
–
18
7.5A
-17
–
17
10.0A
-18
–
18
12.5A
-18
–
18
4.5
6.0
7.0
30
–
100
2.0
3.0
4.0
- 20
–
-15
TSD
160
175
190
°C
TSD(HYS)
5.0
–
20
°C
Current Sense Clamp Voltage
VCL(CSNS)
CSNS Open; IHS[0:1] = 15A
Open Load Detection Current(11)
IOLDC
Output Fault Detection Threshold
VOLD(THRES)
Output Programmed OFF
Output Negative Clamp Voltage
Over-temperature Shutdown(12)
(12)
μA
V
VCL
0.5A < IHS[0:1] < 2.0A, Output OFF
Over-temperature Shutdown Hysteresis
V
V
Notes
11. Output OFF Open Load Detection Current is the current required to flow through the load for the purpose of detecting the existence of
an open load condition when the specific output is commanded OFF.
12. Guaranteed by process monitoring. Not production tested.
33988
Analog Integrated Circuit Device Data
Freescale Semiconductor
9
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 3. Static Electrical Characteristics (continued)
Characteristics noted under conditions 4.5V ≤ VDD ≤ 5.5V, 6.0V ≤ VPWR ≤ 27V, -40°C ≤ TA ≤ 125°C, unless otherwise noted.
Typical values noted reflect the approximate parameter mean at TA = 25°C under nominal conditions, unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
VIH
0.7 VDD
–
–
V
VIL
–
–
0.2 VDD
V
VIN[0:1] (HYS)
100
600
1200
mV
Input Logic Pull-down Current (SCLK, IN, SI)
IDWN
5.0
–
20
μA
RST Input Voltage Range
VRST
4.5
5.0
5.5
V
SO, FS Tri-state Capacitance(15)
CSO
–
–
20
pF
RDWN
100
200
400
kΩ
CIN
–
4.0
12
pF
7.0
–
14
- 2.0
–
- 0.3
CONTROL INTERFACE
Input Logic High-voltage(13)
Input Logic
Low-voltage(13)
Input Logic Voltage Hysteresis
(14)
Input Logic Pull-down Resistor (RST) and WAKE
Input Capacitance(15)
WAKE Input Clamp
Voltage(16)
VCL(WAKE)
ICL(WAKE) < 2.5 mA
WAKE Input Forward Voltage
VF(WAKE)
ICL(WAKE) = - 2.5mA
SO High-state Output Voltage
V
VSOH
IOH = 1.0mA
V
0.8 VDD
FS, SO Low-state Output Voltage
FSI Enabled, HS[0:1] OFF
FSI Enabled, HS0 ON, HS1 OFF
FSI Enabled, HS[0:1] ON
0
5.0
μA
IUP
CS, VIN[0:1] > 0.7 x VDD
FSI Disabled, HS[0:1] Indeterminate
0.4
μA
- 5.0
FSI Input Pin External Pull-down Resistance
0.2
ISO(LEAK)
CS > 0.7 x VDD
Current(17)
–
V
–
SO Tri-state Leakage Current
–
VSOL
IOL = -1.6mA
Input Logic Pull-up
V
5.0
–
20
RFS
kΩ
RFSDIS
–
0
1.0
RFSOFFOFF
6.0
6.5
7.0
RFSONOFF
15
17
19
RFSONON
40
Infinite
–
Notes
13. Upper and lower logic threshold voltage range applies to SI, CS, SCLK, RST, IN[0:1], and WAKE input signals. The WAKE and RST
signals may be supplied by a derived voltage reference to VPWR.
14.
15.
16.
17.
No hysteresis on FSI and wake pins. Parameter is guaranteed by processing monitoring but is not production tested.
Input capacitance of SI, CS, SCLK, RST, and WAKE. This parameter is guaranteed by process monitoring but is not production tested.
The current must be limited by a series resistance when using voltages > 7.0V.
Pull-up current is with CS OPEN. CS has an active internal pull-up to VDD.
33988
10
Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
DYNAMIC ELECTRICAL CHARACTERISTICS
DYNAMIC ELECTRICAL CHARACTERISTICS
Table 4. Dynamic Electrical Characteristics
Characteristics noted under conditions 4.5V ≤ VDD ≤ 5.5V, 6.0V ≤ VPWR ≤ 27V, -40°C ≤ TA ≤ 125°C, unless otherwise noted.
Typical values noted reflect the approximate parameter mean at TA = 25°C under nominal conditions, unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
POWER OUTPUT TIMING
Output Rising Slow Slew Rate A (DICR D3 = 0)(18)
SRRA_SLOW
9.0V < VPWR < 16V
0.3
Output Rising Slow Slew Rate B (DICR D3 = 0)
(19)
4.8
V/μs
0.3
1.0
2.0
SRFB_SLOW
V/μs
0.12
1)(18)
0.4
1.2
SRFA_FAST
9.0V < VPWR < 16V
V/μs
1.2
1)(19)
3.2
6.4
SRFB_FAST
9.0V < VPWR < 16V
(20)
Output Turn-OFF Delay Time in Slow Slew Rate Mode(21)
0.4
1.4
4.8
1.0
8.0
30
5
57
125
2.0
15
50
–
300
–
μs
μs
t DLY_SLOW(OFF)
DICR = 0
Output Turn-OFF Delay Time in Fast Slew Rate Mode(21)
V/μs
t DLY(ON)
DICR = 0, DICR = 1
μs
t DLY_FAST(OFF)
DICR = 1
Direct Input Switching Frequency (DICR D3 = 0)
0.4
SRFA_SLOW
0)(19)
Output Turn-ON Delay Time in Fast/Slow Slew Rate
6.4
V/μs
0.12
0)(18)
9.0V < VPWR < 16V
Output Falling Fast Slew Rate B (DICR D3 =
1.6
SRRB_FAST
9.0V < VPWR < 16V
Output Falling Fast Slew Rate A (DICR D3 =
1.2
V/μs
0.6
(19)
9.0V < VPWR < 16V
Output Falling Slow Slew Rate B (DICR D3 =
0.4
SRRA_FAST
9.0V < VPWR < 16V
Output Falling Slow Slew Rate A (DICR D3 =
2.0
V/μs
0.12
1)(18)
Output Rising Fast Slew Rate B (DICR D3 = 1)
1.0
SRRB_SLOW
9.0V < VPWR < 16V
Output Rising Fast Slew Rate A (DICR D3 =
V/μs
f PWM
Hz
Notes
18. Rise and Fall Slew Rates A measured across a 5.0Ω resistive load at high side output = 0.5V to VPWR - 3.5V. These parameters are
guaranteed by process monitoring.
19. Rise and Fall Slew Rates B measured across a 5.0Ω resistive load at high side output = VPWR - 3.5V to VPWR - 0.5V. These parameters
are guaranteed by process monitoring.
20. Turn-ON delay time measured from rising edge of IN[0:1] signal that would turn the output ON to VHS[0:1] = 0.5V with RL = 5.0Ω resistive
load.
21. Turn-OFF delay time measured from falling edge that would turn the output OFF to VHS[0:1] = VPWR - 0.5V with RL = 5.0Ω resistive load.
33988
Analog Integrated Circuit Device Data
Freescale Semiconductor
11
ELECTRICAL CHARACTERISTICS
DYNAMIC ELECTRICAL CHARACTERISTICS
Table 4. Dynamic Electrical Characteristics (continued)
Characteristics noted under conditions 4.5V ≤ VDD ≤ 5.5V, 6.0V ≤ VPWR ≤ 27V, -40°C ≤ TA ≤ 125°C, unless otherwise noted.
Typical values noted reflect the approximate parameter mean at TA = 25°C under nominal conditions, unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
t OCL0
t OCL1
t OCL2
t OCL3
108
155
202
Unit
POWER OUTPUT TIMING (CONTINUED)
Overcurrent Detection Blanking Time (OCLT [1:0])
00
01
10
11
Overcurrent High Detection Blanking Time
CS to CSNS Valid Time
(22)
ms
7.0
10
13
0.8
1.2
1.6
0.08
0.15
0.25
t OCH
1.0
10
20
μs
t CNSVAL
–
–
10
μs
t OSD0
t OSD1
t OSD2
t OSD3
t OSD4
t OSD5
t OSD6
t OSD7
–
0
–
55
75
95
110
150
190
165
225
285
220
300
380
275
375
475
330
450
570
385
525
665
HS1 Switching Delay Time (OSD[2:0])
000
001
010
011
100
101
110
111
ms
HS0 Switching Delay Time (OSD[2:0])
000
001
010
011
100
101
110
111
ms
t OSD0
t OSD1
t OSD2
t OSD3
t OSD4
t OSD5
t OSD6
t OSD7
–
0
–
0
–
–
110
150
190
110
150
190
220
300
380
220
300
380
330
450
570
330
450
570
434
620
806
Watchdog Timeout (WD [1:0])(23)
00
01
10
11
ms
t WDTO0
t WDTO1
t WDTO2
t WDTO3
207
310
403
1750
2500
3250
875
1250
1625
Notes
22. Time necessary for the CSNS to be within ±5% of the targeted value.
23. Watchdog timeout delay measured from the rising edge of WAKE to RST from a sleep state condition to output turn-ON with the output
driven OFF and FSI floating. The values shown are for WDR setting of [00]. The accuracy of tWDTO is consistent for all configured
watchdog timeouts.
33988
12
Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
DYNAMIC ELECTRICAL CHARACTERISTICS
Table 4. Dynamic Electrical Characteristics (continued)
Characteristics noted under conditions 4.5V ≤ VDD ≤ 5.5V, 6.0V ≤ VPWR ≤ 27V, -40°C ≤ TA ≤ 125°C, unless otherwise noted.
Typical values noted reflect the approximate parameter mean at TA = 25°C under nominal conditions, unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
f SPI
–
–
3.0
MHz
t WRST
–
50
350
ns
t CS
–
–
300
ns
t ENBL
–
–
5.0
μs
t LEAD
–
50
167
ns
Required High State Duration of SCLK (Required Setup Time)(25)
t WSCLKh
–
–
167
ns
(25)
t WSCLKl
–
–
167
ns
SPI INTERFACE CHARACTERISTICS
Recommended Frequency of SPI Operation
Required Low State Duration for
RST(24)
Rising Edge of CS to Falling Edge of CS (Required Setup Time)
(25)
Rising Edge of RST to Falling Edge of CS (Required Setup Time)(25)
Falling Edge of CS to Rising Edge of SCLK (Required Setup Time)
Required Low State Duration of SCLK (Required Setup Time)
(25)
Falling Edge of SCLK to Rising Edge of CS (Required Setup Time)(25)
t LAG
–
50
167
ns
SI to Falling Edge of SCLK (Required Setup
Time)(26)
t SI(SU)
–
25
83
ns
Falling Edge of SCLK to SI (Required Setup
Time)(26)
t SI(HOLD)
–
25
83
ns
–
25
50
–
25
50
t RSI
–
–
50
ns
t RSI
–
–
50
ns
Time from Falling Edge of CS to SO Low-impedance(27)
t SO(EN)
–
–
145
ns
High-impedance(28)
t SO(DIS)
–
65
145
ns
–
65
105
SO Rise Time
t RSO
CL = 200pF
SO Fall Time
t FSO
CL = 200pF
SI, CS, SCLK, Incoming Signal Rise Time(26)
SI, CS, SCLK, Incoming Signal Fall
Time from Rising Edge of CS to SO
Time(26)
Time from Rising Edge of SCLK to SO Data Valid(29)
0.2 x VDD ≤ SO ≤ 0.8 x VDD, CL = 200pF
Notes
24.
25.
26.
27.
28.
29.
ns
ns
t VALID
ns
RST low duration measured with outputs enabled and going to OFF or disabled condition.
Maximum setup time required for the 33988 is the minimum guaranteed time needed from the microcontroller.
Rise and Fall time of incoming SI, CS, and SCLK signals suggested for design consideration to prevent the occurrence of double pulsing.
Time required for output status data to be available for use at SO. 1.0kΩ on pull-up on CS.
Time required for output status data to be terminated at SO. 1.0kΩ on pull-up on CS.
Time required to obtain valid data out from SO following the rise of SCLK.
33988
Analog Integrated Circuit Device Data
Freescale Semiconductor
13
ELECTRICAL CHARACTERISTICS
TIMING DIAGRAMS
TIMING DIAGRAMS
CS
VPWR
VPWR
VPWR
0.5V
VPWR- -0.5V
SRfB
SRFB_SLOW & SRFB_FAST
SRRB_SLOW & SRRB_FAST
SRrB
VVPWR
- 3V
PWR -3.5V
SRfA
SRFA_SLOW & SRFA_FAST
SRRA_SLOW & SRRA_FAST
SRrA
HS
0.5V
0.5V
t DLY_SLOW(OFF) & tDLY_FAST(OFF)
Tdly(off)
t DLY(ON)
Tdly
(on)
Figure 4. Output Slew Rate and Time Delays
IOCHx
Load
Current
IOCLx
t OCH
Time
t OCLx
Figure 5. Overcurrent Shutdown
IOCH0
IOCH1
IOCL0
IOCL1
Load
Current
IOCL2
IOCL3
IOCL4
IOCL5
IOCL6
IOCL7
Time
t OCHx
t OCL3 t OCL2
t OCL1
t OCL0
Figure 6. Over-current Low and High Detection
33988
14
Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
TIMING DIAGRAMS
• During tOCHX, the device can reach up to IOCH0 overcurrent level.
• During tOCL3 or tOCL2 or tOCL1 or tOCL0, the device can be
programmed to detect up to IOCL0.
Figure 6 illustrates the over-current detection level (IOCLX,
IOCHX) the device can reach for each over-current detection
blanking time (tOCHX, tOCLX):
VIH
V
IH
RSTB
RST
0.2
x VDD
0.2
VDD
VIL
VIL
TwRSTB
t ENBL
t WRST
tTCSB
CS
TENBL
VIH
V
0.7
x VDD
0.7VDD
CS
CSB
IH
0.2
x VDD
0.7VDD
t WSCLKh
TwSCLKh
tTlead
LEAD
VIL
V
IL
t RSI
TrSI
t LAG Tlag
0.70.7VDD
x VDD
SCLK
SCLK
VIH
VIH
0.2 x VDD
0.2VDD
VIL
V
t TSIsu
SI(SU)
IL
t WSCLKl
TwSCLKl
tTfSI
FSI
t SI(HOLD)
TSI(hold)
SI
SI
VIH
V
0.7
VDD
0.7 xVDD
0.2VDD
0.2
x VDD
Don’t Care
Don’t Care
Valid
Don’t Care
Valid
IH
VIH
VIL
Figure 7. Input Timing Switching Characteristics
t FSI
t RSI
TrSI
TfSI
VOH
VOH
3.5V
3.5V
50%
SCLK
SCLK
1.0V
1.0V
VOL
VOL
t SO(EN)
TdlyLH
SO
SO
0.7 xVDD
VDD
0.20.2
VDD
x VDD
Low-to-High
Low
to High
TrSO
t RSO
VOH
VOH
VOL
VOL
VALID
tTVALID
SO
TfSO
t FSO
SO
VOH
VOH
0.7VDD
x VDD
High to Low 0.7
High-to-Low
0.2VDD
0.2 x VDD
TdlyHL
VOL
VOL
t SO(DIS)
Figure 8. SCLK Waveform and Valid SO Data Delay Time
33988
Analog Integrated Circuit Device Data
Freescale Semiconductor
15
FUNCTIONAL DESCRIPTION
FUNCTIONAL PIN DESCRIPTION
FUNCTIONAL DESCRIPTION
INTRODUCTION
The 33988 is a dual self-protected 8.0mΩ silicon switch
used to replace electromechanical relays, fuses, and discrete
devices in power management applications. The 33988 is
designed for harsh environments, and includes self-recovery
features. The device is suitable for loads with high inrush
current, as well as motors and all types of resistive and
inductive loads.
Programming, control, and diagnostics are implemented
via the Serial Peripheral Interface (SPI). A dedicated parallel
input is available for alternate and Pulse Width Modulation
(PWM) control of each output. SPI-programmable fault trip
thresholds allow the device to be adjusted for optimal
performance in the application.
The 33988 is packaged in a power-enhanced 12 x 12
nonleaded PQFN package with exposed tabs.
FUNCTIONAL PIN DESCRIPTION
OUTPUT CURRENT MONITORING (CSNS)
This pin is used to output a current proportional to the
designated HS0-1 output. That current is fed into a groundreferenced resistor and its voltage is monitored by an MCU's
A/D. The channel to be monitored is selected via the SPI.
This pin can be tri-stated through the SPI.
WAKE (WAKE)
This pin is used to input a Logic [1] signal so as to enable
the watchdog timer function. An internal clamp protects this
pin from high damaging voltages when the output is current
limited with an external resistor. This input has a passive
internal pull-down.
RESET (RST)
This input pin is used to initialize the device configuration
and fault registers, as well as place the device in a lowcurrent Sleep mode. The pin also starts the watchdog timer
when transitioning from Logic LOW to Logic HIGH. This pin
should not be allowed to be Logic HIGH until VDD is in
regulation. This pin has a passive internal pull-down.
DIRECT IN 0 & 1 (INx)
This input pin is used to directly control the output HS0 and
1. This input has an active internal pull-down current source
and requires CMOS logic levels. This input may be
configured via the SPI.
FAULT STATUS (FS)
This is an open drain configured output requiring an
external pull-up resistor to VDD for fault reporting. When a
device fault condition is detected, this pin is active LOW.
Specific device diagnostic faults are reported via the SPI SO
pin.
FAIL-SAFE INPUT (FSI)
watchdog timeout occurs. Depending on the resistance
value, either all outputs are OFF, ON, or the output HS0 only
is ON. When the FSI pin is connected to GND, the watchdog
circuit and fail-safe operation are disabled. This pin
incorporates an active internal pull-up current source.
CHIP SELECT (CS)
This input pin is connected to a chip select output of a
master microcontroller (MCU). The MCU determines which
device is addressed (selected) to receive data by pulling the
CS pin of the selected device Logic LOW, enabling SPI
communication with the device. Other unselected devices on
the serial link having their CS pins pulled-up Logic HIGH
disregard the SPI communication data sent. This pin
incorporates an active internal pull-up current source.
SERIAL CLOCK (SCLK)
This input pin is connected to the MCU providing the
required bit shift clock for SPI communication. It transitions
one time per bit transferred at an operating frequency, fSPI,
defined by the communication interface. The 50 percent duty
cycle CMOS-level serial clock signal is idle between
command transfers. The signal is used to shift data into and
out of the device. This input has an active internal pull-down
current source.
SERIAL INPUT (SI)
This is a command data input pin connected to the SPI
Serial Data Output of the MCU or to the SO pin of the
previous device of a daisy chain of devices. The input
requires CMOS logic-level signals and incorporates an active
internal pull-down current source. Device control is facilitated
by the input's receiving the MSB first of a serial 8-bit control
command. The MCU ensures data is available upon the
falling edge of SCLK. The logic state of SI present upon the
rising edge of SCLK loads that bit command into the internal
command shift register.
The value of the resistance connected between this pin
and ground determines the state of the outputs after a
33988
16
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DESCRIPTION
FUNCTIONAL PIN DESCRIPTION
DIGITAL DRAIN VOLTAGE (VDD)
This is an external voltage input pin used to supply power
to the SPI circuit. In the event VDD is lost, an internal supply
provides power to a portion of the logic, ensuring limited
functionality of the device. All device configuration registers
are reset.
SERIAL OUTPUT (SO)
This output pin is connected to the SPI Serial Data Input
pin of the MCU or to the SI pin of the next device of a daisy
chain of devices. This output will remain tri-stated (highimpedance OFF condition) so long as the CS pin of the device
is Logic HIGH. SO is only active when the CS pin of the device
is asserted Logic LOW. The generated SO output signals are
CMOS logic levels. SO output data is available on the falling
edge of SCLK and transitions immediately on the rising edge
of SCLK.
POSITIVE POWER SUPPLY (VPWR)
This pin connects to the positive power supply and is the
source input of operational power for the device. The VPWR
pin is a backside surface mount tab of the package.
HIGH-SIDE OUTPUT 0 & 1 (HSx)
This pin protects 8.0mΩ high-side power output to the
load.
33988
Analog Integrated Circuit Device Data
Freescale Semiconductor
17
FUNCTIONAL DESCRIPTION
FUNCTIONAL INTERNAL BLOCK DESCRIPTION
FUNCTIONAL INTERNAL BLOCK DESCRIPTION
POWER SUPPLY
SELF-PROTECTED
HIGH SIDE SWITCH
MCU INTERFACE AND
OUTPUT CONTROL
HS [0:1]
SPI INTERFACE
MCU
INTERFACE
PARALLEL CONTROL
INPUTS
Figure 9. Functional Internal Block Diagram
POWER SUPPLY
The 33988 is designed to operate from 4.0V to 28V on the
VPWR pin. Characteristics are provided from 6.0V to 20V for
the device. The VPWR pin supplies power to internal
regulator, analog, and logic circuit blocks. The VDD supply is
used for Serial Peripheral Interface (SPI) communication in
order to configure and diagnose the device. This IC
architecture provides a low quiescent current sleep mode.
Applying VPWR and VDD to the device will place the device in
the Normal mode. The device will transit to Fail-safe mode in
case of failures on the SPI (watchdog timeout).
HIGH-SIDE SWITCH: HS[0:1]
Those pins are the high side outputs controlling multiple
automotive loads with high inrush current, as well as motors
and all types of resistive and inductive loads. This N-channel
MOSFET with 8mΩ RDS(ON), is self-protected and each Nchannel presents extended diagnostics in order to detect
load disconnections and short-circuit fault conditions. The
HS[0:1] outputs are actively clamped during a turn-off of
inductive loads.
MCU INTERFACE AND OUTPUT CONTROL
In Normal mode, the loads are controlled directly from the
MCU through the SPI. With a dedicated SPI command, it is
possible to independently turn on and off several loads that
are PWM’d at the same frequency, and duty cycles with only
one PWM signal. An analog feedback output provides a
current proportional to each load current. The SPI is used to
configure and to read the diagnostic status (faults) of the high
side output. The reported fault conditions are: open load,
short-circuit to ground (OCLO-resistive and OCHI-severe
short-circuit), thermal shutdown, and under/over-voltage.
In Fail-safe mode, the loads are controlled with dedicated
parallel input pins. The device is configured in default mode.
33988
18
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
The 33988 has four operating modes: Sleep, Normal,
Fault, and Fail-safe. Table 5 summarizes details contained in
succeeding paragraphs.
Table 5. Fail-Safe Operation and Transitions to Other
33988 Modes
Mode
FS
WAKE
Sleep
x
0
0
x
Device is in Sleep mode.
All outputs are OFF.
Normal
1
x
1
No
Normal mode. Watchdog
is active if enabled.
Fault
0
1
x
No
0
x
1
The device is currently in
Fault mode. The faulted
output(s) is (are) OFF.
1
0
1
Yes
1
1
1
1
1
0
Watchdog has timed out
and the device is in Failsafe mode. The outputs
are as configured with
the RFS resistor
connected to FSI. RST
and WAKE must be
transitioned to Logic [0]
simultaneously to bring
the device out of the Failsafe mode or
momentarily tied the FSI
pin to ground.
Failsafe
RST WDTO
Comments
x = Don’t care.
SLEEP MODE
The default mode of the 33988 is the Sleep mode. This is
the state of the device after first applying battery voltage
(VPWR), prior to any I/O transitions. This is also the state of
the device when the WAKE and RST are both Logic [0]. In the
Sleep mode, the output and all unused internal circuitry, such
as the internal 5.0 V regulator, are off to minimize current
draw. In addition, all SPI-configurable features of the device
are as if set to Logic [0]. The device will transition to the
Normal or Fail-safe operating modes based on the WAKE
and RST inputs as defined in Table 5.
NORMAL MODE
The 33988 is in Normal mode when:
• VPWR is within the normal voltage range.
• RST pin is Logic [1].
• No fault has occurred.
FAIL-SAFE AND WATCHDOG
If the FSI input is not grounded, the watchdog timeout
detection is active when either the WAKE or RST input pin
transitions from Logic [0] to Logic [1]. The WAKE input is
capable of being pulled up to VPWR with a series of limiting
resistance that limits the internal clamp current according to
the specification.
The watchdog timeout is a multiple of an internal oscillator
and is specified in Table 14. As long as the WD bit (D7) of an
incoming SPI message is toggled within the minimum
watchdog timeout period (WDTO), based on the
programmed value of the WDR the device will operate
normally. If an internal watchdog timeout occurs before the
WD bit, the device will revert to a Fail-safe mode until the
device is reinitialized.
During the Fail-safe mode, the outputs will be ON or OFF
depending upon the resistor RFS connected to the FSI pin,
regardless of the state of the various direct inputs and modes
(Table 6). In this mode, the SPI register content is retained
except for over-current high and low detection levels and
timing, which are reset to their default value (SOCL, SOCH,
and OCLT). Then the watchdog, over-voltage, overtemperature, and over-current circuitry (with default value)
are fully operational.
Table 6. Output State During Fail-safe Mode
RFS (kΩ)
High Side State
0
Fail-safe mode Disabled
6.0
Both HS0 and HS1 OFF
17
HS0 ON, HS1 OFF
Open
Both HS0 and HS1 ON
The Fail-safe mode can be detected by monitoring the
WDTO bit D2 of the WD register. This bit is Logic [1] when the
device is in Fail-safe mode. The device can be brought out of
the Fail-safe mode by transitioning the WAKE and RST pins
from Logic [1] to Logic [0] or forcing the FSI pin to Logic [0].
Table 5 summarizes the various methods for resetting the
device from the latched Fail-safe mode.
If the FSI pin is tied to GND, the Watchdog Fail-safe
operation is disabled.
LOSS OF VDD
If the external 5.0V supply is not within specification, or
even disconnected, all register content is reset. The two
outputs can still be driven by the direct inputs IN 1:IN0. The
33988 uses the battery input to power the output MOSFETrelated current sense circuitry and any other internal logic
providing Fail-safe device operation with no VDD supplied. In
this state, the watchdog, over-voltage, over-temperature, and
over-current circuitry are fully operational with default values.
33988
Analog Integrated Circuit Device Data
Freescale Semiconductor
19
FUNCTIONAL DEVICE OPERATION
PROTECTION AND DIAGNOSIS FEATURES
FAULT MODE
The 33988 indicates the following faults as they occur by
driving the FS pin to Logic [0]:
• Over-temperature fault
• Open load fault
• Over-current fault (high and low)
• Over-voltage and under-voltage fault
The FS pin will automatically return to Logic [1] when the
fault condition is removed, except for over-current and in
some cases under-voltage.
Fault information is retained in the fault register and is
available (and reset) via the SO pin during the first valid SPI
communication (refer to Table 16).
PROTECTION AND DIAGNOSIS FEATURES
OVER-TEMPERATURE FAULT (NON-LATCHING)
The 33988 incorporates over-temperature detection and
shutdown circuitry in each output structure. Overtemperature detection is enabled when an output is in the ON
state.
For the output, an over-temperature fault (OTF) condition
results in the faulted output turning OFF until the temperature
falls below the TSD(HYS). This cycle will continue indefinitely
until action is taken by the MCU to shut OFF the output, or
until the offending load is removed.
When experiencing this fault, the OTF fault bit will be set
in the status register and cleared after either a valid SPI read
or a power reset of the device.
OVER-VOLTAGE FAULT (NON-LATCHING)
The 33988 shuts down the output during an over-voltage
fault (OVF) condition on the VPWR pin. The output remains in
the OFF state until the over-voltage condition is removed.
When experiencing this fault, the OVF fault bit is set in the bit
OD1 and cleared after either a valid SPI read or a power reset
of the device.
The over-voltage protection and diagnostic can be
disabled trough SPI (bit OV_dis).
UNDER-VOLTAGE SHUTDOWN (LATCHING OR
NON-LATCHING)
The output(s) will latch off at some battery voltage below
6.0 V. As long as the VDD level stays within the normal
specified range, the internal logic states within the device will
be sustained.
In the case where the battery voltage drops below the
under-voltage threshold (VPWRUV) output will turn off, FS
will go to Logic [0], and the fault register UVF bit will be set to
1. Two cases need to be considered when the battery level
recovers:
• If output(s) command is (are) low, FS will go to Logic [1]
but the UVF bit will remain set to 1 until the next read
operation.
• If the output command is ON, then FS will remain at
Logic [0]. The output must be turned OFF and ON again
to re-enable the state of output and release FS . The
UVF bit will remain set to 1 until the next read operation.
The under-voltage protection can be disabled through the
SPI (bit UV_dis = 1). In this case, the FS and UVF bit do not
report any under-voltage fault condition and the output state
will not be changed as long as the battery voltage does not
drop any lower than 2.5V.
OPEN LOAD FAULT (NON-LATCHING)
The 33988 incorporates open load detection circuitry on
each output. Output open load fault (OLF) is detected and
reported as a fault condition when that output is disabled
(OFF). The open load fault is detected and latched into the
status register after the internal gate voltage is pulled low
enough to turn OFF the output. The OLF fault bit is set in the
status register. If the open load fault is removed, the status
register will be cleared after reading the register.
The open load protection can be disabled trough SPI (bit
OL_dis). It is recommended to disable the open load
detection circuitry (OL_dis bit sets to logic [1]) in case
of permanent open load fault condition.
OVER-CURRENT FAULT (LATCHING)
The device has eight programmable over-current low
detection levels (IOCL) and two programmable over-current
high detection levels (IOCH) for maximum device protection.
The two selectable, simultaneously active over-current
detection levels, defined by IOCH and IOCL, are illustrated in
Figure 6. The eight different over-current low detect levels
(IOCL0 : IOCL7) are likewise illustrated in Figure 6.
If the load current level ever reaches the selected overcurrent low detect level and the over-current condition
exceeds the programmed over-current time period (tOCx), the
device will latch the effected output OFF.
If at any time the current reaches the selected IOCH level,
then the device will immediately latch the fault and turn OFF
the output, regardless of the selected tOCL driver.
For both cases, the device output will stay off indefinitely
until the device is commanded OFF and then ON again.
REVERSE BATTERY
The output survives the application of reverse voltage as
low as -16V. Under these conditions, the output’s gates are
enhanced to keep the junction temperature less than 150°C.
The ON resistance of the output is fairly similar to that in the
Normal mode. No additional passive components are
required.
33988
20
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
GROUND DISCONNECT PROTECTION
In the event the 33988 ground is disconnected from load
ground, the device protects itself and safely turns OFF the
output regardless the state of the output at the time of
disconnection. A 10K resistor needs to be added between the
wake pin and the rest of the circuitry in order to ensure that
the device turns off in case of ground disconnect and to
prevent this pin to exceed its maximum ratings
Table 7. Device Behavior in Case of Under-voltage
High Side
Switch
(VPWR Battery
Voltage) ∗∗
VPWR >
VPWRUV
VPWRUV >
VPWR >
UVPOR
UVPOR >
VPWR > 2.5V ∗
State
Output State
UV Enable
UV Enable
UV Enable
UV Enable
IN = 0
IN = 0
IN∗∗∗ = 1
IN∗∗∗ = 1
(Falling VPWR) (Rising VPWR) (Falling VPWR) (Rising VPWR)
UV Disable
IN = 0
(Falling or
Rising VPWR)
UV Disable
IN∗∗∗ = 1
(Falling or
Rising VPWR)
OFF
OFF
ON
OFF
OFF
ON
FS State
1
1
1
0
1
1
SPI Fault
Register UVF
Bit
0
1 until next read
0
1
0
0
Output State
OFF
OFF
OFF
OFF
OFF
ON
FS State
0
0
0
0
1
1
SPI Fault
Register UVF
Bit
1
1
1
1
0
0
Output State
OFF
OFF
OFF
OFF
OFF
ON
1
1
1
1
1
1
1 until next read
1
0
0
OFF
OFF
OFF
OFF
OFF
OFF
1
1
1
1
1
1
0
0
FS State
SPI Fault
Register UVF
Bit
2.5V > VPWR > Output State
0V
FS State
SPI Fault
Register UVF
Bit
Comments
1 until next read 1 until next read
1 until next read 1 until next read 1 until next read 1 until next read
UV fault is
not latched
UV fault is
not latched
UV fault
is latched
∗ Typical value; not guaranteed
∗∗ While VDD remains within specified range.
∗∗∗ = IN is equivalent to IN direct input or IN_spi SPI input.
33988
Analog Integrated Circuit Device Data
Freescale Semiconductor
21
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
LOGIC COMMANDS AND REGISTERS
SPI PROTOCOL DESCRIPTION
to D0. The internal registers of the 33988 are configured and
controlled using a 4-bit addressing scheme, as shown in
Table 8. Register addressing and configuration are described
in Table 9. The SI input has an active internal pull-down,
IDWN.
The SPI interface has a full duplex, three-wire
synchronous data transfer with four I/O lines associated with
it: Serial Clock (SCLK), Serial Input (SI), Serial Output (SO),
and Chip Select (CS).
The SI / SO pins of the 33988 follow a first-in first-out (D7/
D0) protocol with both input and output words transferring the
most significant bit (MSB) first. All inputs are compatible with
5.0 V CMOS logic levels.
The SPI lines perform the following functions:
SERIAL OUTPUT (SO)
The SO data pin is a tri-stateable output from the shift
register. The SO pin remains in a high-impedance state until
the CS pin is put into a Logic [0] state. The SO data is capable
of reporting the status of the output, the device configuration,
and the state of the key inputs. The SO pin changes states on
the rising edge of SCLK and reads out on the falling edge of
SCLK. Fault and Input Status descriptions are provided in
Table 5.
SERIAL CLOCK (SCLK)
Serial clocks (SCLK) the internal shift registers of the
33988 device. The serial input (SI) pin accepts data into the
input shift register on the falling edge of the SCLK signal
while the serial output (SO) pin shifts data information out of
the SO line driver on the rising edge of the SCLK signal. It is
important that the SCLK pin be in a logic low state whenever
CS makes any transition. For this reason, it is recommended
that the SCLK pin be in a Logic [0] state whenever the device
is not accessed (CS Logic [1] state). SCLK has an active
internal pull-down, IDWN. When CS is Logic [1], signals at the
SCLK and SI pins are ignored and SO is tri-stated (highimpedance). See Figure 10 and Figure 11.
CHIP SELECT (CS)
The CS pin enables communication with the master
microcontroller (MCU). When this pin is in a Logic [0] state,
the device is capable of transferring information to, and
receiving information from, the MCU. The 33988 device
latches in data from the Input shift registers to the addressed
registers on the rising edge of CS. The device transfers status
information from the power output to the shift register on the
falling edge of CS. The SO output driver is enabled when CS
is Logic [0]. CS should transition from a Logic [1] to a Logic [0]
state only when SCLK is a Logic [0]. CS has an active internal
pull-up, IUP.
SERIAL INPUT (SI)
This is a serial interface (SI) command data input pin. SI
instruction is read on the falling edge of SCLK. An 8-bit
stream of serial data is required on the SI pin, starting with D7
CSB
CS
SCLK
SI
SO
SO
NOTES:
1.
D7
OD7
D6
OD6
D5
OD5
D4
OD4
D3
OD3
D2
OD2
D1
OD1
D0
OD0
RSTB
RST is in a logic 1 state during the above operation.
Logic
[1] relate
state to
during
therecent
above
operation.
Notes
2. 1.
D0,RST
D1, is
D2,a ...,
and D7
the most
ordered
entry of data into the SPSS
D7:D0
to and
the OD7
mostrelate
recent
ordered
entry
of datafault
intoand
thestatus
device.
3. 2.
OD0,
OD1,relate
OD2, ...,
to the
first 8 bits
of ordered
data out
of
the
device.
3. OD7:OD0 relate to the first 8 bits of ordered fault and status data out of the device.
Figure 10. Single 8-Bit Word SPI Communication
33988
22
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
C S B
CS
SSCLK
C L K
SI
S I
D 7
SSO
O
O D 7
D 6
D 5
O D 6
D 2
O D 5
O D 2
D 1
D 0
O D 1
O D 0
D 7 *
D 6 *
D 7
D 5 *
D 6
D 2 *
D 5
D 1 *
D 2
D 0 *
D 1
D 0
.
ST T B i s i n a l o g i c 1 s t a t e d u r i n g t h e a b o v e o p e r a t i o n .
RRSis
Notes 1.12 RST
a Logic [1] state during the above operation.
.
D 0 , D 1 , D 2 , . .., a n d D 7 r e la t e t o t h e m o s t r e c e n t o r d e r e d e n tr y o f d a ta in to th e S P S S
.
O D 0 , O D 1 , O D 2 , . . ., a n d O D 7 r e la t e t o t h e fir s t 8 b it s o f o r d e r e d f a u lt a n d s t a t u s d a t a o u t o f t h e d e v ic e .
2.34 D7:D0
relate to the most recent ordered entry of data into the device.
.
O D 0 , O D 1 , O D 2 , .. ., a n d O D 7 r e p r e s e n t t h e f ir s t 8 b its o f o r d e r e d f a u lt a n d s t a t u s d a t a o u t o f t h e S P S S
3. D7*:D0* relate to the previous 8 bits (last command word) of data that was previously shifted into the device.
4. OD7:OD0 relate to the Ffirst
8 bits of ordered fault and status data out of the device.
I G U R E 4 b . M U L T I P L E 8 b it W O R D S P I C O M M U N I C A T I O N
N O T E S :
Figure 11. Multiple 8-Bit Word SPI Communication
SERIAL INPUT COMMUNICATION
SPI communication is accomplished using 8-bit
messages. A message is transmitted by the MCU starting
with the MSB, D7, and ending with the LSB, D0 (Table 8).
Each incoming command message on the SI pin can be
interpreted using the following bit assignments: the MSB (D7)
is the watchdog bit and in some cases a register address bit
common to both outputs or specific to an output; the next
three bits, D6 : D4, are used to select the command register;
and the remaining four bits, D3 : D0, are used to configure and
control the outputs and their protection features.
Multiple messages can be transmitted in succession to
accommodate those applications where daisy chaining is
desirable, or to confirm transmitted data, as long as the
messages are all multiples of eight bits. Any attempt made to
latch in a message that is not eight bits will be ignored.
The 33988 has defined registers, which are used to
configure the device and to control the state of the output.
Table 9, summarizes the SI registers. The registers are
addressed via D6 : D4 of the incoming SPI word (Table 8).
Table 8. SI Message Bit Assignment
Bit Sig SI Msg Bit
MSB
LSB
D7
Message Bit Description
Register address bit for output selection.
Also used for Watchdog: toggled to satisfy
watchdog requirements.
D6 : D4
Register address bits.
D3 : D1
Used to configure the inputs, outputs, and
the device protection features and SO status
content.
D0
Used to configure the inputs, outputs, and
the device protection features and SO status
content.
Table 9. Serial Input Address and Configuration Bit Map
SI
Register D7 D6 D5 D4
Serial Input Data
D3
D2
D1
D0
SOA2
SOA1
SOA0
STATR
s
0
0
0
0
OCR
x
0
0
1
CSNS1
IN1_SPI CSNS0 IN0_SPI
EN
EN
SOCHLR s
0
1
0
SOCHs SOCL2s SOCL1s SOCL0s
CDTOLR s
0
1
1
OL_DIS CD_DIS OCLT1s OCLT0 s
s
s
DICR
s
1
0
0
FAST
SR s
CSNS
high s
IN DIS s
A/Os
OSDR
0
1
0
1
0
OSD2
OSD1
OSD0
WDR
1
1
0
1
0
0
WD1
WD0
NAR
0
1
1
0
0
0
0
0
UOVR
1
1
1
0
0
0
UV_dis
OV_dis
TEST
x
1
1
1
Freescale Internal Use (Test)
x = Don’t care.
s (SOA3 bit) = Selection of output: Logic [0] = HS0, Logic [1] =
HS1.
33988
Analog Integrated Circuit Device Data
Freescale Semiconductor
23
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
DEVICE REGISTER ADDRESSING
The following section describes the possible register
addresses and their impact on device operation.
Address x000 — Status Register (STATR)
The STATR register is used to read the device status and
the various configuration register contents without disrupting
the device operation or the register contents. The register bits
D2:D0, determine the content of the first eight bits of SO data.
When register content is specific to one of the two outputs, bit
D7 is used to select the desired output (SOA3). In addition to
the device status, this feature provides the ability to read the
content of the OCR, SOCHLR, CDTOLR, DICR, OSDR,
WDR, NAR, and UOVR registers. (Refer to the section
entitled Serial Output Communication (Device Status Return
Data).)
Address x001 — Output Control Register (OCR)
The OCR register allows the MCU to control the outputs
through the SPI. Incoming message bit D0 reflects the
desired states of the high side output HS0 (IN0_SPI): a
Logic [1] enables the output switch and a Logic [0] turns it
OFF. A Logic [1] on message bit D1 enables the Current
Sense (CSNS) pin. Similarly, incoming message bit D2
reflects the desired states of the high side output HS1
(IN1_SPI): Logic [1] enables the output switch and a Logic [0]
turns it OFF. A Logic [1] on message bit D3 enables the
CSNS pin. In the event that the current sense is enabled for
both outputs, the current will be summed. Bit D7 is used to
feed the watchdog if enabled.
Address x010— Select Over-current High and Low
Register (SOCHLR)
The SOCHLR register allows the MCU to configure the
output over-current low and high detection levels,
respectively. Each output is independently selected for
configuration based on the state of the D7 bit; a write to this
register when D7 is Logic [0] will configure the current
detection levels for the HS0. Similarly, if D7 is Logic [1] when
this register is written, HS1 is configured. Each output can be
configured to different levels. In addition to protecting the
device, this slow blow fuse emulation feature can be used to
optimize the load requirements matching system
characteristics. Bits D2 : D0 set the over-current low detection
level to one of eight possible levels, as shown in Table 10.
Bit D3 sets the over-current high detection level to one of two
levels, which is described inTable 11.
Table 10. Over-current Low Detection Levels
SOCL2
(D2)
SOCL1
(D1)
SOCL0
(D0)
Over-current Low Detection
(Amperes)
0
0
0
12.5
0
0
1
11.25
0
1
0
10.0
0
1
1
8.75
1
0
0
7.5
1
0
1
6.25
1
1
0
5.0
1
1
1
3.75
Table 11. Over-current High Detection Levels
SOCH (D3)
Over-current High Detection
(Amperes)
0
50
1
37.5
Address x011 — Current Detection Time and Open Load
Register (CDTOLR)
The CDTOLR register is used by the MCU to determine
the amount of time the device will allow an over-current low
condition before output latches OFF occurs. Each output is
independently selected for configuration based on the state
of the D7 bit. A write to this register when bit 7 is Logic [0] will
configure the timeout for the HS0. Similarly, if D7 is Logic [1]
when this register is written, then HS1 is configured. Bits
D1: D0 allow the MCU to select one of four fault blanking
times defined in Table 12. Note that these timeouts apply
only to the over-current low detection levels. If the selected
over-current high level is reached, the device will latch off
within 20μs.
Table 12. Over-current Low Detection Blanking Time
OCLT [1:0]
Timing
00
155ms
01
10ms
10
1.2ms
11
150μs
A Logic [1] on bit D2 disables the over-current low
(CD_dis) detection timeout feature. A Logic [1] on bit D3
disables the open load (OL) detection feature.
33988
24
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
Address x100 — Direct Input Control Register (DICR)
The DICR register is used by the MCU to enable, disable,
or configure the direct IN pin control of each output. Each
output is independently selected for configuration based on
the state of bit D7. A write to this register when bit D7 is
Logic [0] will configure the direct input control for the HS0.
Similarly, if D7 is Logic [1] when this register is written, then
HS1 is configured.
A Logic [0] on bit D1 will enable the output for direct control
by the IN pin. A Logic [1] on bit D1 will disable the output from
direct control. While addressing this register, if the input was
enabled for direct control, a Logic [1] for the D0 bit will result
in a Boolean AND of the IN pin with its corresponding D0
message bit when addressing the OCR register. Similarly, a
Logic [0] on the D0 pin results in a Boolean OR of the IN pin
with the corresponding message bits when addressing the
OCR register.
The DICR register is useful if there is a need to
independently turn on and off several loads that are PWM’d
at the same frequency and duty cycle with only one PWM
signal. This type of operation can be accomplished by
connecting the pertinent direct IN pins of several devices to a
PWM output port from the MCU and configuring each of the
outputs to be controlled via their respective direct IN pin. The
DICR is then used to Boolean AND the direct IN(s) of each of
the outputs with the dedicated SPI bit that also controls the
output. Each configured SPI bit can now be used to enable
and disable the common PWM signal from controlling its
assigned output.
A Logic [1] on bit D2 is used to select the high ratio (CSR1,
1/41000) on the CSNS pin for the selected output. The
default value [0] is used to select the low ratio (CSR0,
1/20500). A Logic [1] on bit D3 is used to select the high
speed slew rate for the selected output. The default value [0]
corresponds to the low speed slew rate.
Address 0101 — Output Switching Delay Register (OSDR)
The OSDR register configures the device with a
programmable time delay that is active during Output ON
transitions initiated via SPI (not via direct input).
A write to this register configures both outputs for different
delay. Whenever the input is commanded to transition from
Logic [0] to Logic [1], both outputs will be held OFF for the
time delay configured in the OSDR. The programming of the
contents of this register have no effect on device Fail-safe
mode operation. The default value of the OSDR register is
000, equating to no delay. This feature allows the user a way
to minimize inrush currents, or surges, thereby allowing loads
to be switched ON with a single command. There are eight
selectable output switching delay times that range from 0ms
to 525ms. Refer to Table 13.
Table 13. Switching Delay
OSD [2:0] (D2 : D0)
Turn ON Delay (ms) Turn ON Delay (ms)
HS0
HS1
000
0
0
001
75
0
010
150
150
011
225
150
100
300
300
101
375
300
110
450
450
111
525
450
Address 1101 — Watchdog Register (WDR)
The WDR register is used by the MCU to configure the
watchdog timeout. Watchdog timeout is configured using bits
D1:D0. When D1:D0 bits are programmed for the desired
watchdog timeout period, the WD bit (D7) should be toggled
as well, ensuring the new timeout period is programmed at
the beginning of a new count sequence. Refer to Table 14.
Table 14. Watchdog Timeout
WD [1:0] (D1: D0)
Timing (ms)
00
620
01
310
10
2500
11
1250
Address 0110 — No Action Register (NAR)
The NAR register can be used to no-operation fill SPI data
packets in a daisy chain SPI configuration. This allows
devices to not be affected by commands being clocked over
a daisy-chained SPI configuration, and by toggling the WD bit
(D7), the watchdog circuitry will continue to be reset while no
programming or data readback functions are being requested
from the device.
Address 1110 — Under-voltage/Over-voltage Register
(UOVR)
The UOVR register can be used to disable or enable overvoltage and/or under-voltage protection. By default
(Logic [0]), both protections are active. When disabled, an
under-voltage or over-voltage condition fault will not be
reported in the output fault register.
Address x111 — TEST
The TEST register is reserved for test and is not
accessible with the SPI during normal operation.
33988
Analog Integrated Circuit Device Data
Freescale Semiconductor
25
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
SERIAL OUTPUT COMMUNICATION
(DEVICE STATUS RETURN DATA)
to the MCU during the first SPI communication following
this condition should be ignored.
When the CS pin is pulled low, the output status register is
loaded. Meanwhile, the data is clocked out MSB- (OD7-) first
as the new message data is clocked into the SI pin. The first
eight bits of data clocking out of the SO, and following a CS
transition, are dependant upon the previously written SPI
word.
Any bits clocked out of the SO pin after the first eight will
be representative of the initial message bits clocked into the
SI pin since the CS pin first transitioned to a Logic [0]. This
feature is useful for daisy chaining devices as well as
message verification.
A valid message length is determined following a CS
transition of Logic [0] to Logic [1]. If there is a valid message
length, the data is latched into the appropriate registers. A
valid message length is a multiple of eight bits. At this time,
the SO pin is tri-stated and the fault status register is now
able to accept new fault status information.
The output status register correctly reflects the status of
the STATR-selected register data at the time that the CS is
pulled to a Logic [0] during SPI communication and / or for the
period of time since the last valid SPI communication, with
the following exceptions:
• The previous SPI communication was determined to be
invalid. In this case, the status will be reported as
though the invalid SPI communication never occurred.
• Battery transients below 6.0V resulting in an undervoltage shutdown of the outputs may result in incorrect
data loaded into the status register. The SO data
transmitted to the MCU during the first SPI
communication following an under-voltage VPWR
condition should be ignored.
• The RST pin transition from a Logic [0] to Logic [1] while
the WAKE pin is at Logic [0] may result in incorrect data
loaded into the status register. The SO data transmitted
SERIAL OUTPUT BIT ASSIGNMENT
The 8 bits of serial output data depend on the previous
serial input message, as explained in the following
paragraphs. Table 15 summarizes the SO register content.
Bit OD7 reflects the state of the watchdog bit (D7)
addressed during the prior communication. The value of the
previous D7 will determine which output the status
information applies to for the Fault (FLTR), SOCHLR,
CDTOLR, and DICR registers. SO data will represent
information ranging from fault status to register contents,
user selected by writing to the STATR bits D2:D0. Note that
the SO data will continue to reflect the information for each
output (depending on the previous D7 state) that was
selected during the most recent STATR write until changed
with an updated STATR write.
Previous Address SOA[2:0] = 000
If the previous three MSBs are 000, bits OD6 : OD0 will
reflect the current state of the Fault register (FLTR)
corresponding to the output previously selected with the bit
OD7 (Table 16).
Previous Address SOA[2:0] = 001
Data in bits OD1:OD0 contain CSNS0 EN and IN0_SPI
programmed bits, respectively. Data in bits OD3:OD2 contain
CSNS0 EN and IN0_SPI programmed bits, respectively.
Previous Address SOA[2:0] = 010
The data in bit OD3 contain the programmed over-current
high detection level (refer to Table 11), and the data in bits
OD2:OD0 contain the programmed over-current low
detection levels (refer to Table 12).
Table 15. Serial Output Bit Map Description
Previous STATR
D7, D2, D1, D0
Serial Output Returned Data
SOA3 SOA2 SOA1 SOA0
OD7
OD6
OD5
OD4
OD3
OD2
OD1
OD0
s
0
0
0
s
OTFs
OCHFs
OCLFs
OLFs
UVF
OVF
FAULTs
x
0
0
1
x
0
0
1
CSNS1 EN
IN1_SPI
CSNS0 EN
IN0_SPI
s
0
1
0
s
0
1
0
SOCHs
SOCL2s
SOCL1s
SOCL0s
s
0
1
1
s
0
1
1
OL_DIS s
CD_DIS s
OCLT1s
OCLT0s
s
1
0
0
s
1
0
0
FAST SR s CSNS high s
0
1
0
1
0
1
0
1
FSM_HS0
1
1
0
1
1
1
0
1
FSM_HS1
WDTO
WD1
WD0
0
1
1
0
0
1
1
0
IN1 Pin
IN0 Pin
FSI Pin
WAKE Pin
1
1
1
0
1
1
1
0
–
–
UV_dis
OV_dis
x
1
1
1
–
–
–
–
–
–
–
–
OSD2
IN DIS s
A/O s
OSD1
OSD0
s = Selection of output: Logic [0] = HS0, Logic [1] = HS1.
x = Don’t care.
33988
26
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
Previous Address SOA[2:0] = 101
Table 16. Fault Register
OD7
OD6
s
OTF
OD5
OD4
OCHFs OCLFs
OD3
OD2
OD1
OD0
OLFs
UVF
OVF
FAULTs
OD7 (s) = Selection of output: Logic [0] = HS0, Logic [1] = HS1.
OD6 (OTF) = Over-temperature Flag.
OD5 (OCHFs) = Over-current High Flag. (This fault is latched.)
OD4 (OCLFs) = Over-current Low Flag. (This fault is latched.)
OD3 (OLFs) = Open Load Flag.
OD2 (UVF) = Under-voltage Flag. (This fault is latched or not latched.)
OD1 (OVF) = Over-voltage Flag.
OD0 (FAULTs) = This flag reports a fault and is reset by a read
operation.
Note The FS pin reports a fault. For latched faults, this pin is reset by
a new Switch ON command (via SPI or direct input IN).
Previous Address SOA[2:0] = 011
Data returned in bits OD1 and OD0 are current values for
the over-current fault blanking time, illustrated in Table 12. Bit
OD2 reports if the over-current detection timeout feature is
active. OD3 reports if the open load circuitry is active.
Previous Address SOA[2:0] =100
The returned data contain the programmed values in the
DICR.
• SOA3 = 0. The returned data contain the programmed
values in the OSDR. Bit OD3 (FSM_HS0) reflects the
state of the output HS0 in the Fail-safe mode after a
watchdog timeout occurs.
• SOA3 = 1. The returned data contain the programmed
values in the WDR. Bit OD2 (WDTO) reflects the status
of the watchdog circuitry. If WDTO bit is Logic [1], the
watchdog has timed out and the device is in Fail-safe
mode. If WDTO is Logic [0], the device is in Normal
mode (assuming the device is powered and not in Sleep
mode), with the watchdog either enabled or disabled.
Bit OD3 (FSM_HS1) reflects the state of the output HS1
in the Fail-safe mode after a watchdog timeout occurs.
Previous Address SOA[2:0] = 110
• SOA3 = 0. OD3:OD0 return the state of the IN1, IN0,
FSI, and WAKE pins, respectively (Table 17).
Table 17. Pin Register
OD3
OD2
OD1
OD0
IN1 Pin
IN0 Pin
FSI Pin
WAKE Pin
• SOA3 = 1. The returned data contain the programmed
values in the UOVR. Bit OD1 reflects the state of the
under-voltage protection and bit OD0 reflects the state
of the over-voltage protection. Refer to Table 15).
Previous Address SOA[2:0] =111
Null Data. No previous register Read Back command
received, so bits OD2:OD0 are null, or 000.
33988
Analog Integrated Circuit Device Data
Freescale Semiconductor
27
TYPICAL APPLICATIONS
TYPICAL APPLICATIONS
The 33988 can be configured in several applications. The figure below shows the 33988 in a typical main switch application.
VPWR
VDD
Voltage
Regulator
VDD
VDD NC VPWR
2.2k
VDD
VPWR
10k
MCU
10
100nF
10µF
2
I/O
I/O
SCLK
CS
I/O
SI
SO
I/O
A/D
10k
4
10k
12
10k
10k
8
10k
7
3
11
10k
9
5
1
6
1k
VDD
WAKE
IN0
IN1
SCLK
CS
RST
SO
SI
FS
CSNS
FSI
VPWR
14
HS1
15
2.5µF
10nF
33988
HS0
16
LOAD
GND
LOAD
13
RFS
Figure 12. Typical Applications
Two application notes are available in order to:
• propose safe configurations of the eXtreme Switch
devices in case of application faults and protect all circuitry
with minimum external components (AN 3274),
• provide guidelines for Printed Circuit Board (PCB) design
and assembly (AN 2469).
Development effort will be required by the end users to
optimize the board design and PCB layout in order to reach
electromagnetic compatibility standards (emission and
immunity).
The loads must be chosen in order to guarantee the device
normal operating condition as junction temperature from -40
to 150°C. In case of permanent short-circuit conditions, the
duration and number of activation cycles must be limited with
a dedicated MCU fault management using the fault reporting
through SPI.
Figure 13 describes the maximum turn-off current versus
load inductance for single-pulse method, based on lab
characterization results. When driving DC motor or Solenoid
loads demanding multiple switching, an external recirculation
device must be used to maintain the device in its Safe
Operating Area.
33988
28
Analog Integrated Circuit Device Data
Freescale Semiconductor
TYPICAL APPLICATIONS
Figure 13. Maximum Turn-off Current Versus Inductive Load (Single Pulse for RL = 0 and VPWR = 12 V at TJ = 150°C Initial)
33988
29
Analog Integrated Circuit Device Data
Freescale Semiconductor
PACKAGING
SOLDERING INFORMATION
PACKAGING
SOLDERING INFORMATION
SOLDERING INFORMATION
The 33988 is packaged in a surface mount power package
intended to be soldered directly on the printed circuit board.
The 33988 was qualified in accordance with JEDEC
standards JESD22-A113-B and J-STD-020A. The
recommended reflow conditions are as follows:
• Convection: 225°C +5 .0/ -0°C
• Vapor Phase Reflow (VPR): 215°C to 219°C
• Infrared (IR) / Convection: 225°C +5.0 / -0°C
The maximum peak temperature during the soldering
process should not exceed 230°C. The time at maximum
temperature should range from 10s to 40s maximum.
33988
30
Analog Integrated Circuit Device Data
Freescale Semiconductor
PACKAGING
PACKAGE DIMENSIONS
PACKAGE DIMENSIONS
For the most current revision of the package, visit www.freescale.com and perform a keyword search on 98ARL10521D.
PNA SUFFIX
16-PIN PQFN
98ARL10521D
ISSUE C
33988
Analog Integrated Circuit Device Data
Freescale Semiconductor
31
PACKAGING
PACKAGE DIMENSIONS (CONTINUED)
PACKAGE DIMENSIONS (CONTINUED)
PNA SUFFIX
16-PIN PQFN
98ARL10521D
ISSUE C
33988
32
Analog Integrated Circuit Device Data
Freescale Semiconductor
REVISION HISTORY
REVISION HISTORY
REVISION
DATE
DESCRIPTION OF CHANGES
1.0
1/2007
• Initial release
2.0
5/2007
3.0
8/2007
• Changed typ and max number on Output Turn-ON Delay Time in Fast/Slow Slew Rate(20)
• Changed min on Output Turn-OFF Delay Time in Fast Slew Rate Mode(21)
• Changed labels on HS1 Switching Delay Time (OSD[2:0]) and HS0 Switching Delay Time
(OSD[2:0])
• Corrected labels on Figure 12, Typical Applications
• Updated Freescale format and style
• Updated Junction-to-Ambient
• Added Functional Internal Block Description
• Updated Device Behavior in Case of Under-voltage
4.0
11/2009
• Added one paragraph and figure to Typical Applications
33988
Analog Integrated Circuit Device Data
Freescale Semiconductor
33
How to Reach Us:
Home Page:
www.freescale.com
Web Support:
http://www.freescale.com/support
USA/Europe or Locations Not Listed:
Freescale Semiconductor, Inc.
Technical Information Center, EL516
2100 East Elliot Road
Tempe, Arizona 85284
1-800-521-6274 or +1-480-768-2130
www.freescale.com/support
Europe, Middle East, and Africa:
Freescale Halbleiter Deutschland GmbH
Technical Information Center
Schatzbogen 7
81829 Muenchen, Germany
+44 1296 380 456 (English)
+46 8 52200080 (English)
+49 89 92103 559 (German)
+33 1 69 35 48 48 (French)
www.freescale.com/support
Japan:
Freescale Semiconductor Japan Ltd.
Headquarters
ARCO Tower 15F
1-8-1, Shimo-Meguro, Meguro-ku,
Tokyo 153-0064
Japan
0120 191014 or +81 3 5437 9125
[email protected]
Asia/Pacific:
Freescale Semiconductor China Ltd.
Exchange Building 23F
No. 118 Jianguo Road
Chaoyang District
Beijing 100022
China
+86 10 5879 8000
[email protected]
For Literature Requests Only:
Freescale Semiconductor Literature Distribution Center
P.O. Box 5405
Denver, Colorado 80217
1-800-441-2447 or +1-303-675-2140
Fax: +1-303-675-2150
[email protected]
Information in this document is provided solely to enable system and
software implementers to use Freescale Semiconductor products. There are
no express or implied copyright licenses granted hereunder to design or
fabricate any integrated circuits or integrated circuits based on the
information in this document.
Freescale Semiconductor reserves the right to make changes without further
notice to any products herein. Freescale Semiconductor makes no warranty,
representation or guarantee regarding the suitability of its products for any
particular purpose, nor does Freescale Semiconductor assume any liability
arising out of the application or use of any product or circuit, and specifically
disclaims any and all liability, including without limitation consequential or
incidental damages. “Typical” parameters that may be provided in Freescale
Semiconductor data sheets and/or specifications can and do vary in different
applications and actual performance may vary over time. All operating
parameters, including “Typicals”, must be validated for each customer
application by customer’s technical experts. Freescale Semiconductor does
not convey any license under its patent rights nor the rights of others.
Freescale Semiconductor products are not designed, intended, or authorized
for use as components in systems intended for surgical implant into the body,
or other applications intended to support or sustain life, or for any other
application in which the failure of the Freescale Semiconductor product could
create a situation where personal injury or death may occur. Should Buyer
purchase or use Freescale Semiconductor products for any such unintended
or unauthorized application, Buyer shall indemnify and hold Freescale
Semiconductor and its officers, employees, subsidiaries, affiliates, and
distributors harmless against all claims, costs, damages, and expenses, and
reasonable attorney fees arising out of, directly or indirectly, any claim of
personal injury or death associated with such unintended or unauthorized
use, even if such claim alleges that Freescale Semiconductor was negligent
regarding the design or manufacture of the part.
Freescale™ and the Freescale logo are trademarks of
Freescale Semiconductor, Inc. All other product or service names
are the property of their respective owners.
© Freescale Semiconductor, Inc. 2007 - 2009. All rights reserved.
MC33988
Rev. 4.0
11/2009