FREESCALE MCZ33742EGR2

Document Number: MC33742
Rev. 10.0, 5/2007
Freescale Semiconductor
Advance Information
System Basis Chip (SBC) with
Enhanced High-Speed CAN
Transceiver
33742
33742S
The 33742 and the 33742S are SPI-controlled System Basis Chips
(SBCs) combining many frequently used functions along with a CAN 2.0compliant transceiver, used in many automotive electronic control units
(ECUs). The 33742 SBC has a fully protected fixed 5.0 V low dropout
internal regulator with current limiting, overtemperature pre-warning, and
reset. A second 5.0 V regulator can be implemented using external pass
PNP bipolar junction pass transistor driven by the SBC’s external V2
sense input and V2 output drive pins.
The SBC has four main operating modes: Normal, Standby, Stop, and
Sleep mode. Additionally there is an internally switched high-side power
supply output, four wake-up inputs pins, a programmable window
watchdog, interrupt, reset, and a SPI module for communication and
control. The high-speed CAN A and B transceiver is available for intermodule communication.
Features
• 1.0 Mbps CAN Transceiver Bus Interface with Bus Diagnostic
Capability
• SPI Control at Frequencies up to 4.0 Mhz
• 5.0 V Low Dropout Voltage Regulator with Current Limiting,
Overtemperature Pre-Warning, and Output Monitoring and Reset
• A Second 5.0 V Regulator Capability using an External Series Pass
Transistor
• Normal, Standby, Stop, and Sleep Modes of Operation with Low Sleep
and Stop Mode Current
• A High-Side (HS) Switch Output Driver for Controlling External
Circuitry.
• Pb-Free Packaging Designated by Suffix Code EG and EP
SYSTEM BASIS CHIP
DW SUFFIX
EG SUFFIX (PB-FREE)
98ASB42345B
28-PIN SOICW
ORDERING INFORMATION
Device
Temperature
Range (TA)
MCZ33742EG/R2
MC33742SDW/R2
- 40°C to 125°C
PCZ33742EP/R2
48 QFN
CS
SCLK
MOSI
MISO
SPI
V2CTRL
V2
CS
SCLK
MOSI
MISO
L0
L1
L2
L3
WDOG
INT
TXD
RXD
GND
V2
VSUP
RST
MCU
HS
CANH
CANL
GND
VPWR
Safe Circuitry
ECU Local
Supply
Twisted
CAN Bus
Pair
Figure 1. 33742 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., 2007. All rights reserved.
28 SOICW
MCZ33742SEG/R2
33742
VDD
Package
MC33742DW/R2
VPWR
5.0 V
EP SUFFIX
(PB-FREE)
98ARH99048A
48-PIN QFN
DEVICE VARIATIONS
DEVICE VARIATIONS
Table 1. Device Differences During a Reset Condition
Part No.
Reset Duration
Device Differences
See Page
33742
15 ms (typical)
The duration the RST pin is asserted low when the Reset mode is entered after
the SBC is powered up and a VDD undervoltage condition is detected and the
watchdog register is not properly triggered.
page 19
33742S
3.5 ms (typical)
The duration the RST pin is asserted low when the Reset mode is entered after
the SBC is powered up and a VDD undervoltage condition is detected and the
watchdog register is not properly triggered.
page 19
33742
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Analog Integrated Circuit Device Data
Freescale Semiconductor
INTERNAL BLOCK DIAGRAM
INTERNAL BLOCK DIAGRAM
V2CTRL
V2
VSUP Monitor
Dual Voltage Regulator
VSUP
V1 Monitor
HS Control
5.0 V / 200 mA
V1
Mode Control
Oscillator
HS
Interrupt
Watchdog
Reset
L1
Programmable
Wake-Up Input
L2
L3
SPI
L4
CANH
High-Speed 1.0 Mbps
CAN Physical Interface
CANL
INT
WDOG
RST
MOSI
SCLK
MISO
CS
TXD
RXD
GND
Figure 2. 33742 Simplified Internal Block Diagram
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
3
PIN CONNECTIONS
PIN CONNECTIONS
RXD
TXD
VDD
1
28
2
27
3
26
RST
INT
4
25
5
24
GND
GND
GND
GND
V2
V2CTRL
VSUP
HS
L0
6
23
7
22
8
21
9
20
10
19
11
18
12
17
13
16
14
15
WDOG
CS
MOSI
MISO
SCLK
GND
GND
GND
GND
CANL
CANH
L3
L2
L1
Figure 3. 33742 28-Pin Connections
Table 2. 33742 28-Pin Definitions
A functional description of each pin can be found in the Functional Pin description section beginning on page 22.
Pin
Pin Name
Formal Name
Definition
1
RXD
Receive Data
CAN bus receive data output pin.
2
TXD
Transmit Data
CAN bus transmit data input pin.
3
VDD
Voltage Digital Drain
4
RST
Reset Output
(Active LOW)
This is the device reset output pin whose main function is to reset the MCU. This pin has
an internal pullup current source to VDD.
5
INT
Interrupt Output
(Active LOW)
This output is asserted LOW when an enabled interrupt condition occurs. The output is
a push-pull structure.
6–9
20 – 23
GND
Ground
These device ground pins are internally connected to the package lead frame to provide
a 33742-to-PCB thermal path.
10
V2
Voltage Source 2
Sense input for the V2 regulator using an external series pass transistor. V2 is also the
internal supply for the CAN transceiver.
11
V2CTRL
Voltage Source 2 Control
Output drive source for the V2 regulator connected to the external series pass transistor.
12
VSUP
Voltage Supply
13
HS
High-Side Output
Output of the internal high-side switch. The output current is internally limited to 150 mA.
14 –17
L0- L3
Level 0 - 3 Inputs
Inputs from external switches or from logic circuitry.
18
CANH
CAN High Output
CAN high output pin.
19
CANL
CAN Low Output
CAN low output pin.
24
SCLK
Serial Data Clock
Clock input pin for the Serial Peripheral Interface (SPI).
25
MISO
Master In Slave Out
SPI data sent to the MCU by the 33742. When CS is HIGH, the pin is in the highimpedance state.
26
MOSI
Master Out Slave In
SPI data received by the 33742.
27
CS
Chip Select
(Active LOW)
28
WDOG
Watchdog Output
(Active LOW)
5.0 V regulator output pin. Supply pin for the MCU.
Supply input pin for the 33742.
The CS input pin is used with the SPI bus to select the 33742. When the CS is asserted
LOW, the 33742 is the selected device of the SPI bus.
The WDOG output pin is asserted LOW if the software watchdog is not correctly
triggered.
33742
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Analog Integrated Circuit Device Data
Freescale Semiconductor
48
47
46
45
44
43
42
41
40
39
38
37
NC
NC
NC
NC
GND
GND
GND
GND
NC
NC
NC
NC
PIN CONNECTIONS
NC
SCLK
MISO
MOSI
CS
WDOG
RXD
NC
CANL
CANH
L3
L2
L1
L0
HS
VSUP
V2 CTRL
V2
NC
NC
NC
NC
NC
GND
GND
GND
GND
NC
NC
NC
NC
13
14
15
16
17
18
19
20
21
22
23
24
TXD
VDD
RST
INT
NC
36
35
34
33
32
31
30
29
28
27
26
25
1
2
3
4
5
6
7
8
9
10
11
12
Figure 4. 33742 48-Pin Connections
Table 3. 33742 48-Pin Definitions
A functional description of each pin can be found in the Functional Pin description section beginning on page 22.
Pin
Pin Name
Formal Name
Definition
1, 12-16,
21-25,
36-40,
45-48
NC
No Connect
2
SCLK
Serial Data Clock
3
MISO
Master In Slave Out
SPI data sent to the MCU by the 33742. When CS is HIGH, the pin is in the highimpedance state.
4
MOSI
Master Out Slave In
SPI data received by the 33742.
5
CS
Chip Select
(Active LOW)
6
WDOG
Watchdog Output
(Active LOW)
7
RXD
Receive Data
CAN bus receive data output pin.
8
TXD
Transmit Data
CAN bus transmit data input pin.
9
VDD
Voltage Digital Drain
10
RST
Reset Output
(Active LOW)
This is the device reset output pin whose main function is to reset the MCU. This pin has
an internal pullup current source to VDD.
11
INT
Interrupt Output
(Active LOW)
This output is asserted LOW when an enabled interrupt condition occurs. The output is
a push-pull structure.
17-20
41-44
GND
Ground
These device ground pins are internally connected to the package lead frame to provide
a 33742-to-PCB thermal path.
No connection.
Clock input pin for the Serial Peripheral Interface (SPI).
The CS input pin is used with the SPI bus to select the 33742. When the CS is asserted
LOW, the 33742 is the selected device of the SPI bus.
The WDOG output pin is asserted LOW if the software watchdog is not correctly
triggered.
5.0 V regulator output pin. Supply pin for the MCU.
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
5
PIN CONNECTIONS
Table 3. 33742 48-Pin Definitions (continued)
A functional description of each pin can be found in the Functional Pin description section beginning on page 22.
Pin
Pin Name
Formal Name
Definition
26
V2
Voltage Source 2
Sense input for the V2 regulator using an external series pass transistor. V2 is also the
internal supply for the CAN transceiver.
27
V2CTRL
Voltage Source 2 Control
28
VSUP
Voltage Supply
29
HS
High-Side Output
Output of the internal high-side switch. The output current is internally limited to 150 mA.
30-33
L0- L3
Level 0 - 3 Inputs
Inputs from external switches or from logic circuitry.
34
CANH
CAN High Output
CAN high output pin.
35
CANL
CAN Low Output
CAN low output pin.
Output drive source for the V2 regulator connected to the external series pass
transistor.
Supply input pin for the 33742.
33742
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Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
MAXIMUM RATINGS
ELECTRICAL CHARACTERISTICS
MAXIMUM RATINGS
Table 4. Maximum Ratings
All voltages are with respect to ground unless otherwise noted. Exceeding these ratings may cause a malfunction or
permanent damage to the device.
Rating
Symbol
Value
Unit
ELECTRICAL RATINGS
Power Supply Voltage at VSUP
VSUP
V
Continuous (Steady-State)
- 0.3 to 27
Transient Voltage (Load Dump)
- 0.3 to 40
Logic Signals
(RXD, TXD, MOSI, MISO, CS, SCLK, RST, WDOG, and INT)
VLOG
- 0.3 to VDD + 0.3
V
Output Voltage at VDD
VDD
0.0 to 5.3
V
Output Current at VDD
IDD
Internally Limited
A
Voltage
VHS
- 0.3 to VSUP + 0.3
V
Output Current
IHS
Internally Limited
A
HS
ESD Capability, Human Body Model (1)
VESD1
V
HS, L0, L1, L2, L3, CANH, CANL pins
± 4000
All Other pins
± 2000
ESD Capability, Machine Model (1)
VESD2
± 200
V
DC Input Voltage
VDCIN
- 0.3 to 40
V
DC Input Current
IDCIN
± 2.0
mA
VTRINEC
± 100
V
Continuous Voltage
VCANH/L
- 27 to 40
V
Continuous Current
ICANH/L
200
mA
CANH and CANL Transient Voltage (Load Dump) (3)
VLDH/L
40
V
CANH and CANL Transient Voltage (3)
VTRH/L
± 40
V
Input Voltage/Current at L0, L1, L2, L3
Transient Input Voltage attached to external circuitry (2)
CANL and CANH
Notes
1. Testing done in accordance with the Human Body Model (CZAP = 100 pF, RZAP = 1500 Ω), Machine Model (CZAP = 200 pF, RZAP = 0 Ω).
2.
3.
Testing done in accordance with ISO 7637-1. See Figure 5.
Load dump testing done in accordance with ISO 7637-1, Transient test done in accordance with ISO 7637-1. See Figure 6.
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
7
ELECTRICAL CHARACTERISTICS
MAXIMUM RATINGS
Table 4. Maximum Ratings (continued)
All voltages are with respect to ground unless otherwise noted. Exceeding these ratings may cause a malfunction or
permanent damage to the device.
Rating
Symbol
Value
Unit
Ambient
TA
- 40 to 125
Junction
TJ
- 40 to 150
Storage Temperature
TSTG
- 55 to 165
°C
Thermal Resistance
RθJG
20
°C/W
RTJC-RθJC
TBD
°C/W
PD
1.0
W
TPPRT
Note 7
°C
THERMAL RATINGS
Operating Temperature
°C
Thermal Resistance Junction Case (QFN)
(4)
Power Dissipation
Peak Package Reflow Temperature During Reflow (6), (7)
Notes
4. Maximum power dissipation is at 85°C ambient temperature in free aIr and with no heatsink, according to JEDEC JESD51-2 and
JESD51-3 specifications.
5. The package is not designed for immersion soldering. The maximum soldering time is 10 seconds at 240 °C on any pin. Exceeding the
maximum temperature and time limits may cause permanent damage to the device.
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.
33742
33742
1.0 nF
1.0 nF
Lx
10 kΩ
GND
Transient Pulse
Generator
(Note)
GND
Note Waveform per ISO 7637-1. Test Pulses 1, 2, 3a, and 3b.
Figure 5. Transient Test Setup for L0 : L3 Inputs
CANH
Transient Pulse
Generator
(Note)
CANL
GND
1.0 nF
GND
Note Waveform per ISO 7637-1. Test Pulses 1, 2, 3a, and 3b.
Figure 6. Transient Test Setup for CANH / CANL
33742
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Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 5. Static Electrical Characteristics
Characteristics noted under conditions 4.75 V ≤ V2 ≤ 5.25 V, 5.5 V ≤ VSUP ≤ 18 V, and -40°C ≤ TA ≤ 125°C. Typical values
noted reflect the approximate parameter mean at TA = 25°C under nominal conditions unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
5.5
—
18
18
—
27
Unit
INPUT PIN (VSUP)
Supply Voltage
VSUP
Nominal DC Voltage
Extended DC Voltage: Full Functionality (8)
(9)
V
4.5
—
5.5
Load Dump
—
—
40
Jump Start
—
—
27
Extended DC Voltage: Reduced Functionality
Supply Current in Standby Mode (10)
(IOUT at VDD = 40 mA, CAN Recessive or Sleep Mode)
ISUP(STDBY)
TA ≥ 25°C
mA
—
Supply Current in Normal Mode (10)
(IOUT at VDD = 40 mA, CAN Recessive or Sleep Mode)
mA
—
(13)
VSUP = 18 V, Oscillator Running (12)
Supply Current in Sleep Mode (10)
(V1 and V2 OFF, VSUP < 13.5 V, Oscillator Not Running (13), CAN in Sleep
Mode with Wake-Up Enabled)
TA = 25°C
TA = 125°C
Supply Current in Stop Mode
(IOUT at VDD < 2.0 mA, VDD ON, CAN in Sleep Mode with Wake-Up
Disabled (11))
VSUP < 13.5 V, Oscillator Running (12)
VSUP < 13.5 V, Oscillator Not Running (13)
VSUP = 18 V, Oscillator Running (12)
45
µA
—
85
—
53
105
80
—
110
140
µA
ISUP(SLP-WE)
TA = - 40°C
(10)
42
ISUP(SLP-WD)
VSUP < 13.5 V, Oscillator Running (12)
VSUP < 13.5 V, Oscillator Not Running
45
ISUP(NORM)
TA ≥ 25°C
Supply Current in Sleep Mode (10)
(VDD and V2 OFF, CAN in Sleep Mode with CAN Wake-Up Disabled (11))
42
—
80
—
—
65
—
—
55
—
µA
ISUP(STOP-WD)
—
—
160
—
80
160
—
100
210
Notes
8. All functions and modes available and operating: Watchdog, HS turn ON / turn OFF, CAN transceiver operating, L0 : L3 inputs operating,
normal SPI operation. The 33742 may experience an over temperature fault.
9. At VDD > 4.0 V, RST HIGH if reset 2 selected via SPI. The logic HIGH level will be degraded but the 33742 is functional.
10. Current measured at VSUP pin.
11. If CAN Module is Sleep-Enabled for wake-up, an additional current (ICAN-SLEEP) must be added to specified value.
12.
13.
Oscillator running means one of the following function is active: Forced Wake-Up or Cyclic Sense or Software Watchdog in Stop mode.
Oscillator not running means none of the following functions are active: Forced Wake-Up and Cyclic Sense and Software Watchdog in
Stop mode.
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
9
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 5. Static Electrical Characteristics (continued)
Characteristics noted under conditions 4.75 V ≤ V2 ≤ 5.25 V, 5.5 V ≤ VSUP ≤ 18 V, and -40°C ≤ TA ≤ 125°C. Typical values
noted reflect the approximate parameter mean at TA = 25°C under nominal conditions unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
INPUT PIN (VSUP) (CONTINUED)
Supply Current in Stop Mode (14)
( IOUT at VDD < 2.0 mA, VDD ON, VSUP < 13.5 V, Oscillator Not Running,
CAN in Sleep Mode with Wake-Up Enabled) (15)
TA = - 40°C
—
100
—
—
92
—
—
80
—
VBF
1.5
3.0
4.0
V
VBF(HYS)
—
1.0
—
V
5.3
5.8
6.3
TA = 25°C
TA = 125°C
BATFAIL Flag Internal Threshold
BATFAIL Flag Hysteresis
(16)
Battery Fall Early Warning Threshold
VBF(EW)
In Normal and Standby Modes
Battery Fall Early Warning Hysteresis
In Normal and Standby Modes
µA
ISUP(STOP-WE)
V
VBF(EW-HYST)
(16)
V
0.1
0.2
0.3
OUTPUT PIN (VDD) (17)
VDD Output Voltage (2.0 mA < IV1 < 200 mA)
VDDOUT
V
5.5 V < VSUP < 27 V
4.9
5.0
5.1
4.5 V < VSUP < 5.5 V
4.0
—
—
Dropout Voltage
VDDDRP1
IDD = 200 mA
Dropout Voltage, Limited Output Current and Low VSUP
—
VDDTEMP Bit Set
0.1
0.25
IDD
mA
200
285
350
160
—
200
125
—
160
TSD
Normal or Standby Mode
Overtemperature Pre-Warning (Junction)
0.5
V
—
Internally Limited
Thermal Shutdown (Junction)
0.2
VDDDRP2
IDD = 50 mA, 4.5 V < VSUP
Output Current
V
°C
TPW
°C
Notes
14. Current measured at VSUP pin.
15. Oscillator not running means none of the following functions are active: Forced Wake-Up and Cyclic Sense and Software Watchdog in
Stop mode.
16. Guaranteed by design; it is not production tested.
17. IDD is the total regulator output current. V1 specification with external capacitor. Stability requirement: Capacitance > 47 µF, ESR < 1.3 Ω
(tantalum capacitor). In Reset, Normal Request, Normal and Standby modes. Measures with capacitance = 47 µF tantalum.
33742
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Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 5. Static Electrical Characteristics (continued)
Characteristics noted under conditions 4.75 V ≤ V2 ≤ 5.25 V, 5.5 V ≤ VSUP ≤ 18 V, and -40°C ≤ TA ≤ 125°C. Typical values
noted reflect the approximate parameter mean at TA = 25°C under nominal conditions unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
TSD - TPW
20
—
40
°C
Threshold 1, Default Value after Reset, RSTTH Bit Set to Logic [0]
4.5
4.6
4.7
Threshold 2, RSTTH Bit Set to Logic [1]
4.0
4.2
4.3
1.0
—
VRSTTH
9.0 V < VSUP < 18 V
—
5.0
25
5.5 V < VSUP < 27 V
—
10
25
OUTPUT PIN (VDD) (CONTINUED) (18)
Temperature Threshold Difference
Reset Threshold
VRSTTH
VDD for Reset Active
VDDR
Line Regulation (IDD = 10 mA, Capacitance = 47 µF Tantalum at VDD)
VDDR
Load Regulation (Capacitance = 47 µF Tantalum at V1)
V
mV
VLD
1.0 mA < IDD < 200 mA
mV
—
25
75
—
30
50
IDD ≤ 2.0 mA
4.75
5.0
5.25
IDD ≤ 10 mA
4.75
5.0
5.25
10
17
25
Threshold 1, Default Value after Reset, RSTTH Bit Set to Logic [0]
4.5
4.6
4.7
Threshold 2, RSTTH Bit Set to Logic [1]
4.1
4.2
4.3
—
5.0
25
—
15
75
Thermal Stability
VTHERM-S
VSUP = 13.5 V, IDD = 100 mA (19)
V
mV
OUTPUT PIN IN STOP MODE (VDD) (18)
VDD Output Voltage
IDD Output Current to Wake-Up
Reset Threshold (18)
Line Regulation (Capacitance = 47 µF Tantalum at VDD)
VDDSTOP
IDDS-WU
VRST-STOP
1.0 mA < IDD < 10 mA
mA
V
VLR-STOP
5.5 V < VSUP < 27 V, IDD = 2.0 mA
Load Regulation (Capacitance = 47 µF Tantalum at V1)
V
mV
VLD-STOP
mV
Notes
18. IDD is the total regulator output current. VDD specification with external capacitor. Stability requirement: capacitance > 47 µF, ESR <
1.3 Ω (tantalum capacitor). In Reset, Normal Request, Normal and Standby modes, measures with capacitance = 47 µF
tantalum.Selectable by RSTTH bit in SPI Register Reset Control Register (RCR).
19. Guaranteed by characterization and design; it is not production tested.
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
11
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 5. Static Electrical Characteristics (continued)
Characteristics noted under conditions 4.75 V ≤ V2 ≤ 5.25 V, 5.5 V ≤ VSUP ≤ 18 V, and -40°C ≤ TA ≤ 125°C. Typical values
noted reflect the approximate parameter mean at TA = 25°C under nominal conditions unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
0.99
1.0
1.01
200
—
—
0.0
—
10
3.75
4.0
4.25
0.0
—
1.0
Unit
TRACKING VOLTAGE REGULATOR (V2) (20)
V2 Output Voltage (Capacitance = 10 µF Tantalum at V2)
V2
2.0 mA ≤ IV2 ≤ 200 mA, 5.5 V < VSUP < 27 V
IV2 Output Current (for Information Only)
IV2
Depending on External Ballast Transistor
V2 Control Drive Current Capability (21)
mA
IV2CTRL
Worst Case at TJ = 125°C
V2LOW Flag Threshold
VDD
V2LTH
mA
V
LOGIC OUTPUT PIN (MISO) (22)
Low-Level Output Voltage
VOL
IOUT = 1.5 mA
High-Level Output Voltage
VOH
IOUT = -250 µA
Tri-Stated MISO Leakage Current
0 V < VMISO < VDD
V
V
VDD - 0.9
—
VDD
µA
IHZ
- 2.0
—
2.0
Notes
20. V2 specification with external capacitor. Stability requirement: capacitance > 42 µF and ESR < 1.3 Ω (tantalum capacitor), external
resistor between base and emitter required. Measurement conditions: ballast transistor MJD32C, capacitance > 10 µF tantalum, 2.2 kΩ
resistor between base and emitter of ballast transistor.
21. The guaranteed V2CTRL current capability is 10 mA. No active current limiting is used so the actual available current may be higher.
22. Push-pull structure with tri-state condition (CS HIGH).
33742
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Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 5. Static Electrical Characteristics (continued)
Characteristics noted under conditions 4.75 V ≤ V2 ≤ 5.25 V, 5.5 V ≤ VSUP ≤ 18 V, and -40°C ≤ TA ≤ 125°C. Typical values
noted reflect the approximate parameter mean at TA = 25°C under nominal conditions unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
High-Level Input Voltage
VIH
0.7 VDD
—
VDD + 0.3
V
Low-Level Input Voltage
VIL
- 0.3
—
0.3 VDD
V
High-Level Input Current on CS
I IH
LOGIC INPUT PINS (MOSI, SCLK, CS)
VIN = 4.0 V
Low-Level Input Current on CS
-100
—
- 20
µA
I IL
VIN = 1.0 V
MOSI and SCLK Input Current
µA
-100
—
- 20
µA
I IN
0 V < VIN < VDD
-10
—
10
- 300
- 250
-150
IO = 1.5 mA, 5.5 V < VSUP < 27 V
0.0
—
0.9
IO = 0 mA, 1.0 V <VSUP < 5.5 V
0.0
—
0.9
2.3
—
5.0
0.0
—
0.9
VDD - 0.9
—
VDD
0.0
—
0.9
VDD - 0.9
—
VDD
OUTPUT PIN (RST) (23)
High-Level Output Current
Low-Level Output Voltage
RST Pulldown Current
µA
IOH
0 V < VOUT < 0.7 VDD
VOL
V
IPDW
V > 0.9 V
mA
OUTPUT PIN (WDOG) (24)
Low-Level Output Voltage
VOL
IO = 1.5 mA, 1.0 V < VSUP < 27 V
High-Level Output Voltage
V
VOH
IO = -250 µA
V
OUTPUT PIN (INT) (24)
Low-Level Output Voltage
VOL
IO = 1.5 mA
High-Level Output Voltage
V
VOH
IO = -250 µA
V
Notes
23. Output pin only. Supply from VDD. Structure switch to ground with pullup current source.
24. Push-pull structure.
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
13
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 5. Static Electrical Characteristics (continued)
Characteristics noted under conditions 4.75 V ≤ V2 ≤ 5.25 V, 5.5 V ≤ VSUP ≤ 18 V, and -40°C ≤ TA ≤ 125°C. Typical values
noted reflect the approximate parameter mean at TA = 25°C under nominal conditions unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
TA = 25°C, IOUT - 150 mA, VSUP > 9.0 V
—
2.0
2.5
TA = 125°C, IOUT - 150 mA, VSUP > 9.0 V
—
—
4.5
TA = 125°C, IOUT - 120 mA, 5.5 V < VSUP < 9.0 V
—
3.5
5.5
160
—
500
TSD
155
—
190
°C
ILEAK
—
—
10
µA
OUTPUT PIN (HS)
Driver Output ON Resistance
Output Current Limitation
ILIM
VSUP - VHS > 1.0 V
HS Thermal Shutdown
HS Leakage Current
Output Clamp Voltage
Ω
RDS(ON)
mA
VCL
IOUT = -10 mA, No Inductive Load Drive Capability
V
-1.5
—
- 0.3
5.5 V < VSUP < 6.0 V
2.0
2.5
3.0
6.0 V < VSUP < 18 V
2.5
3.0
3.6
18 V < VSUP < 27 V
2.7
3.2
3.7
5.5 V < VSUP < 6.0 V
2.7
3.3
3.8
6.0 V < VSUP < 18 V
3.0
4.0
4.6
18 V < VSUP < 27 V
3.5
4.2
4.7
0.6
—
1.3
-10
—
10
INPUT PINS (L0, L1, L2, AND L3)
Low-Voltage Detection Threshold
High-Voltage Detection Threshold
Hysteresis
VTHL
VTHH
V
VHYS
5.5 V < VSUP < 27 V
Input Current
V
V
µA
I IN
- 0.2 V < VIN < 40 V
CAN TRANSCEIVER CURRENT
Supply Current of CAN Module
CAN in Normal Mode, Bus Recessive State
IRES
—
1.3
3.0
mA
CAN in Normal Mode, Bus Dominant State without Bus Load
IDOM
—
1.5
3.5
mA
ICAN-SLEEP
—
12
24
µA
IDIS
—
—
1.0
µA
CAN in Sleep State, Wake-Up Enabled, V2 Regulator OFF
CAN in Sleep State, Wake-Up Disabled, V2 Regulator OFF (25)
Notes
25. Guaranteed by design; it is not production tested.
33742
14
Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 5. Static Electrical Characteristics (continued)
Characteristics noted under conditions 4.75 V ≤ V2 ≤ 5.25 V, 5.5 V ≤ VSUP ≤ 18 V, and -40°C ≤ TA ≤ 125°C. Typical values
noted reflect the approximate parameter mean at TA = 25°C under nominal conditions unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
VCM
- 27
—
40
V
Recessive State at RXD
—
—
500
Dominant State at RXD
900
—
—
VHYS
100
—
—
mV
Input Resistance
RIN
5.0
—
100
kΩ
Differential Input Resistance
RIND
10
—
100
kΩ
TXD Dominant State
2.75
—
4.5
TXD Recessive State
—
—
3.0
TXD Dominant State
0.5
—
2.25
TXD Recessive State
2.0
—
—
TXD Dominant State
1.5
—
3.0
V
TXD Recessive State
—
—
100
mV
PINS (CANH AND CANL)
Bus Pin Common Mode Voltage
Differential Input Voltage (Common Mode Between - 3.0 V and 7.0 V)
Differential Input Hysteresis (RXD)
CANH Output Voltage
VCANH - VCANL
mV
VCANH
CANL Output Voltage
V
VCANL
Differential Output Voltage
V
VoH - VoL
Output Current Capability (Dominant State)
mA
CANH
ICANH
—
—
- 35
CANL
ICANL
35
—
—
TSD
160
180
—
CANL
ICANL /OC
60
—
200
CANH
ICANH /OC
- 200
—
- 60
Overtemperature Shutdown
CANL Overcurrent Detection
(26)
CANH and CANL Input Current, Device Supplied
(CAN Sleep Mode with CAN Wake-Up Enabled or Disabled)
mA
µA
ICAN1
VCANH, VCANL from 0 V to 5.0 V
—
3.0
VCANH, VCANL = - 2.0 V
- 60
- 50
—
VCANH, VCANL = 7.0 V
—
60
75
CANH and CANL Input Current, Device Unsupplied
°C
10
µA
ICAN2
VCANH, VCANL = 2.5 V
—
40
VCANH, VCANL = - 2.0 V
- 60
- 50
—
VCANH, VCANL = 7.0 V
—
190
240
100
Notes
26. Reported in CAN register. For a description of the contents of the CAN register, refer to CAN Register (CAN) on page 44
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
15
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 5. Static Electrical Characteristics (continued)
Characteristics noted under conditions 4.75 V ≤ V2 ≤ 5.25 V, 5.5 V ≤ VSUP ≤ 18 V, and -40°C ≤ TA ≤ 125°C. Typical values
noted reflect the approximate parameter mean at TA = 25°C under nominal conditions unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
CANL to GND Threshold
VLG
—
1.75
—
V
CANH to GND Threshold
VHG
—
1.75
—
V
CANL to VSUP Threshold
VLVB
—
VSUP - 2.0
—
V
CANH to VSUP Threshold
VHVB
—
VSUP - 2.0
—
V
CANL to VDD Threshold
VL5
—
VDD - 0.43
—
V
CANH to VDD Threshold
VH5
—
VDD - 0.43
—
V
—
100
—
DIAGNOSTIC INFORMATION (CANH AND CANL)
RXD Weak Pull-down Current Source (27)
µA
IRXDW
RXD Permanent Dominant Failure Condition
PINS (TXD AND RXD)
TXD Input High Voltage
VIH
0.7 VDD
—
VDD + 0.4
V
TXD Input Low Voltage
VIL
- 0.4
—
0.3 VDD
V
TXD High-Level Input Current
IIH
-10
—
10
-150
- 100
- 50
VDD - 1.0
—
—
—
—
0.5
VTXD = V2
TXD Low-Level Input Current
VOH
IRXD = 250 µA
RXD Output Low Voltage
IRXD = 1.0 mA
µA
IIL
VTXD = 0 V
RXD Output High Voltage
µA
V
VOL
V
Notes
27. Guaranteed by design; it is not production tested.
33742
16
Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
DYNAMIC ELECTRICAL CHARACTERISTICS
DYNAMIC ELECTRICAL CHARACTERISTICS
Table 6. Dynamic Electrical Characteristics
Characteristics noted under conditions 4.75 V ≤ V2 ≤ 5.25 V, 5.5 V ≤ VSUP ≤ 18 V, and -40°C ≤ TA ≤ 125°C. Typical values
noted reflect the approximate parameter mean at TA = 25°C under nominal conditions unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
SPI Operation Frequency
f REQ
0.25
—
4.0
MHz
SCLK Clock Period
t PCLK
250
—
N/A
ns
SCLK Clock High Time
t WSCLKH
125
—
N/A
ns
SCLK Clock Low Time
t WSCLKL
125
—
N/A
ns
Falling Edge of CS to Rising Edge of SCLK
t LEAD
100
—
N/A
ns
Falling Edge of SCLK to Rising Edge of CS
t LAG
100
—
N/A
ns
MOSI to Falling Edge of SCLK
t SISU
40
—
N/A
ns
Falling Edge of SCLK to MOSI
t SIH
40
—
N/A
ns
DIGITAL INTERFACE TIMING (SCLK, CS, MOSI, MISO) (28)
MISO Rise Time
(29)
t RSO
CL = 220 pF
MISO Fall Time
(29)
ns
—
25
50
—
25
50
—
—
50
—
—
50
t FSO
CL = 220 pF
ns
Time from Falling or Rising Edges of CS
MISO Low Impedance
MISO High Impedance
Time from Rising Edge of SCLK to MISO Data Valid
ns
t SOEN
t SODIS
t VALID
0.2 VDD ≤ MISO ≥ 0.8 VDD, CL = 200 pF
ns
—
—
50
18
—
34
7.0
10
13
—
100
—
Period 1
8.58
9.75
10.92
Period 2
39.6
45
50.4
Period 3
88
100
112
Period 4
308
350
392
STATE MACHINE TIMING (CS, SCLK, MOSI, MISO, WDOG, INT)
Delay Between CS LOW-to-HIGH Transition (at End of SPI Stop Command)
and Stop Mode Activation (30)
Interrupt Low-Level Duration
t CS-STOP
t INT
Stop Mode
Internal Oscillator Frequency (31)
Watchdog Period Normal and Standby Modes
Notes
28.
29.
30.
31.
µs
f OSC
µs
t WDOG
kHz
ms
See Figure 7, SPI Timing Diagram, page 21.
Not production tested. Guaranteed by design.
Not production tested. Guaranteed by design. Detected by V2 OFF.
f OSC is indirectly measured (1.0 ms reset) and trimmed.
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
17
ELECTRICAL CHARACTERISTICS
DYNAMIC ELECTRICAL CHARACTERISTICS
Table 6. Dynamic Electrical Characteristics (continued)
Characteristics noted under conditions 4.75 V ≤ V2 ≤ 5.25 V, 5.5 V ≤ VSUP ≤ 18 V, and -40°C ≤ TA ≤ 125°C. Typical values
noted reflect the approximate parameter mean at TA = 25°C under nominal conditions unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
308
350
392
Unit
STATE MACHINE TIMING (CS, SCLK, MOSI, MISO, WDOG, INT) (CONTINUED)
Normal Request Mode Timeout
t NRTOUT
Normal Request Mode
Watchdog Period Stop Mode
ms
t WD-STOP
ms
Period 1
6.82
9.75
12.7
Period 2
31.5
45
58.5
Period 3
70
100
130
Period 4
245
350
455
Normal and Standby Modes
-12
—
12
Stop Mode
- 30
—
30
Timing 1
3.22
4.6
5.98
Timing 2
6.47
9.25
12
Timing 3
12.9
18.5
24
Timing 4
25.9
37
48.1
Timing 5
51.8
74
96.2
Timing 6
66.8
95.5
124
Timing 7
134
191
248
Timing 8
271
388
504
200
350
500
- 30
—
30
—
—
Watchdog Period Accuracy
Cyclic Sense / FWU Timing Sleep and Stop Modes
Cyclic Sense ON Time
t ACC
t CSFWU
µs
t ACC
Sleep and Stop Modes
Delay Between SPI Command and HS Turn ON (32)
ms
t ON
Sleep and Stop Modes.
Cyclic Sense / FWU Timing Accuracy
%
t S-HSON
%
Delay Between SPI Command and HS Turn OFF (32)
t S-HSOFF
—
22
t S-V2ON
Standby Mode
Delay Between SPI and V2 Turn OFF (32)
Command (32)
Normal Request Mode
µs
9.0
—
22
9.0
—
22
t S-V2OFF
Normal Mode
Delay Between Normal Request and Normal Mode After Watchdog Trigger
µs
—
Normal or Standby Mode, VSUP > 9.0 V
Delay Between SPI and V2 Turn ON (32)
µs
22
Normal or Standby Mode, VSUP > 9.0 V
µs
t S-NR2N
µs
15
35
70
Notes
32. Delay starts at falling edge of clock cycle #8 of the SPI command and start of “Turn ON” or “Turn OFF” of HS or V2.
33742
18
Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
DYNAMIC ELECTRICAL CHARACTERISTICS
Table 6. Dynamic Electrical Characteristics (continued)
Characteristics noted under conditions 4.75 V ≤ V2 ≤ 5.25 V, 5.5 V ≤ VSUP ≤ 18 V, and -40°C ≤ TA ≤ 125°C. Typical values
noted reflect the approximate parameter mean at TA = 25°C under nominal conditions unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
—
—
10
—
—
10
Unit
STATE MACHINE TIMING (CS, SCLK, MOSI, MISO, WDOG, INT) (CONTINUED)
Delay Between SPI and CAN Normal Mode (33)
t S-CAN_N
Normal Mode (34)
Delay Between SPI and CAN Sleep Mode (33)
Normal Mode
t S-CAN_S
(34)
Delay Between CS Wake-Up (CS LOW to HIGH) and Device in Normal
Request Mode (VDD ON and RST HIGH)
µs
µs
t W-CS
Stop Mode
µs
15
Delay Between CS Wake-Up (CS LOW to HIGH) and First Accepted SPI
Command
µs
90
—
N/A
20
—
N/A
25
—
—
t S-1STSPI
Device in Stop Mode After Wake-Up
Delay Between Two SPI Messages Addressing the Same Register
90
t W-SPI
Device in Stop Mode After Wake-Up
Delay Between INT Pulse and First SPI Command Accepted
40
t 2SPI
µs
µs
OUTPUT PIN (VDD)
Reset Delay Time
µs
tD
Measured at 50% of Reset Signal
4.0
—
30
tIDD-DGLT
40
55
75
33742
t RSTDUR
12
15
18
33742S
t RSTDURS
3.0
3.5
4.0
t WUF
8.0
20
38
IDD Overcurrent to Wake-Up Deglitcher Time
(34)
µs
OUTPUT PIN (RST)
Reset Duration After VDD HIGH
ms
INPUT PINS (L0, L1, L2, AND L3)
Wake-Up Filter Time
µs
Notes
33. Delay starts at falling edge of clock cycle #8 of the SPI command and start of “Turn ON” or “Turn OFF” of HS or V2.
34. Guaranteed by design; it is not production tested.
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
19
ELECTRICAL CHARACTERISTICS
DYNAMIC ELECTRICAL CHARACTERISTICS
Table 6. Dynamic Electrical Characteristics (continued)
Characteristics noted under conditions 4.75 V ≤ V2 ≤ 5.25 V, 5.5 V ≤ VSUP ≤ 18 V, and -40°C ≤ TA ≤ 125°C. Typical values
noted reflect the approximate parameter mean at TA = 25°C under nominal conditions unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
t DOUT
200
360
520
µs
Slew Rate 3
60
100
210
Slew Rate 2
70
110
225
Slew Rate 1
80
130
255
Slew Rate 0
110
200
310
Slew Rate 3
20
65
110
Slew Rate 2
25
80
150
Slew Rate 1
35
100
200
Slew Rate 0
50
160
300
10
50
140
CAN MODULE – SIGNAL EDGE RISE AND FALL TIMES (CANH, CANL)
Dominant State Timeout
Propagation Loop Delay TXD to RXD (Recessive to Dominant) (35)
Propagation Delay TXD to CAN (Recessive to Dominant) (36)
t LRD
ns
t TRD
Propagation Delay CAN to RXD (Recessive to Dominant) (37)
t RRD
Propagation Loop Delay TXD to RXD (Dominant to Recessive) (35)
t LDR
ns
ns
Slew Rate 3
100
150
200
Slew Rate 2
120
165
220
Slew Rate 1
140
200
250
Slew Rate 0
250
340
410
Slew Rate 3
60
125
150
Slew Rate 2
65
150
190
Slew Rate 1
75
180
250
200
310
460
t RDR
20
30
60
t SL3
t SL2
t SL1
t SL0
4.0
19
40
3.0
13.5
20
2.0
8.0
15
1.0
5.0
10
tBUS
60k
—
1.0M
Propagation Delay TXD to CAN (Dominant to Recessive) (36)
t TDR
Slew Rate 0
Propagation Delay CAN to RXD (Dominant to Recessive)
(37)
ns
Non-Differential Slew Rate (CANL or CANH)
Slew Rate 3
Slew Rate 2
Slew Rate 1
Slew Rate 0
Bus Communication Rate
ns
ns
V/µs
bps
Νοτεσ
35. See Figure 8, page 21.
36. See Figure 9, page 21.
37. See Figure 10, page 21.
33742
20
Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
TIMING DIAGRAMS
TIMING DIAGRAMS
t PCLK
CS
t WSCLKH
t LEAD
t LAG
SCLK
t WSCLKL
t SIH
t SISU
MOSI
Undefined
DI 8
Don’t Care
DI 0
Don’t Care
t VALID
t SODIS
t SOEN
MISO
DO 0
DO 8
Note Incoming data at MOSI pin is sampled by the 33742 at SCLK falling edge. Outgoing data at MISO pin
is set by the 33742 at SCLK rising edge (after t VALID delay time).
Figure 7. SPI Timing Diagram
tLRD
TXD
tTRD
TXD
0.8 V
2.0 V
2.0 V
tTDR
0.8 V
tLDR
0.9 V
VDIFF
0.5 V
2.0 V
RXD
VDIFF = VCANH - VCANL
0.8 V
Figure 9. Propagation Delay TXD to CAN
Figure 8. Propagation Loop Delay TXD to RXD
tRDR
0.9 V
VDIFF
tRRD
0.5 V
2.0 V
RXD
0.8 V
Figure 10. Propagation Delay CAN to RXD
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
21
FUNCTIONAL DESCRIPTION
INTRODUCTION
FUNCTIONAL DESCRIPTION
INTRODUCTION
The 33742 and the 33742S are system basis chips (SBCs)
dedicated to automotive applications. Their functions include
the following:
• One fully protected 5.0 V voltage regulator with 200 mA
total output current capability available at the VDD pin.
• VDD regulator undervoltage reset function,
programmable window or time-out software watchdog
function.
• Internal driver (V2) for an external series pass transistor
to implement a second 5.0 V voltage regulator.
• Two running modes: Normal and Standby modes set by
the system microcontroller.
• Sleep and Stop modes low power operating modes to
reduce an application’s current consumption while
providing a wake-up capability from the CAN interface,
L3 : L0 wake-up inputs, or from a timer wake-up.
• Programmable wake-up input and cyclic sense wakeups.
• CAN high-speed physical bus interface with TXD and
RXD fault diagnostic capability and enhanced
protection features.
• An SPI interface for use in communicating with a MCU
and Interrupt outputs to report SBC status, perform
diagnostics, and report wake-up events.
FUNCTIONAL PIN DESCRIPTION
RECEIVE AND TRANSMIT DATA (RXD AND TXD)
VOLTAGE SOURCE 2 (V2)
The RXD and TXD pins (receive data and transmit data
pins, respectively) are connected to a microcontroller’s CAN
protocol handler. TXD is an input and controls the CANH and
CANL line state (dominant when TXD is LOW, recessive
when TXD is HIGH). RXD is an output and reports the bus
state (RXD LOW when CAN bus is dominant, HIGH when
CAN bus is recessive).
The V2 pin is the input sense for the V2 regulator. It is
connected to the external series pass transistor. V2 is also
the 5.0 V supply of the internal CAN interface. It is possible to
connect V2 to an external 5.0 V regulator or to the VDD
output when no external series pass transistor is used. In this
case, the V2CTRL pin must be left open. Refer to Figure 31,
SBC Typical Application Schematic, page 52.
Voltage Digital Drain (VDD)
VOLTAGE SOURCE 2 CONTROL (V2CTRL)
The VDD pin is the output pin of the 5.0 V internal
regulator. It can deliver up to 200 mA. This output is protected
against overcurrent and overtemperature. It includes an
overtemperature pre-warning flag, which is set when the
internal regulator temperature exceeds 130°C typical. When
the temperature exceeds the overtemperature shutdown
(170°C typical), the regulator is turned off.
VDD includes an undervoltage reset circuitry, which sets
the RST pin LOW when VDD is below the undervoltage reset
threshold.
The V2CTRL pin is the output drive pin for the V2 regulator
connected to the external series pass transistor.
RESET OUTPUT (RST)
The Reset pin RST is an output that is set LOW when the
device is in reset mode. The RST pin is set HIGH when the
device is not in reset mode. RST includes an internal pullup
current source. When RST is LOW, the sink current capability
is limited, allowing RST to be shorted to 5.0 V for software
debug or software download purposes.
INTERRUPT OUTPUT (INT)
The Interrupt pin INT is an output that is set LOW when an
interrupt occurs. INT is enabled using the Interrupt Register
(INTR). When an interrupt occurs, INT stays LOW until the
interrupt source is cleared.
INT output also reports a wake-up event by a 10 µs typical
pulse when the device is in Stop mode.
VOLTAGE SUPPLY (VSUP)
The VSUP pin is the battery supply input of the device.
HIGH-SIDE OUTPUT (HS)
The HS pin is the internal high-side driver output. It is
internally protected against overcurrent and
overtemperature.
LEVEL 0-3 INPUTS (L0: L3)
The L0 : L3 pins can be connected to contact switches or
the output of other ICs for external inputs. The input states
can be read by SPI. These inputs can be used as wake-up
events for the SBC when operating in the Sleep or Stop
mode.
CAN HIGH AND CAN LOW OUTPUTS
(CANH AND CANL)
The CAN High and CAN Low pins are the interfaces to the
CAN bus lines. They are controlled by TXD input level, and
the state of CANH and CANL is reported through RXD output.
A 60 Ω termination resistor is connected between CANH and
CANL pins.
33742
22
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DESCRIPTION
FUNCTIONAL PIN DESCRIPTION
SERIAL DATA CLOCK (SCLK)
MASTER OUT SLAVE IN (MOSI)
SCLK is the Serial Data Clock input pin of the serial
peripheral interface.
MOSI is the Master Out Slave In pin of the serial peripheral
interface. Control data from a microcontroller is received
through this pin.
MASTER IN SLAVE OUT (MISO)
MISO is the Master In Slave Out pin of the serial peripheral
interface. Data is sent from the SBC to the microcontroller
through the MISO pin.
CHIP SELECT (CS)
CS is the Chip Select pin of the serial peripheral interface.
When this pin is LOW, the SPI port of the device is selected.
WATCHDOG OUTPUT (WDOG)
The Watchdog output pin is asserted LOW to flag that the
software watchdog has not been properly triggered.
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
23
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
FUNCTIONAL DEVICE OPERATION
SUPPLY VOLTAGE AT VSUP
The 33742 receives its operating voltage via the VSUP
pin. An external diode is needed in series with the VSUP pin
and the supply voltage to protect the SBC against negative
transients or from a reverse battery situation that can occur in
a vehicle application. The 33742 will operate from a supply
voltage input as low as 4.5 VDC to as high as 27 VDC. The
later voltage is often encountered during a vehicle jump-start.
The VSUP pin can tolerate automotive transient conditions
such as load dump to 40 V. The SBC is able to detect when
VSUP falls below 3.0 V typical. This undervoltage state is
detected and retained in the parts Mode Control Register
(MCR) as the BATFAIL bit. This detection capability is
available across all operating modes.
Note For a detailed description of all the registers
mentioned in this section, refer to the section titled SPI
Interface And Register Description beginning on page 42.
The SBC incorporates a VSUP level early warning function,
which provides a maskable interrupt if the VSUP voltage level
falls below 6.0 V typical. Hysteresis is used to reduce false
detections. The early warning function works only in Normal
and Standby operation modes. An undervoltage at the VSUP
pin is reported in the Input / Output Register (IOR).
VDD REGULATOR
The VDD regulator provides a 5.0 V low dropout voltage
capable of supplying up to 200 mA with monitoring circuitry
for undervoltage detection and a reset function. The VDD
regulator is protected against overcurrent and short circuit
conditions. It has overtemperature detection and will set
warning flags (bit VDDTEMP in the MCR and INTR registers)
and has overtemperature shutdown with hysteresis.
V2 REGULATOR
The V2 regulator feature provides for a second 5.0 VDC
voltage source The internal V2 circuitry will drive an external
series pass transistor, substantially increasing the available
supply current. Two pins, the V2 and the V2CTRL, are used
to sense and drive the series pass transistor. The output
voltage is 5.0 V and tracks the VDD regulator. The MJD32C
transistor is recommended for use as the external pass
device. Other PNP transistors can be used but depending on
the device’s gain, an external resistor-capacitor network
might be needed. V2 is also the supply voltage for the onboard CAN module. An undervoltage condition for the V2
voltage is reported in the IOR Register (bit V2LOW set to
logic [1] if V2 falls below 4.0 V typical).
HS VSUP SWITCH OUTPUT
The HS output is a 2.0 Ω typical switch tied to the VSUP
pin. It can power or bias external switches and their
associated pullup or put-downs or other circuitry. An example
is biasing a set of switches connected to the L0 : L3 wake-up
input pins. The HS VSUP output current is limited to 200 mA
and is protected against short circuits conditions and will
report an overtemperature shutdown condition (bit HSOT in
the IOR register and bit HSOT - V2LOW in the INTR register).
The HS output “on” state is set by the HSON bit in the IOR
register. A cyclic mode of operation can be implemented
using an internal timer in the Sleep and Stop operating
modes. It can also be turned on in Normal or Standby modes
to drive loads or supply peripheral components. No internal
protection circuitry is provided, however. Dedicated chip
protection circuitry is required for inductive load applications.
The HS output pin should not go below - 0.3 V.
BATTERY FAIL EARLY WARNING
Refer to the discussion under the heading, Supply Voltage
at VSUP above.
INTERNAL CLOCK
The 33742 has an internal clock used to generate all
timings (reset, watchdog, cyclic wake-up, filtering time, etc.).
There are two on-board oscillators;: a higher accuracy (±12
percent) oscillator used in Normal Request, Normal, and
Standby modes,; and a lower accuracy (±30 percent)
oscillator used during Sleep and Stop modes.
OPERATIONAL MODES
INTRODUCTION
STANDBY MODE
The 33742 has four modes of operation, all controllable via
the SPI. The modes are Standby, Normal, Stop, and Sleep.
An additional temporary mode called Normal Request mode
is automatically accessed by the device after reset or wakeup from Stop mode. A Reset mode is also implemented.
Special modes and configurations are possible for debug and
program microcontroller flash memory.
Table 7, page 25, offers a summary of the functional
modes.
In Standby mode only the VDD regulator is ON. The V2
regulator is turned OFF by disabling the V2CTRL pin. Other
functions available are the L0 : L3 inputs read through via the
SPI and HS output activation.
The CAN interface is not able to send messages. If a CAN
message is received, the CANWU bit is set. The watchdog
timer is running.
33742
24
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
NORMAL MODE
RESET MODE
In Normal mode, both the VDD and V2 regulators are in the
ON state. All functions are available in this operating mode
(watchdog, wake-up input reading through SPI, HS
activation, and CAN communication). The watchdog timer is
running and must be periodically cleared through SPI.
In the Reset mode, the RST pin is LOW and a timer runs
for t RSTDUR time. After t RSTDUR has elapsed, the 33742
enters the Normal Request operating mode. The Reset mode
is entered if a reset condition occurs (VDD LOW, watchdog
time-out, or watchdog trigger in a closed window).
STOP MODE
NORMAL REQUEST MODE
The V2 regulator is turned OFF by disabling the V2CTRL
pin. The VDD regulator is activated in a special low power
mode supplying only a few mA of current. This maintains
“keep alive” power for the application’s MCU while the MCU
is in a power-saving state (i.e., a MCU’s version of Stop or
Wait). In the Stop mode, the supply current available from
VSUP pin is very low.
Both parts (the SBC or the MCU) can be awakened from
either the 33742 side (for example, cyclic sense, forced
wake-up, CAN message, wake-up inputs, and overcurrent on
VDD) or from the MCU side (key wake-up, etc.).
Stop mode is always selected via SPI. In Stop mode, the
watchdog software may be either running or not running
depending upon selection by SPI (Reset Control Register
[RCR], bit WDSTOP). To clear a running watchdog timer, the
SBC must be awakened using the CS pin (SPI wake-up). In
Stop mode, wake-up is identical to that in Sleep mode, with
the addition of CS and VDD overcurrent wake-up. Refer to
Table 7, page 25.
The Normal Request mode is a temporary operating mode
automatically entered by the SBC after the Reset mode or
after the 33742 wakes up from the Stop mode.
After a wake-up from the Sleep mode or after a device
power-up, the SBC enters the Reset mode prior to entering
the Normal Request mode. After a wake-up from the Stop
mode, the 33742 enters the Normal Request mode directly.
In Normal Request mode, the VDD regulator is ON, the V2
regulator is OFF, and the RST pin is HIGH. As soon as the
SBC enters the Normal Request mode, an internal 350 ms
timer is started (parameter tNRTOUT). During this time, the
application’s MCU must address the 33742 via SPI and
configure the TIM1 sub register to select the watchdog
period. This is required of the SBC to stop the 350 ms
watchdog timer and enter the Normal or Standby mode and
to set the watchdog timer configuration.
SLEEP MODE
In Sleep mode, the VDD and V2 regulators are OFF.
Current consumption from the VSUP pin is cut. In Sleep
mode, the SBC can be awakened by sensing individual level
individual level changes in the L0 : L3 inputs, by cyclic
checking of the L0 : L3 inputs, by the forced wake-up timer, or
from the CAN physical interface upon receiving a CAN
message. When a wake-up occurs, the SBC goes first into
the Reset mode before entering Normal Request mode.
NORMAL REQUEST ENTERED AND NO
WATCHDOG CONFIGURATION OCCURS
If the Normal Request mode is entered after the SBC
powers up or after a wake-up from Stop mode and no
watchdog configuration occurs before the 350 ms time period
has expired, the device enters the Reset mode. If no
watchdog configuration is performed, the 33742 will cycle
from the Normal Request mode to Reset mode to Normal
Request mode.
If the Normal Request mode is entered after a wake-up
from Sleep mode, and no watchdog configuration occurs
while the 33742S is in Normal Request mode, the SBC
returns to the Sleep mode.
Table 7. Table of Operations
Mode
Voltage Regulator
HS Switch
Wake-Up
Capabilities
(if Enabled)
RST Pin
INT Pin
Watchdog
Software
CAN Cell
–
–
–
Running
TXD / RXD
Running
Low power
Normal
Request
VDD: ON,
V2: OFF,
HS: OFF
–
Low for t RSTDUR time,
then HIGH
Normal
VDD: ON,
V2: ON,
HS: Controllable
–
Normally HIGH.
If enabled, signal
Active LOW if WDOG
failure (VDD
Pre-Warning
or VDD undervoltage
Temp, CAN, HS)
occurs
Standby
VDD: ON,
V2: OFF,
HS: Controllable
–
Same as Normal
mode
Same as Normal
mode
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
25
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
Stop
VDD: ON
(Limited Current
Capability),
V2: OFF,
HS:OFF or Cyclic Sense
CAN, SPI, L0 : L3,
Cyclic Sense,
Forced Wake-Up,
IDD Overcurrent (39)
Normally HIGH.
Active LOW if WDOG
Sleep
VDD: OFF,
V2: OFF,
HS: OFF or Cyclic
CAN, SPI,
L0 : L3, Cyclic Sense
Forced Wake-Up
LOW
Not Active
Not running
Low power.
Wake-up capability
if enabled
Normal
Debug (38)
Same as Normal
–
Normally HIGH.
Active LOW if VDD
undervoltage occurs
Same as Normal
Not running
Same as Normal
Standby
Debug (38)
Same as Standby
–
Normally HIGH.
Same as Standby
Active LOW if VDD
undervoltage occurs
Not running
Same as Standby
Stop
Debug (38)
Same as Stop
Same as Stop
Normally HIGH.
Active LOW if VDD
undervoltage occurs
Same as Stop
Not running
Same as Stop
Flash
Programming
Forced externally
–
Not operating
Not operating
Not operating
Not operating
(40)
or VDD undervoltage
occurs
Signal 33742S
wake-up and
IDD > IDDS-WU
(not maskable)
Running if
Low power.
enabled.
Wake-up capability
Not running if
if enabled
disabled
Notes
38. Mode entered via special sequence described under the heading Debug Mode: Hardware and Software Debug with the 33742 beginning
on page 30.
39. IDD overcurrent always enabled.
40.
WDOG if enabled.
APPLICATION WAKE-UP FROM THE 33742
When the application is in Stop mode, it can be awakened
from the SBC side. When a wake-up condition is detected by
the SBC (for example, CAN, wake-up input), the 33742
enters the Normal Request mode and generates an interrupt
pulse at the INT pin.
APPLICATION WAKE-UP FROM THE MCU
When the device is in the Stop mode, a wake-up event
may come from the system MCU. In this case the MCU
selects the device the using a LOW-to-HIGH transition on the
33742 CS pin. Then the 33742S goes into Normal Request
mode and generates an interrupt pulse at the INT pin.
STOP MODE CURRENT MONITOR
If the VDD output current exceeds an internal set threshold
(IDDS-WU), the SBC automatically enters the Normal Request
mode and generates an interrupt at the INT pin. The interrupt
is a non-maskable and the INTR register will have no flag set.
INTERRUPT GENERATION WHEN WAKE-UP
FROM STOP MODE
When the SBC wakes from Stop mode, it first enters the
Normal Request mode before generating a 10 µs typical
pulse on the INT pin. These are non-maskable interrupts with
the wake-up event read through the SPI registers, the
CANWU bit in the CAN Register (CANR), or the LCTRx bit in
the Wake-Up Register (WUR). In case of wake-up from Stop
mode overcurrent situation or from forced wake-up, no bits
are set. After the INT pulse, the 33742 accepts SPI command
after a time delay (t S-1STSPI).
WATCHDOG SOFTWARE IN STOP MODE
If the SBC watchdog is enabled, the application must
provide a “system ok” response before the end of the 33742
watchdog time. Typically an MCU initiates the wake-up of the
33742 through the SPI wake-up (CS activation). The SBC will
awaken and jump into the Normal Request mode. The MCU
has to configure the 33742 to go to either Normal or Standby
mode. The MCU can then decide to return to the Stop mode.
If no MCU wake-up occurs within the watchdog time
period, the SBC activates the RST pin and jumps into the
Normal Request mode. The MCU can then be re-initialized.
STOP MODE ENTER COMMAND
Stop mode is entered at the end of the SPI message at the
rising edge of the CS. (Refer to the t CS-STOP data in the
Dynamic Electrical Characteristics table on page 17.) Once
Stop mode is entered, the SBC can wake up from a VDD
regulator overcurrent detection state. In order to allow time
for the MCU to complete the last CPU instruction and enter
its low power mode, a deglitcher time of 40 µs typical is
implemented.
Figure 11, page 27, depicts the operation of entering the
Stop mode.
33742
26
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
SPI Stop/Sleep
Command
SPI CS
t CS-STOP
33742 in Normal
or Stand-by mode
tIDD-DGLT
33742 in Stop mode.
No IDD over IDD-DGLT
33742 in Stop mode.
IDD over IDD-DGLT
Figure 11. Entering the Stop Mode
WATCHDOG SOFTWARE (RST AND WDOG)
(SELECTABLE WATCHDOG WINDOW OR
WATCHDOG TIME-OUT)
A watchdog is used in the SBC Normal and Standby
modes for monitoring the MCU operation. The watchdog
timer may be implemented as either a watchdog window or
watchdog time-out, selectable by SPI (TIM1 sub register, bit
WDW). Default operation is a watchdog window.
The watchdog period can be set from 10 ms to 350 ms
(TIM1 sub register, bits WDT0 and WDT1). When a watchdog
window is selected, the closed window is the first part of the
selected period, and the open window is the second part of
the period. (Refer to Timing Register (TIM1 / 2) beginning on
page 47.)
The watchdog can only be cleared within the open window
time period. Any attempt to clear watchdog in the closed
window will generate a reset. The watchdog is cleared
addressing the TIM1 sub register using the SPI
RST PIN DESCRIPTION
A 33742 output is available to perform a reset of the MCU.
Reset can happen from:
• VDD Falling Out of Range — If VDD falls below the reset
threshold (V RSTTH), the RST pin is pulled LOW until
VDD returns to the normal voltage.
• Power-ON Reset — At 33742 power-on or wake-up from
Sleep mode, the RST pin is maintained LOW until VDD
is within its operation range.
• Watchdog Time-out — If watchdog is not cleared, the
33742 will pull the RST pin LOW for the duration of the
reset time (t RSTDUR).
RST AND WDOG OPERATION
Table 8 describes watchdog and reset output modes of
operation. RST is activated in the event VDD fall or watchdog
is not triggered. WDOG output is active LOW as soon as RST
goes LOW and stays LOW as long as the watchdog is not
properly reset via SPI. The WDOG output pin is designed as
a push-pull structure that can drive off chip components
signaling, for instance, errant MCU operation.
Figure 12 illustrates the device behavior in the event the
TIM1 register in not properly accessed. In this case a
software reset occurs, and the WDOG pin is set LOW until
the TIM1 register is properly accessed.
Table 8. Watchdog and Reset Output Operation
Events
WDOG
Output
RST Output
Device Power-Up
LOW to HIGH
LOW to HIGH
VDD Normal, WDOG Properly Triggered
HIGH
HIGH
VDD < VRSTTH
HIGH
LOW
WDOG Time-out Reached
LOW
(41)
LOW
Notes
41. WDOG stays LOW until the TIM1 register is properly addressed through SPI.
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
27
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
Watchdog Time-out
VDD
RST
WDOG
Watchdog
Period
SPI
WDOG Clear
TIM1 register addressed.
SPI CS
Figure 12. RST and WDOG Output Operation
WAKE-UP CAPABILITIES
Several wake-up capabilities are available to the SBC
when it is in Sleep or Stop mode. When a wake-up has
occurred, the wake-up event is stored in the Wake-Up
Register (WUR) or the CAN register and read by the MCU to
determine the wake-up source. The wake-up options are
selectable through SPI while the 33742 is in Normal or
Standby mode and prior to entering low power modes (Sleep
or Stop mode). When a wake-up occurs in Sleep mode, the
SBC reactivates VDD supply. It generates an interrupt if
wake-up occurs from Stop mode.
WAKE-UP FROM WAKE-UP INPUTS (L0 : L3)
WITHOUT CYCLIC SENSE
The wake-up lines are used to determine the state of
external switches and if changes occurred to wake up the
MCU (in Sleep or Stop modes). Wake-up pins L0 : L3 are able
to handle up to 40 VDC. The internalize” threshold is 3.0 V
typical and these inputs can be used as an input port
expander. The wake-up input states are read through SPI
(WUR register).
In order to select and activate direct wake-up from the
L0 : L3 inputs, the WUR register must be configured with the
appropriate level sensitivity. Additionally, the Low Power
Control (LPC) Register must be configured with 0xx0 data
(bits LX2HS and HSAUTO are set to 0).
The sensitivity of the L0 : L3 inputs is selected by the WUR
register. Level sensitivity is configured by L0 : L3 input pairs:
L0 and L1 level sensitivity are configured together, while L2
and L3 are configured together.
CYCLIC SENSE WAKE-UP (CYCLIC SENSE TIMER
AND WAKE-UP INPUTS L0 : L3)
The 33742 can wake up upon state change of one of the
four wake-up input lines (L0 : L3). The external pullup or pulldown resistor of the switches associated with the wake-up
input lines can be biased from the HS VSUP switch. The HS
switch is activated in Sleep or Stop modes from an internal
timer. Cyclic Sense and Forced Wake-Up are exclusive
states. If Cyclic Sense is enabled, Forced Wake-Up cannot
be enabled.
In order to select and activate the cyclic sense wake-up
from the L0 : L3 inputs, the WUR register must be configured
with the appropriate level sensitivity and the LPC register
must be configured with 1xx1 data (bit LX2HS set at 1 and bit
HSAUTO set at 1). The wake-up mode selection (direct or
cyclic sense) is valid for all four wake-up inputs.
FORCED WAKE-UP
The SBC can wake up automatically after a predetermined
time spent in Sleep or Stop mode. Cyclic Sense and Forced
Wake-up are exclusive. If Forced Wake-Up is enabled (FWU
bit set to 1 in the LPC register), Cyclic Sense cannot be
enabled.
CAN INTERFACE WAKE-UP
The SBC incorporates a high-speed 1.0 Mbps CAN
physical interface. It is compatible with ISO 11898-2
standard. The operation of the CAN physical interface is
controlled through the SPI. The CAN operating modes are
independent of the 33742 operational modes.
The SBC can wake up from a CAN message if the CAN
wake-up feature is enabled. Refer to the section titled LOGIC
COMMANDS AND REGISTERS beginning on page 42 for
details of the wake-up detection.
SPI WAKE-UP
The 33742 can be awakened by changes on the CS pin in
Sleep or Stop modes. Wake-up is detected as a LOW-toHIGH level transition on the CS pin. In the Stop mode, this
corresponds to a condition where an MCU and the SBC are
both in the Stop mode and when the application wake-up
event comes through the MCU.
33742 POWER-UP AND WAKE-UP FROM SLEEP
MODE
After device or system power-up, or after the SBC
awakens from Sleep mode, the 33742S enters into the Reset
mode prior to moving into Normal Request mode.
Figure 13, shows the device state diagram. Figure 14,
shows device operation after power-up.
33742
28
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
Watchdog: Timeout OR VDD Low
Watchdog: Time-out & Nostop &!BATFAIL
R
V
D
Power
Down
DL
ow
2
(4
3)
1
Stop
SPI: Stop & CS
LOW to HIGH
Transition
Watchdog: Timeout OR VDD Low
Nostop and SPI: Sleep
& CS LOW to HIGH
Transition
O
Normal
1
Nostop and SPI:
Sleep & CS LOW
to HIGH
ou
t
Standby
SPI: Normal
:T
im
e-
4
1
3
SP
do
g
VDD Low OR Watchdog:
Timeout 350 ms & Nostop
Wake-Up
ch
Normal Request
g:
do
ch r
at e
W rigg
T
33742S Power-
1
I:
H Sto
ig p
h &
Tr C
an S
s i Lo
tio w
n to
Reset
W
at
SPI: Stand-by and
Watchdog Trigger
2
SPI: Standby
Reset Counter (3.4 ms)
Expired
Wake-Up
(VDD High Temperature OR [VDD Low > 100 ms & VSUP > BFew]) & Nostop &!BATFAIL
1
2
3
4
Sleep
Denotes priority
State Machine Description
Nostop = Nostop bit = 1
! Nostop = Nostop bit = 0
BATFAIL = Batfail bit = 1
! BATFAIL = Batfail bit = 0
VDD Overtemperature = VDD thermal shutdown occurs
VDD LOW = VDD below reset threshold
VDD LOW > 100 ms = VDD below reset threshold for more than 100 ms
Watchdog: Trigger = TIM1 subregister write operation
VSUP > BFew = VSUP > Battery Fail Early Warning (6.1 V typical)
Watchdog: Timeout = TIM1 register not written before watchdog timeout period
expired, or watchdog written in incorrect time window if watchdog window
selected (except Stop mode). In Normal Request mode, timeout is 355 ms
p2.2 (350 ms p3) ms.
SPI: Sleep = SPI write command to MCR register, data sleep
SPI: Stop = SPI write command to MCR register, data stop
SPI: Normal = SPI write command to MCR register, data normal
SPI: Standby = SPI write command to MCR register, data standby
Notes
42. These two SPI commands must be sent consecutively in this sequence.
43. If watchdog activated.
Figure 13. SBC State Diagram (Not Valid in Debug Modes)
Power-Up
Operation after power-up if no trigger appears
Operation after reset of BATFAIL if no trigger appears
Reset
Normal
Request
Yes
No
Trigger
No
No
Batfail
No Stop
Yes
Sleep
Yes
Normal
Figure 14. Operation After SBC Power-Up
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
29
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
DEBUG MODE: HARDWARE AND SOFTWARE
DEBUG WITH THE 33742
normal 33742 operation, it is recommended that the disable
be done using the following sequence:
When a SBC, and the MCU it serves, is used on the same
printed circuit board, both the MCU software and the 33742
operation must be debugged concurrently. The following
features permit system debugging by allowing the disabling
of the SBC internal software watchdog timer.
• Step 1– Power down the SBC.
• Step 2 – Power up the SBC. This sets the BATFAIL bit,
allowing the 33742 to enter Normal Request mode.
• Step 3 – Write to the TIM1 sub register to allow the SBC to
enter Normal mode.
• Step 4 – Write to the MCR register with data 0000. This
enables the debug mode. Complete SPI byte is
0001 0000.
• Step 5 – Write to the MCR register normal debug. SPI byte
is 0001 x101.
Important While in debug mode, the SBC can be used
without having to clear the watchdog on a regular basis to
facilitate software and hardware debug.
• Step 6 – To leave the debug mode, write 0000 to the MCR
register.
DEVICE POWER-UP, RESET PIN CONNECTED TO
VDD
The VDD voltage is available when the 33742 power-up
but the 33742 will not have received any SPI communication
to configure itself. Until set up by the system MCU, the 33742
will generate a reset every 350 ms until the part is configured.
To avoid continuous MCU hardware resets, the 33742’s RST
pin can be connected directly to VDD pin by a hardware
jumper.
DEBUG MODES WITH SOFTWARE WATCHDOG
DISABLED THOUGH SPI (NORMAL DEBUG,
STANDBY DEBUG, AND STOP DEBUG)
The software configurable watchdog can be disabled
through SPI. To set the watchdog disable while limiting the
risk of inadvertently disabling the watchdog timer during
At Step 2, the SBC is in Normal Request. Steps 3, 4, and 5
should be completed consecutively and within the 350 ms
time period of the Normal Request mode. If not, the 33742
will go into Reset mode and enter Normal Request again.
Figure 15, page 30, illustrates debug mode selection.
VSUP
VDD
BATFAIL
TIM1(Step 3)
MCR (Step 5)
MCR (Step 6)
SPI
MCR (Step 4)
Debug Mode
SPI: Read BATFAIL
33742 in Debug mode.
No Watchdog
33742 not in Debug mode.
Watchdog ON
Figure 15. Entering Debug Mode
When the SBC is operating in the debug mode and has
been set into Stop Debug or Sleep mode, a wake-up causes
the 33742 to enter the Normal Request mode for 350 ms. To
avoid having the SBC generate an unwanted reset (enter
Reset mode), the next debug mode (Normal Debug or
Standby Debug) should be configured within the 350 ms time
window of the Normal Request mode.
To avoid entering debug mode after a power-up, first read
the BATFAIL bit (MCR read) and write 0000 into the MCR
register.
Figures 16 and 17, page 31, show the detailed operation
of the SBC once the debug mode has been selected.
33742
30
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
Watchdog: Timeout 350 ms
Reset Counter
(3.4 ms) Expired
Power
Down
Reset
Watchdog:
Trigger
Normal Request
SPI: MCR (0000) and Normal Debug
Normal
Normal Debug
SPI: MCR (0000) and Standby Debug
Standby Debug
Figure 16. Transitions to Enter Debug Modes
Watchdog: Time-out 350 ms
og
: Tr
ig g
er
R
D
Normal
by
ma
l
De
b
E
St
an
d
or
I:
I: N
ug
SP
SPI: Standby Debug
Standby Debug
eb
ug
Standby
R
Sleep
&!BATFAIL & NOSTOP
& SPI: Sleep
hd
R
SP
SPI: Stop Debug & CS Low to
High Transition
SPI: Stop
Stop Debug
Wa
tc
R
Wake-Up
Reset
E
SPI: Standby Debug
Normal Debug
SPI: Normal Debug
R
SPI: Normal Debug
W
ak
eU
p
R
R
Reset Counter
(3.4 ms) Expired
Normal Request
SPI: Standby &
Watchdog: Trigger
Wake-Up
Stop (1)
R
(1) If Stop mode is entered, it is entered without watchdog, no matter the WDSTOP bit.
(E) Debug mode entry point (Step 5 of the Debug mode entering sequence).
(R) Represents transitions to Reset mode due to V1 low.
Figure 17. Simplified 33742S State Diagram in Debug Modes
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
31
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
MCU FLASH PROGRAMMING CONFIGURATION
To allow for new software to be loaded into a SBC’s MCU
NVM or to standalone EEPROM or Flash, the 33742 is
capable of having (1) VSUP applied to it to from an external
power 5.0 V supply and (2) having the RST and the WDOG
outputs pins eternally forced to 0.0 V or 5.0 V without
damaging the device.
This allows the SBC to be externally powered and offboard signals to be applied to the reset pins. No functions of
the 33742 are operating. Figure 18 illustrates a typical
configuration for the connection of programming and
debugging tools.
The VSUP should be left open or forced to a value equal
to or above V.
The VDD regulator uses an internal pass transistor
between VSUP and the VDD output pin. Biasing the VDD
output pin with a voltage greater than VDD potential will force
current through the body diode of the internal pass transistor
to the VSUP pin.
The RST pin is periodically pulled LOW for the t RSTDUR
time (device in Reset mode), before being pulled to VDD for
350 ms typical (device in Normal Request mode). During the
time reset is LOW, the RST pin sinks 5.0 mA maximum
(IPDW).
VDD
VSUP (Open or > 5.0 V
RST
33742
WDOG
5.0 V
MCU with
Flash Memory
Programming Bus
Programming Tool
Note External supply and sources applied to VDD, RST, and WDOG test points on application circuit board.
Figure 18. Simplified Schematic for Microcontroller Flash Programming
33742
32
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
CAN PHYSICAL INTERFACE
The SBC features a high-speed CAN physical interface for bus communication from 60 kbps up to 1.0 Mbps. Figure 19 is a
simplified block diagram of the CAN interface of the 33742.
33742
V2
V2
V2
SPI Control
TXD
Driver
QH
CANH
V2
CANH Line
Differential
Receiver
RXD
Bus Termination (60 Ω)
2.5 V
CANL Line
V2
CANL
Driver
QL
SPI Control
VSUP
Internal
Wake-Up
Signal
Wake-Up
Pattern
Recognition
Wake-Up
Receiver
SPI Control
Figure 19. Simplified Block Diagram of CAN Interface
CAN INTERFACE SUPPLY
CAN DRIVER OPERATION IN TXRX MODE
The supply voltage for the CAN transceiver is the V2 pin.
The CAN interface also has a supply path from the external
supply line through the VSUP pin. This path is used in CAN
Sleep mode to allow wake-up detection.
During CAN communication (transmission and reception),
the CAN interface current is sourced from the V2 pin. During
CAN low power mode, the current is sourced from the VSUP
pin.
When the CAN interface is in TXRX mode, the driver has
two states: recessive or dominant. The driver state is
controlled by the TXD pin. The bus state is reported through
the RXD pin.
When TXD is HIGH, the driver is set in recessive state, and
CANH and CANL lines are biased to the voltage set at V2
divided by 2, or approximately 2.5 V.
When TXD is LOW, the bus is set into dominant state:
CANL and CANH drivers are active. CANL is pulled to
ground, and CANH is pulled HIGH toward 5.0 V (voltage at
V2).
The RXD pin reports the bus state: CANH minus CANL
voltage is compared versus an internal threshold (a few
hundred millivolts). If CANH minus CANL is below the
threshold, the bus is recessive and RXD is set HIGH. If CANH
minus CANL is above the threshold, the bus is dominant and
RXD is set LOW. This is illustrated in Figure 19.
MAIN OPERATION MODES DESCRIPTION
The CAN interface of the SBC has two main operating
modes: TXRX and Sleep mode. The modes are controlled by
the CAN SPI Register. In the TXRX mode, which is used for
communication, four different slew rates are available for the
user. In the Sleep mode, the user has the option of enabling
or disabling the remote CAN wake-up capability.
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
33
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
TXD
CANH
CANL
Typ 2.5 V
VCANH -VCANL > 900 mV
Typ 2.5 V
VCANH -VCANL < 500 mV
RXD
CAN Recessive State
CAN Dominant State
CAN Recessive State
Figure 20. CAN Interface Levels
TXD AND RXD PINS
CAN TXRX MODE AND SLEW RATE SELECTION
The TXD pin has an internal pullup to V2. The state of TXD
depends on the V2 status. RXD is a push-pull structure,
supplied by V2. When V2 is set at 5.0 V and CAN is TXRX
mode, RXD reports bus status. For details, refer to Table 7,
page 25, Table 9, below, and Table 10, page 35.
The slew rate selection is done via CAN register (refer to
Tables 21 through 23 on page 45). Four slew rates are
available and control the recessive-to-dominant and
dominant-to-recessive transitions. The delay time from TXD
pin to CAN bus, from CAN bus to RXD, and from the TXD to
RXD loop time is affected by the slew rate selection.
Table 9. CAN Interface / 33742S Modes and Pin Status—Operation with Ballast on V2 (44)
Mode
CAN Mode
(Controlled by SPI)
V2 Voltage
TXD Pin
RXD Pin
CANH/CANL
(Disconnected from
Other Node)
CAN
Communication
Unpowered
–
0.0 V
LOW
LOW
Floating to GND
NO
Reset (with Ballast)
–
0.0 V
LOW
LOW
Floating to GND
NO
Normal Request
(with Ballast)
–
0.0 V
LOW
LOW
Floating to GND
NO
Normal
Sleep
5.0 V
0.0 V
5.0 V
Floating to GND
NO
Normal
Normal
Slew Rate 0, 1, 2, 3
5.0 V
Internal Pullup
to V2
Standby with
External Ballast
Normal or Sleep
0.0 V
LOW
LOW
Floating to GND
NO
Sleep
Sleep
0.0 V
LOW
LOW
Floating to GND
NO.
Wake-up if enabled
Stop
Sleep
0.0 V
LOW
LOW
Floating to GND
NO.
Wake-up if enabled
Report Bus State
Bus Recessive
HIGH if Bus
CANH = CANL = 2.5 V
Recessive,
LOW if dominant
YES
Notes
44. See also Figure 31, page 52.
33742
34
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
Table 10. CAN Interface / 33742 Modes and Pin Status — Operation without Ballast on V2 (45)
Mode
CAN Mode
(Controlled by SPI)
V2 Voltage
TXD Pin
RXD Pin
CANH/CANL
(Disconnected from
Other Node)
CAN
Communication
Unpowered
–
0.0 V
LOW
LOW
Floating to GND
NO
Reset (with Ballast)
–
0.0 V
LOW
LOW
Floating to GND
NO
Normal Request
without Ballast.
V2 Connected to
VDD
–
5.0 V
LOW
5.0 V
Floating to GND
NO
Standby without
External Ballast,.
V2 connected to VDD
Normal or Sleep
5.0 V
0.0 V
5.0 V
Floating to GND
NO
Normal without
External Ballast.
V2 Connected to
VDD
Normal
Slew Rate 0, 1, 2,3
5.0 V
5.0 V
5.0 V
Bus Recessive
CANH = CANL = 2.5 V
YES
Normal without
External Ballast,.
V2 Connected to
VDD
Sleep
5.0 V
0.0 V
5.0 V
Floating to GND
NO
Sleep
Sleep
0.0 V
LOW
LOW
Floating to GND
NO.
Wake-up if enabled
Stop
Sleep
0.0 V
LOW
LOW
Floating to GND
NO.
Wake-up if enabled
Notes
45. See also Figure 36, page 55.
CAN SLEEP MODE
The 33742 offers two CAN Sleep modes:
• Sleep mode with CAN wake-up enable: detection of
incoming CAN message and SBC wake-up.
• Sleep mode with CAN wake-up disable: no detection of
incoming CAN message.
The CAN Sleep modes are set via the CAN SPI register.
In CAN Sleep mode (with wake-up enable or disable), the
CAN interface is internally supplied from the VSUP pin. The
voltage at V2 pin can be either 5.0 V or turned off. When the
CAN is in Sleep mode, the current sourced from V2 is
extremely low. In most cases the V2 voltage is off; however,
the CAN can be placed into Sleep mode even with 5.0 V
applied on V2.
In CAN Sleep mode, the CANH and CANL drivers are
disabled, and the receiver is also disabled. CANH and CANL
are high-impedance mode to ground.
CAN SIGNALS IN TXRX AND SLEEP MODES
When the CAN interface is set back into TXRX mode by an
SPI command, CAN H and CANL are set in recessive level.
This is illustrated in Figure 21.
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
35
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
TXD
CANH Dominant
CANH
CANL/CANH Recessive
2.5 V
CANL
CANL Dominant
Ground
RXD
CAN in Sleep Mode
(Wake-Up Enable or Disable)
CAN in TXRX Mode
CAN in TXRX Mode
(Controlled by SPI Command)
Figure 21. CAN Signals in TXRX and Sleep Modes
• The distance between 2 pulses must be lower than 500 µs.
• The three pulses must occur within a time frame of 1.0 ms.
The pattern wake-up of the 33742 CAN interface allow
wake-up by any CAN message content.
Figure 22 below illustrates the CAN signals during a CAN
bus Sleep state and wake-up sequence.
CAN IN SLEEP MODE WITH WAKE-UP ENABLE
When the CAN interface is in Sleep mode with wake-up
enable, the CAN bus traffic is detected. The CAN bus wakeup is a pattern wake-up.
PATTERN WAKE-UP
In order to wake up the CAN interface, the following criteria
must be fulfilled:
• The CAN interface wake-up receiver must receive a series
of three consecutive valid dominant pulses, each of which
must be longer than 500 ns and shorter than 500 µs.
TXD
CANH Dominant
CANH
2.5 V
CANL/CANH Recessive
CANH Dominant
CANH Dominant
CANH Dominant
Pulse # 1
Pulse # 2
Pulse # 3
CANL Dominant
CANL Dominant
CANL Dominant
CANL
CANL Dominant
Ground
CAN Bus Sleep State
RXD
CAN in TXRX Mode
Incoming CAN Message
CAN in Sleep Mode (Wake-Up Enable)
WU Receiver
Min 500 ns
Max 500 µs
Internal Wake-Up Signal
Figure 22. CAN Bus Signal During Can Sleep State and Wake-Up Sequence
33742
36
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
Figure 23 illustrates how the wake-up signal is generated.
First the CAN signal is detected by a low consumption
receiver (WU receiver). Then the signal passes through a
pulse width filter, which discards the undesired pulses. The
pulse must have a width bigger than 0.5 µs and smaller than
500 µs to be accepted. When a pulse is discarded, the pulse
counter is reset and no wake-up signal is generated. When a
Pulse OK
CANH
Pulse Width
Filter
CANL
WU Receiver
Narrow
Pulse
pulse is accepted, the pulse counter is incremented and, after
three pulses, the internal wake-up signal is asserted.
Each one of the pulses must be spaced by no more than
500 µs. If not, the counter will be reset and no wake-up signal
will be generated. This is accomplished by the wake-up
timeout generator. The wake-up cycle is completed (and the
wake-up flag reset) when the CAN interface is brought to
CAN Normal mode.
Counter
Latch
RST
RST
+
Internal Wake-Up
Signal
Time-out
Time-out
Generator
Standby
Figure 23. Wake-Up Functional Block Diagram
CAN WAKE-UP REPORT
The CAN wake-up reporting depend upon the low power
mode the SBC is in.
If the SBC is placed into Sleep mode (VDD and V2 off), the
CAN wake-up or any wake-up results in the VDD regulator
turning on, leading to turning on the MCU supply and
releasing reset. If the 33742 is in Stop mode (V2 off and VDD
active), the CAN wake-up or any wake-up is signalled by a
pulse on the INT output. In addition the CANWU bit is set in
the CAN register.
If the SBC is in Normal or Standby mode and the CAN
interface is in Sleep mode with wake-up enabled, the CAN
wake-up is reported by the CANWU bit in the CAN register.
In the event the SBC is in Normal mode and CAN Sleep
mode with wake-up enabled, it is recommended that the user
check for the CANWU bit prior to placing the 33742 in Sleep
or Stop mode in case bus traffic has occurred while the CAN
interface was in Sleep mode.
After a CAN wake-up, a flag is set in the CAN register. Bit
CANWU reports the CAN wake-up event while the 33742
was in Sleep or Stop mode. This bit is set until the CAN is in
placed by SPI command into TXRX mode and the CAN
register can be read.
CAN BUS DIAGNOSTIC
The SBC can diagnose CANH or CANL lines short to
GND, shorts to VSUP or VDD.
As illustrated in Figure 24, several single-ended
comparators are implemented on the CANH and CANL bus
lines. These comparators monitor the bus voltage level in the
recessive and dominant states. This information is then
managed by a logic circuit to determine if a failure has
occurred and to report it. Table 11 indicates the state of the
comparators in the event of bus failure and the state of the
drivers; that is, whether they are recessive or dominant.
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
37
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
Vr5
H5
Hb
TXD
Diagnostic
Hg
VSUP (12 V–14 V)
Vrvb
VDD
Vrvb (VSUP - 2.0 V)
Vrg
CANH
Vrg
CANL
Logic
Lg
Lb
L5
VDD (5.0 V)
Vr5 (VDD - 0.43 V)
CANH Dominant Level (3.6 V)
Recessive Level (2.5 V)
Vrg (1.75 V)
Vrvb
CANL Dominant Level (1.4 V)
Vr5
GND (0.0 V)
Figure 24. CAN Bus Simplified Structure
Table 11. Short to GND, Short to VSUP , and Short to 5.0 V (VDD) Detection Truth Table
Driver Recessive State
Driver Dominant State
Failure Description
Lg (Threshold 1.75 V)
Hg (Threshold 1.75 V)
Lg (Threshold 1.75 V)
Hg (Threshold 1.75 V)
No failure
1
1
0
1
CANL to GND
0
0
0
1
CANH to GND
0
0
0
0
Lb (Threshold VSUP - 2.0 V) Hb (Threshold VSUP - 2.0 V) Lb (Threshold VSUP - 2.0 V) Hb (Threshold VSUP -2.0 V)
No failure
0
0
0
0
CANL to VSUP
1
1
1
1
CANH to VSUP
1
1
0
1
L5 (Threshold VDD- 0.43 V) H5 (Threshold VDD- 0.43 V) L5 (Threshold VDD- 0.43 V)
H5
(Threshold VDD- 0.43 V)
No failure
0
0
0
0
CANL to VDD
1
1
1
1
CANH to VDD
1
1
0
1
33742
38
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
DETECTION PRINCIPLE
In the recessive state, if one of the two bus lines is shorted
to GND, VDD, or VSUP, then voltage at the other line follows
the shorted line due to bus termination resistance and the
high impedance of the driver. For example, if CANL is shorted
to GND, CANL voltage is zero, and CANH voltage, as
measured by the Hg comparator, is also close to zero.
In the recessive state the failure detection to GND or
VSUP is possible. However, it is impossible to distinguish
which bus line, CANL or CANH, is shorted to GND or VSUP.
In the dominant state, the complete diagnostic is possible
once the driver is turned on.
CAN BUS FAILURE REPORTING
CANL bus line failures (for example, CANL short to GND)
is reported in the SPI register TIM1/2. CANH bus line (for
example, CANH short to VSUP) is reported in the LPC
register.
In addition CAN-F and CAN-UF bits in the CAN register
indicate that a CAN bus failure has been detected.
NON-IDENTIFIED AND FULLY IDENTIFIED BUS
FAILURES
As indicated in Table 11, page 38, when the bus is in a
recessive state it is possible to detect an error condition;
however, is it not possible to fully identify the specific error.
This is called “non-identified” or “under-acquisition” bus
failure. If there is no communication (i.e., bus idle), it is still
possible to warn the MCU that the SBC has started to detect
a bus failure.
TXD
Diag
2.0 V
V1
RXD
The failure detector requires at least one cycle of
recessive and dominant state to properly recognize the bus
failure. The error will be fully detected after five cycles of
recessive-dominant states. As long as the failure detection
circuitry has not detected the same error for five recessivedominant cycles, the bit “non-identified failure” (CAN-UF) will
be set.
RXD PERMANENT RECESSIVE FAILURE
The purpose of this detection mechanism is to diagnose
an external hardware failure at the RXD output pin and to
ensure that a permanent failure at the RXD pin does not
disturb network communication.In the event RXD is shorted
to a permanent high level signal (i.e., 5.0 V), the CAN
protocol module within the MCU cannot receive any incoming
message. Additionally, the CAN protocol module cannot
distinguish the bus idle state and could start communication
at any time. To prevent this, an RXD failure detection, as
illustrated in Figure 25 and explained below, is necessary.
Diff Output
RXD Sense
RXD Output
CANH
60 Ω
Diff
CANL
Sampling Sampling
Sampling
VDD
RXD
Driver
NUMBER OF SAMPLES FOR PROPER FAILURE
DETECTION
CANL
CANH
TXD
Driver
Logic
In the CAN register, bits D2 and D1 (CAN-F and CAN-UF,
respectively) are used to signal bus failure. Bit D2 reports a
bus failure and bit D1 indicates if the failure is identified or not
(bit D1 is set to logic [1} if the error is not identified).
When the detection mechanism is fully operating any bus
error will be detected and reported in the TIM1/2 and LPC
registers and bit D1 will be reset to logic [0].
Sampling
RXD Short to V1
RXD Flag Latched
RXD Flag
Prop Delay
Note RXD Flag is neither the RXPR bit in the LPC register nor the CAN-F bit in the INTR register.
Figure 25. RXD Path and RXD Permanent Recessive Detection Principle
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
39
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
RXD FAILURE DETECTION
TXD PERMANENT DOMINANT FAILURE
The SBC senses the RXD output voltage at each LOW-toHIGH transition of the differential receiver. Excluding internal
propagation delay, RXD output should be LOW when the
differential receiver is LOW. In the event RXD is shorted to
5.0 V (e.g., to VDD), RXD will be tied to a high level and the
RXD short to 5.0 V can be detected at the next LOW-to-HIGH
transition of the differential receiver. Compete detection
requires three samples.
When the error is detected, an error flag is latched and the
CAN driver is disabled. The error is reported through the SPI
register LPC, bit RXPR.
RECOVERY CONDITION
The SBC will try to recover from a bus fault condition by
sampling for a correct low level at TXD, as illustrated in
Figure 26.
As soon as an RXD permanent recessive is detected, the
RXD driver is deactivated and a weak pull-down current
source is activated in order to allow recovery conditions. The
driver stays disabled until the failure is cleared (RXD no
longer permanent recessive) and the bus driver is activated
by an SPI register command (write 1 to the CANCLR bit in the
CAN register).
PRINCIPLE
In the event TXD is set to a permanent low level, the CAN
bus is set into dominant level, and no communication is
possible. The SBC has a TXD permanent time-out detector.
After time-out, the bus driver is disabled and the bus is
released in a recessive state. The TXD permanent dominant
failure is reported in the TIM1 register.
RECOVERY
The TXD permanent dominant is used and activated also
in case of TXD short to RXD. The recovery condition for TXD
permanent dominant (recovery means the reactivation of the
CAN drivers) is done by an SPI command and is controlled
by the MCU.
The driver stays disabled until the failure is cleared (TXD
no longer permanent dominant) and the bus driver is
activated by an SPI register command (write logic [1] to
CANCLR bit in the CAN register).
TXD TO RXD SHORT CIRCUIT FAILURE
PRINCIPLE
In the event the TXD is shorted to RXD when an incoming
CAN message is received, the RXD will be at a LOW.
Consequently, the TXD pin is LOW and drives CANH and
CANL into the dominant state. The bus is stuck in dominant
mode and no further communication is possible.
CANL
CANH
Diff Output
Sampling
RXD Output
Sampling
RXD Short to VDD
RXD Flag Latched
RXD no longer shorted to VDD
RXD Flag
Note RXD Flag is neither the RXPR bit in the LPC register
nor the CAN-F bit in INTR register.
DETECTION AND RECOVERY
The TXD permanent dominant timeout will be activated
and release the CANL and CANH drivers. However, at the
next incoming dominant bit, the bus will be stuck again in
dominant. In order to avoid this situation, the recovery from a
failure (recovery means the reactivation of the CAN drivers)
is done by an SPI command and controlled by the MCU.
INTERNAL ERROR OUTPUT FLAGS
Figure 26. RXD Recovery Conditions
There are internal error flags to signal whenever thermal
protection is activated or overcurrent detection occurs on the
CANL or CANH pins (THERM-CUR bit). The errors are
reported in the CAN register.
33742
40
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
DEVICE FAULT OPERATION
Table 12 describes the relationship between device fault or warning and the operation of the VDD, V2, CAN, and HS interface.
Table 12. Fault / Warning
Fault / Warning
VDD
V2
CAN
HS
Battery Fail
Turn OFF
Turn OFF
Turn OFF due to V2.
No communication
OFF
VDD Temperature
Pre-Warning
Warning flag only.
Leave as is
No change
No change
No change
VDD Overtemperature
Turn OFF
Turn OFF
Turn OFF due to V2.
No communication
OFF
VDD Overcurrent
VDD regulator enters linear
mode. VDD undervoltage
reset may occurs. VDD
overtemperature PreWarning or shutdown may
occur
Turn OFF if VDD
undervoltage reset occurs
If V2 is OFF, turn OFF
and no communication
Turn OFF if VDD
undervoltage reset occurs
VDD Short Circuit
VDD undervoltage reset
occurs. VDD
overtemperature PreWarning or shutdown may
occur
Turn OFF
Turn OFF due to V2.
No communication
OFF
Watchdog Reset
ON
Turn OFF
Turn OFF due to V2.
No communication
OFF
V2LOW (e.g., V2 < 4.0 V)
No change
V2 out of range
Turn OFF due to V2 low
No change
HS Overtemperature
No change
No change
No change
OFF
HS Overcurrent
No change
No change
No change
HS overtemperature
may occur
VSUP LOW
No change
No change
No change
No change
CAN Overtemperature
No change
No change
Disable. As soon as
temperature falls, CAN is
re-enabled automatically
No change
CAN Overcurrent
No change
No change
(46)
No change
CANH Short to GND
No change
No change (47)
No communication (48)
No change
CANH Short to VDD
No change
No change
Communication OK
No change
CANH Short to VSUP
No change
No change
Communication OK
No change
CANL Short to GND
No change
No change
Communication OK
No change
CANL Short to VDD
No change
No change
No communication (48)
No change
CANL Short to VSUP
No change
No change
No communication (48)
No change
Notes
46. Refer to descriptions of CANH and CANL short to GND, VDD, and VSUP elsewhere in table.
47. Peak current 150 mA during TXD dominant only. Due to loss of communication, CAN controller reaches bus OFF state. Average current
out of V2 is below 10 mA.
48. Overcurrent might be detected. THERM-CUR bit set in CAN register.
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
41
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
LOGIC COMMANDS AND REGISTERS
SPI INTERFACE AND REGISTER DESCRIPTION
DATA FORMAT DESCRIPTION
Figure 27 illustrates an 8-bit byte corresponding to the
8 bits in a SPI register. The first three bits are used to identify
the internal SBC register address. Bit 4 is a read/write bit.
The last four bits are data sent from the MCU to the SBC or
read back from the 33742 to the MCU.
The state of the MISO has no significance during the write
operation. However, during a read operation the final four bits
of MISO have meaning; namely, they contain the content of
the accessed register.
MISO
Bit 7 Bit 6
A2
A1
Bit 5
A0
Bit 4 Bit 3
Bit 2 Bit 1
Bit 0
R/W
D2
D0
D3
D1
MOSI
Table 13. Possible Reset Conditions
Condition
Name
33742 Reset
POR
Power-ON Reset
33742 Mode
Transition
NR2R
Normal Request to Reset Mode
NR2N
Normal Request to Normal Mode
NR2STB
Normal Request to Standby Mode
33742 Mode
Definition
N2R
Normal to Reset Mode
STB2R
Standby to Reset Mode
STO2R
Stop to Reset Mode
STO2NR
Stop to Normal Request
RESET
33742S in Reset Mode
REGISTER DESCRIPTIONS
Address
The following tables in this section describe the SPI
register list and register bit meaning. Register reset values
are also described, along with the reset condition. A reset
condition is the condition causing the bit to be set at the reset
value.
Data
Note Read operation: R/W bit = logic [0]
:
Write operation: R/W = logic [1]
Figure 27. Data Format Description.
Table 14. List of Registers
Register
Address
Comment and Use
Formal Name
and Link
Write
Read
MCR
$000
Mode Control Register (MCR)
on page 43
Selection for Normal, Standby, Sleep,
Stop, and Debug modes
RCR
$001
Reset Control Register (RCR)
on page 44
Configuration for reset voltage level, CAN Sleep and Stop modes
CAN
$010
CAN Register (CAN) on page
44
CAN slew rate, Sleep and Wake-Up
enable/disable modes, drive enable after
failure
CAN wake-up and CAN failure status bits
IOR
$011
Input / Output Register (IOR)
on page 45
HS (high-side switch) control in Normal
and Standby mode
HS overtemperature bit, VSUP, and V2
LOW status
WUR
$100
on page 46
Control of wake-up input polarity
Wake-up input and real time Lx input
state
TIM
$101
Timing Register (TIM1 / 2) on •
page 47
•
BATFAIL, general failure, VDD prewarning, and Watchdog flag
TIM1: Watchdog timing control, Watch- CANL and TXD failure reporting
dog Window (WDW) or Watchdog Timeout (WTO) mode
TIM2: Cyclic Sense and Forced WakeUp timing selection
LPC
$110
Low Power Control Register
(LPC) on page 49
Control HS periodic activation in Sleep
and Stop modes, Forced Wake-Up mode
activation, CAN-INT mode selection
CANH and RXD failure reporting
INTR
$111
Interrupt Register (INTR) on
page 51
Enable or Disable of Interrupts
Interrupt source
33742
42
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
MODE CONTROL REGISTER (MCR)
Tables 15 through 17 describes the various Mode Control Registers.
Table 15. Mode Control Register
MCR
R/W
D3
$000b
W
–
R
Reset Value
(50)
Reset Condition (Write)
BATFAIL
(49)
D2
D1
D0
MCTR2
MCTR1
MCTR0
VDDTEMP
GFAIL
WDRST
–
–
0
0
0
–
–
POR, RESET
POR, RESET
POR, RESET
Notes
49. BATFAIL bit cannot be set by SPI. BATFAIL is set when VSUP falls below 3.0 V.
50. See Table 13 page 42, for definitions of reset conditions
Table 16. Mode Control Register Control Bits
MCTR MCTR MCTR
2
1
0
33742S Mode
Description
To enter/exit Debug Mode, refer to detailed description in Debug Mode: Hardware and
Software Debug with the 33742, page 30.
0
0
0
Enter/Exit Debug
Mode
0
0
1
Normal
–
0
1
0
Standby
–
0
1
1
Stop, Watchdog OFF
–
0
1
1
Stop, Watchdog ON
–
1
0
0
Sleep (52)
–
1
0
1
Normal
1
1
0
Standby
1
1
1
Stop
(51)
(51)
No Watchdog running. Debug Mode.
Notes
51. Watchdog ON or OFF depends on RCR bit D3.
52. Before entering Sleep mode, BATFAIL bit in MCR must be previously cleared (MCR read operation), and NOSTOP bit in RCR must be
previously set to logic [1].
Table 17. Mode Control Register Status Bits
Name
BATFAIL
VDDTEMP
GFAIL
WDRST
Logic
Description
0
VSUP was not below VBF.
1
VSUP has been below VBF.
0
No overtemperature pre-warning.
1
Temperature pre-warning on VDD regulator (bit latched).
0
No failure.
1
CAN Failure or HS overtemperature or V2 low.
0
No watchdog reset occurred.
1
Watchdog reset occurred.
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
43
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
RESET CONTROL REGISTER (RCR)
Tables 18 and 19 contain various Reset Control Register information.
Table 18. Reset Control Register
RCR
R/W
$001b
W
R
D3
D2
D1
D0
WDSTOP
NOSTOP
CAN SLEEP
RSTTH
Reset Value
–
1
0
0
0
Reset Condition
–
POR, RESET, STO2NR
POR, NR2N, NR2STB
POR, NR2N, NR2STB
POR
(Write) (53)
Notes
53. See Table 13 page 42, for definitions of reset conditions.
Table 19. Reset Control Register Control Bits
Name
Logic
WDSTOP
NOSTOP
CAN SLEEP
RSTTH
Description
0
No Watchdog in Stop Mode.
1
Watchdog runs in Stop Mode.
0
Device cannot enter Sleep Mode.
1
Sleep mode allowed. Device can enter Sleep Mode.
0
CAN Sleep Mode disable (despite D0 bit in CAN register).
1
CAN Sleep Mode enabled (in addition to D0 in CAN register).
0
Reset Threshold 1 selected (typ 4.6 V).
1
Reset Threshold 2 selected (typ 4.2 V).
CAN REGISTER (CAN)
Tables 20 through 23 contain the information on the CAN register. Table 20 describes control of the high-speed CAN module,
mode, slew rate, and wake-up.
Table 20. CAN Register
CAN
R/W
D3
D2
D1
D0
W
CANCLR
SC1
SC0
MODE
R
CANWU
CAN-F
CAN-UF
THERM-CUR
Reset Value
–
0
0
0
1
Reset Condition
(Write) (54)
–
POR
POR
POR
NR2N, STB2N
$010b
Notes
54. See Table 13, page 42, for definitions of reset conditions.
Table 21. CANCLR Control Bits
Logic
Description
0
No effect.
1
Re-enables CAN driver after TXD permanent dominant or RXD permanent recessive failure occurred. Failure
recovery conditions must occur to re-enable.
33742
44
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
HIGH-SPEED CAN TRANSCEIVER MODES
The MODE bit (D0) controls the state of the CAN interface, TXRX or Sleep mode (Table 22). SC0 bit (D1) defines the slew
rate when the CAN module is in TXRX, and it controls the wake-up option (wake-up enable or disable) when the CAN module is
in Sleep mode.
Table 22. CAN High-Speed Transceiver Modes
SC1
SC0
MODE
CAN Mode
(Pass 1.1)
0
0
0
CAN TXRX, Slew Rate 0
0
1
0
CAN TXRX, Slew Rate 1
1
0
0
CAN TXRX, Slew Rate 2
1
1
0
CAN TXRX, Slew Rate 3
x
1
1
CAN Sleep and CAN Wake-Up Disable
x
0
1
CAN Sleep and CAN Wake-Up Enable
x = Don’t care.
Table 23. CAN Register Status Bits
Name
Logic
CANWU
CAN-F
CAN-UF
THERM-CUR
Description
0
No CAN wake-up occurred.
1
CAN wake-up occurred.
0
No CAN failure.
1
CAN failure (55).
0
Identified CAN failure (55).
1
Non-identified CAN failure.
0
No overtemperature or overcurrent on CANH or CANL drivers.
1
Overtemperature or overcurrent on CANH or CANL drivers.
Notes
55. Error bits are latched in the CAN register.
INPUT / OUTPUT REGISTER (IOR)
Tables 24 through 26 contain the Input / Output Register information. Table 25 provides information about information HS control
in Normal and Standby modes, while Table 26 provides status bit information.
Table 24. Input / Output Register
IOR
R/W
D3
D2
D1
D0
W
–
HSON
–
–
R
V2LOW
HSOT
VSUPLOW
DEBUG
Reset Value
–
–
0
–
–
Reset Condition
(Write) (56)
–
–
POR
–
–
$011b
Notes
56. See Table 13, page 42, for definitions of reset conditions.
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
45
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
Table 25. HSON Control Bits
Logic
HS State
0
HS OFF, in Normal and Standby modes.
1
HS ON, in Normal and Standby modes. (57).
Notes
57. When HS is turned OFF due to an overtemperature condition, it can be turned ON again by setting the appropriate control bit to 1. Error
bits are latched in the IOR register.
Table 26. Input / Output Register Status Bits
Name
Logic
V2LOW
HSOT
VSUPLOW
DEBUG
Description
0
V2LTH > 4.0 V.
1
V2LTH < 4.0 V.
0
No HS overtemperature.
1
HS overtemperature.
0
VBF(EW) > 5.8 V.
1
VBF(EW) < 5.8 V.
0
SBC not in Debug mode.
1
SBC accepts command to go to Debug modes (no Watchdog).
WAKE-UP REGISTER (WUR)
Tables 27 through 29 contain the Wake-Up Register information. Local wake-up inputs L0 : L3 can be used in both Normal and
Standby modes as port expander, as well as for waking up the SBC from Sleep or Stop modes (Table 27).
Table 27. Wake-Up Register
WUR
$100b
Reset Value
Reset Condition (Write)
(58)
R/W
D3
D2
D1
D0
W
LCTR3
LCTR2
LCTR1
LCTR0
R
L3WU
L2WU
L1WU
L0WU
–
0
0
0
0
–
POR, NR2R, N2R, STB2R, STO2R
Notes
58. See Table 13, page 42, for definitions of reset conditions.
Wake-up inputs can be configured by pair. L0 and L1 can
be configured together, and L1 and L2, and L2 and L3 can be
configured together (Table 28).
33742
46
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
Table 28. Wake-Up Register Control Bits
LCTR3
LCTR2
LCTR1
LCTR0
L0 L1 : L1 L2 Config
L2 L3 : L3 L4 Config
x
x
0
0
Inputs Disabled
–
x
x
0
1
High Level Sensitive
x
x
1
0
Low Level Sensitive
x
x
1
1
Both Level Sensitive
0
0
x
x
–
0
1
x
x
High Level Sensitive
1
0
x
x
Low Level Sensitive
1
1
x
x
Both Level Sensitive
Inputs Disabled
x = Don’t care.
Table 29. Wake-Up Register Status Bits (59)
Name
Logic
Description
L3WU
0 or 1
L2WU
0 or 1
If bit = 1, wake-up occurred from Sleep or Stop modes; if bit = 0, no wake-up has
occurred.
L1WU
0 or 1
L0WU
0 or 1
When device is in Normal or Standby mode, bit reports the State on Lx pin (LOW
or HIGH) (0 = Lx LOW, 1 = Lx HIGH)
Notes
59. WUR status bits have two functions. After SBC wake-up, they indicate the wake up source; for example, L2WU set at logic [1] if wakeup source is L2 input. After SBC wake-up and once the WUR register has been read, status bits indicate the real-time state of the Lx
inputs (1 = Lx is above threshold, 0 = Lx input is below threshold). If after a wake-up from Lx input a watchdog tomato occurs before the
first reading of the WUR register, the LxWU bits are reset. This can occur only if the SBC was in Stop mode.
TIMING REGISTER (TIM1 / 2)
Tables 30 through 34 contain the Timing Register information. The TIM register is composed of two sub registers:
• TIM1 — Controls the watchdog timing selection as well as either the watchdog window or the watchdog time-out option
(Figure 28 and Figure 29, respectively). TIM1 is selected when bit D3 is 0 (Table 30). Watchdog timing characteristics are
described in Table 31.
• TIM2 — Selects an appropriate timing for sensing the wake-up circuitry or cyclically supplying devices by switching the HS on
or off. TIM2 is selected when bit D3 is 1 (Table 32). Figure 30, page 49, describes HS operation when cyclic sense is selected
Cyclic sense timing characteristics are described in Table 34, page 49.
Both subregisters also report the CANL and TXD diagnostics.
Table 30. TIM1 Timing and CANL Failure Diagnostic Register
TIM1
R/W
D3
D2
D1
D0
$101b
W
0
WDW
WDT1
WDT0
R
CANL2VDD
CANL2BAT
CANL2GND
TXPD
Reset Value
–
–
0
0
0
Reset Condition
(Write) (60)
–
–
POR, RESET
POR, RESET
POR, RESET
Notes
60. See Table 13, page 42, for definitions of reset conditions.
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
47
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
Table 31. TIM1 Control Bits
WDW
WDT1
WDT0
Timing (ms typ)
Parameter
0
0
0
9.75
Watchdog Period 1
0
0
1
45
Watchdog Period 2
0
1
0
100
Watchdog Period 3
0
1
1
350
Watchdog Period 4
1
0
0
9.75
Watchdog Period 1
1
0
1
45
Watchdog Period 2
1
1
0
100
Watchdog Period 3
1
1
1
350
Watchdog Period 4
Window Closed
No Watchdog Clear Allowed
No Window Watchdog
Watchdog Window enabled
(Window length is half the
Watchdog Timing).
Window Open for Watchdog Clear
Window Open for Watchdog Clear
Watchdog Timing x 50%
Description
Watchdog Period
(Watchdog Timing Selected by TIM1 Bit WDW = 0)
Watchdog Timing x 50%
Watchdog Period
(Watchdog Timing Selected by TIM1 Bit WDW =1)
Figure 29. Timeout Watchdog
Figure 28. Window Watchdog
Table 32. Timing Register Status Bits
Name
Logic
CANL2VDD
CANL2BAT
CANL2GND
TXPD
Failure Description
0
No CANL short to VDD.
1
CANL short to VDD.
0
No CANL short to VSUP .
1
CANL short to VSUP .
0
No CANL short to GND.
1
CANL short to GND.
0
No TXD dominant.
1
TXD dominant.
Table 33. TIM2 Timing and CANL Failure Diagnostic Register
TIM2
$101b
R/W
D3
D2
D1
D0
W
1
CSP2
CSP1
CSP0
R
CANL2VDD
CANL2BAT
CANL2GND
TXPD
Reset Value
–
–
0
0
0
Reset Condition (Write) (61)
–
–
POR, RESET
POR, RESET
POR, RESET
Notes
61. See Table 13, page 42, for definitions of reset conditions.
33742
48
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
Cyclic Sense Timing,
ON Time
HS ON
Cyclic Sense Timing, OFF Time
HS
10 µs
HS OFF
Lx Sampling Point
Sample
time
Figure 30. HS Operation When Cyclic Sense Is Selected
Table 34. TIM2 Control Bits
Parameter
CSP2
CSP1
CSP0
Cyclic Sense Timing (ms)
0
0
0
4.6
Cyclic Sense/FWU Timing 1
0
0
1
9.25
Cyclic Sense/FWU Timing 2
0
1
0
18.5
Cyclic Sense/FWU Timing 3
0
1
1
37
Cyclic Sense/FWU Timing 4
1
0
0
74
Cyclic Sense/FWU Timing 5
1
0
1
95.5
Cyclic Sense/FWU Timing 6
1
1
0
191
Cyclic Sense/FWU Timing 7
1
1
1
388
Cyclic Sense/FWU Timing 8
LOW POWER CONTROL REGISTER (LPC)
Tables 35 through 39 contain the Low Power Control Register information. The LPC register controls:
• The state of HS in Stop and Sleep modes (HS permanently OFF or HS cyclic).
• Enable or disable of the forced wake-up function (SBC automatic wake-up after time spent in Sleep or Stop modes; time is
defined by the TIM2 sub register).
• Enable or disable the sense of the wake-up inputs (Lx) at the sampling point of the Cyclic Sense period (LX2HS bit). (Refer to
Reset Control Register (RCR) on page 44 for details of the LPC register setup required for proper cyclic sense or direct wakeup operation.
The LPC register also reports the CANH and RXD diagnostic.
Table 35. Low Power Control Register
LPC
R/W
D3
D2
D1
D0
W
LX2HS
FWU
CAN-INT
HSAUTO
R
CANH2VDD
CANH2BAT
CANH2GND
RXPR
Reset Value
–
0
0
0
0
Reset Condition
(Write) (62)
–
POR, NR2R, N2R,
STB2R, STO2R
POR, NR2R, N2R,
STB2R, STO2R
POR, NR2R, N2R,
STB2R, STO2R
POR, NR2R, N2R,
STB2R, STO2R
$110b
Notes
62. See Table 13, page 42, for definitions of reset conditions.
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
49
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
Table 36. LX2HS Control Bits
Logic
Wake-Up Inputs Supplied by HS
0
No.
1
Yes. Lx inputs sensed at sampling point.
Table 37. HSAUTO Control Bits
Logic
Auto-Timing HS in Sleep and Stop Modes
0
OFF.
1
ON, HS Cyclic, period defined in TIM2 subregister.
Table 38. CAN-INT Control Bits
Logic (63)
Description
0
Interrupt as soon as CAN bus failure detected.
1
Interrupt when CAN bus failure detected and fully identified.
Notes
63. If CAN-INT is at logic [0], any undetermined CAN failure will be latched in the CAN register (bit D1: CAN-UF) and can be accessed by
SPI (refer to CAN Register (CAN) on page 44). After reading the CAN register or setting CAN-INT to logic [1], it will be cleared
automatically. The existence of CAN-UF always has priority over clearing, meaning that a further undetermined CAN failure does not
allow clearing the CAN-UF bit.
Table 39. LPC Status Bits
Name
CANH2VDD
CANH2BAT
CANH2GND
RXPR
Logic
Failure Description
0
No CANH short to VDD.
1
CANH short to VDD.
0
No CANH short to VSUP.
1
CANH short to VSUP.
0
No CANH short to GND.
1
CANH short to GND.
0
No RXD permanent recessive.
1
RXD permanent recessive.
33742
50
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
INTERRUPT REGISTER (INTR)
Tables 40 through 42 contain the Interrupt Register information. The INTR register allows masking or enabling the interrupt
source. A read operation identifies the interrupt source. Table 42 provides status bit information. The status bits of the INTR
register content are copies of the IOR, CAN, TIM, and LPC registers status content. To clear the Interrupt Register bits, the IOR,
CAN, TIM, and/or LPC registers must be cleared (read register) and the recovery condition must occur. Errors bits are latched
in the CAN register and the IOR register.
Table 40. Interrupt Register
INTR
R/W
D3
W
VSUPLOW
R
Reset Value
Reset Condition
(Write) (65)
D2
D1
D0
(64)
V1TEMP
CANF
VSUPLOW
HSOT
V1TEMP
CANF
–
0
0
0
0
–
POR, RST
POR, RST
POR, RST
POR, RST
HSOT-V2LOW
$111b
Notes
64. If only HSOT - V2LOW interrupt is selected (only bit D2 set in INTR register), reading INTR register bit D2 leads to two possibilities:
1. Bit D2 = 1: Interrupt source is HSOT.
2. Bit D2 = 0: Interrupt source is V2LOW.
HSOT and V2LOW bits status are available in the IOR register.
65. See Table 13, page 42, for definitions of reset conditions.
Table 41. Interrupt Register Control Bits
Name
CANF
VDDTEMP
HSOT - V2LOW
VSUPLOW
Description
Mask bit for CAN failures.
Mask bit for VDD medium temperature
(pre-warning).
Mask bit for HS overtemperature AND V2LTH < 4.0 V.
Mask bit for VBF(EW) < 5.8 V.
When the mask bit is set, the INT pin goes LOW if the appropriate condition occurs. Upon a wake-up condition from Stop mode
due to overcurrent detection (IDDS-WU1 or IDDS-WU2), an INT pulse is generated; however, INTR register content remains at 0000
(not bit set into the INTR register).
Table 42. Interrupt Register Status Bits
Name
VSUPLOW
HSOT
VDDTEMP
CANF
Logic
Description
0
No VBF(EW) < 5.8 V.
1
VBF(EW) < 5.8 V.
0
No HS overtemperature.
1
HS overtemperature.
0
No VDD medium temperature (pre-warning).
1
VDD medium temperature (pre-warning).
0
No CAN failure.
1
CAN failure.
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
51
TYPICAL APPLICATIONS
TYPICAL APPLICATIONS
SBC POWER SUPPLY
The 33742 is supplied from the battery line. A serial diode is necessary to protect the device against negative transient pulses
and from reverse battery. This is illustrated in Figure 31.
VPWR
Q1
33742
D1
R1
SW1
to L1
C1
C2
HS
Control
HS
L0
R2
SW2
L1
to L1
L2
Programmable
Wake-Up Input
L3
C7
V2CTRL
5.0 V/200 mA
VDD Monitor
C6
Rp
R5
VSUP Monitor
Dual Voltage Regulator
VSUP
Rp
V2
Mode Control
V2
VDD
C3
C4
Oscillator
C10
C5
INT
Interrupt
Watchdog
Reset
WDOG
RST
SPI Interface
MOSI
SCLK
MISO
MCU
CS
CANH
CANL
1.0 Mbps CAN
Physical Interface
SW3
TXD
RXD
GND
R3
Rd
Internal
Module
Supply
to L2
C8
SW4
Safe Circuitry
Clamp (1)
R4
Rd
to L3
C9
Connector
Legend
D1: Example: 1N4002 type
Q1: MJD32C
R1, R2, R3, R4: 10 kΩ
Rp, Rd: Example: 1.0 kΩ depending on switch type.
R5: 2.2 kΩ
C1: 10 µF
C2: 100 nF
C3: 47 µF
C4: 100 nF
C5: 47 µF tantalum or 100 µF chemical
C6, C7, C8, C9, C10: 100 nF
(1) Clamp circuit to ensure max ratings for HS (HS from
- 0.3 V to VSUP + 0.3) are respected.
Figure 31. SBC Typical Application Schematic
33742
52
Analog Integrated Circuit Device Data
Freescale Semiconductor
TYPICAL APPLICATIONS
The recommended value are as follows:
VOLTAGE REGULATOR
The SBC contains two 5.0 V regulators: a V1 regulator,
fully integrated and protected, and a V2 regulator, which
operates with an external ballast transistor.
VDD REGULATOR
The VDD regulator provides 5.0 V output, 2.0% accuracy
with current capability of 200 mA max. It requires external
decoupling and stabilizing capacitors. The minimum
recommended values are as follows:
•
•
•
•
C4: 100 nF
C3: 10 µF < C3 <22 µF, ESR < 1.0 Ω or
C3: 22 µF < C3 <47 µF, ESR < 5.0 Ω or
C3: ≥ 47 µF, ESR < 10 Ω
• 22 µF, ESR < 5.0 Ω
• 47 µF, ESR < 10 Ω
The V2 pin has two functions: it is a sense input for the V2
regulator and is a 5.0 V power supply input to the CAN
interface.
With respect to ballast transistor selection, either PNP or
PMOS transistors may be used. A resistor between base and
emitter (or source and drain) is necessary to ensure proper
operation and optimized performances. Recommended
bipolar transistor is MJD32C.
V2 REGULATOR: OPERATION WITHOUT
BALLAST TRANSISTOR
V2 REGULATOR: OPERATING WITH EXTERNAL
BALLAST TRANSISTOR
The V2 regulator is a tracking regulator of the VDD output.
Its accuracy relative to VDD is ±1.0%. It requires external
decoupling and stabilizing capacitors.
The external ballast transistor is optional. If the application
does not requires more than the maximum output current
capability of the VDD regulator, then the ballast transistor can
be omitted. The thermal aspects must be analyzed as well.
The electrical connection is illustrated in Figure 32.
No Connect
33742
VPWR
V2CTRL
VSUP
C1
V2
Components List
VDD
C2
C3
C1: 22 µF
C4
VDD
RST
RESET
MCU
C2: 100 nF
C3: >10 µF
C4: 100 nF
Figure 32. V2 Regulator Electrical Connection
FAILURE ON VDD, WDOG, RESET, AND INT PINS
The paragraphs below describe the behavior of the device
and of the INT, RST, and WDOG pins at power-up and under
failure of the VDD regulator.
POWER-UP AND SBC ENTERING NORMAL
OPERATION
After power-up the 33742 enters Normal Request mode
(CAN interface is in TXRX mode): VDD is on and V2 is off.
After 350 ms if no watchdog is written (no TIM1 register
write), a reset occurs and the 33742 returns to Normal
Request mode. During this sequence WDOG is active (low
level).
Once watchdog is written, the 33742 goes to Normal
mode: VDD is still on and V2 turns on, WDOG is no longer
active, and the RST pin is HIGH. If watchdog is not refreshed,
the 33742 generates a reset and returns to Normal Request
mode. Figure 33, page 54, illustrates the operation.
33742
Analog Integrated Circuit Device Data
Freescale Semiconductor
53
TYPICAL APPLICATIONS
VDD
Missing watchdog refresh
Watchdog refresh
Watchdog
refresh
SPI (CS)
WD
RST
350 ms
INT
SBC in
RESET
mode
SBC in Normal request
& reset modes
SBC in Normal
mode
Reset each 350 ms
SBC in Normal
request & reset
modes
Figure 33. Power up sequence, No W/D write at first
POWER UP AND VDD GOING LOW WITH STOP MODE AS DEFAULT LOW POWER MODE IS SELECTED
The first part of Figure 34 is identical to Figure 33. If VDD is pulled below VDD undervoltage reset (typ 4.6 V), say by an
overcurrent or short circuit (for instance, short to 4.0 V), and if a low power mode previously selected was Stop mode, the 33742
enters Reset mode (RST pin is active). The WDOG pin stays HIGH, but the high level (Voh) follows V1 level. The INT pin goes
LOW.
When the VDD overload condition is removed, the 33742 restarts in Normal Request mode.
Under voltage at VDD
(VDD < VRSTTH)
VDD
Watchdog refresh
SPI (CS)
350 ms
WD
RST
INT
SBC in
RESET
mode
SBC in Normal request
& reset modes
SBC in Normal
mode
SBC in Reset
mode
Reset each 350 ms
Figure 34. Undervoltage on VDD
33742
54
Analog Integrated Circuit Device Data
Freescale Semiconductor
TYPICAL APPLICATIONS
POWER-UP AND VDD GOING LOW WITH SLEEP MODE AS DEFAULT LOW POWER MODE IS SELECTED
The first part of Figure 35 is identical to Figure 34. If VDD is pulled below the VDD under voltage reset (typ 4.6V), say by an
overcurrent or short circuit (for instance, short to 4.0 V), and if the low power mode previously selected was Sleep mode and if
the BATFAIL flag has been cleared, the 33742 enters in Reset mode for a time period of 100 ms. The WDOG pin stays HIGH,
but the high level (Voh) follows VDD level. The RST and INT pins are low. After 100 ms the 33742 goes into Sleep mode, and
the VDD and V2 are off.
Figure 35 shows an example wherein VDD is shorted to 4.0 V, and after 100 ms the 33742 enters Sleep mode.
.
Under voltage at VDD
VDD
Watchdog refresh
SPI (CS)
100 ms
WD
RST
INT
SBC in
RESET
mode
SBC in Normal request
& reset modes
SBC in Normal
mode
Reset each 350 ms
SBC in Sleep mode
SBC in Reset mode for
100ms, then enter
Sleep mode
Figure 35. Undervoltage at VDD. Sleep mode selected.
CANH
R6
CH
CH
R5
R7
CANL (33742)
CANL
CAN Connector
CANH (33742)
CANH (33742)
CANH
CL
Legend
R5: 60 Ω
CL, CH: 220 pF
Figure 36. CAN Bus Standard Termination
CANL (33742)
CANL
CAN Connector
CL
CS
Legend
R6, R7: 30 Ω
CL, CH: 220 pF
CS: > 470 pF
Figure 37. CAN Bus Split Termination
33742
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PACKAGING
PACKAGE AND THERMAL CONSIDERATIONS
PACKAGING
PACKAGE AND THERMAL CONSIDERATIONS
The 33742 SBC is a standard surface mount 28-pin SOIC wide body. In order to improve the thermal performances of the
SOIC package, eight of the 28 pins are internally connected to the package lead frame for heat transfer to the printed circuit
board.
PACKAGING DIMENSIONS
Important For the most current revision of the package, visit www.freescale.com and perform a keyword search on the 98A
drawing number below.
DW SUFFIX
EG SUFFIX (PB-FREE)
28-LEAD SOICW
PLASTIC PACKAGE
98ASB42345B
ISSUE G
33742
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PACKAGING
PACKAGING DIMENSIONS
DW SUFFIX
EG SUFFIX (PB-FREE)
28-LEAD SOICW
PLASTIC PACKAGE
98ASB42345B
ISSUE G
33742
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57
PACKAGING
PACKAGING DIMENSIONS
EP SUFFIX (PB-FREE)
48-LEAD QFN
98ARH99048A
ISSUE F
33742
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PACKAGING
PACKAGING DIMENSIONS
EP SUFFIX (PB-FREE)
48-LEAD QFN
98ARH99048A
ISSUE F
33742
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PACKAGING
PACKAGING DIMENSIONS
EP SUFFIX (PB-FREE)
48-LEAD QFN
98ARH99048A
ISSUE F
33742
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ADDITIONAL DOCUMENTATION
THERMAL ADDENDUM (REV 2.0)
ADDITIONAL DOCUMENTATION
33742DW
33742EG
THERMAL ADDENDUM (REV 2.0)
Introduction
This thermal addendum is provided as a supplement to the MC33742
technical datasheet. The addendum provides thermal performance
information that may be critical in the design and development of system
applications. All electrical, application, and packaging information is
provided in the data sheet.
28-PIN
SOICW
Packaging and Thermal Considerations
The MC33742 is offered in a 28 pin SOICW exposed pad, single die
package. There is a single heat source (P), a single junction temperature
(TJ), and thermal resistance (RθJA).
TJ
=
RθJA
.
P
The stated values are solely for a thermal performance comparison of
one package to another in a standardized environment. This methodology
is not meant to and will not predict the performance of a package in an
application-specific environment. Stated values were obtained by
measurement and simulation according to the standards listed below.
DW SUFFIX
EG SUFFIX (PB-FREE)
98ASB42345B
28-PIN SOICW
Note For package dimensions, refer to
the 33742 data sheet.
Standards
1.0
Table 43. Thermal Performance Comparison
Thermal Resistance
[°C/W]
RθJA (1) (2)
41
RθJB (2) (3)
10
RθJA (1) (4)
68
RθJC (5)
220
Notes:
1. Per JEDEC JESD51-2 at natural convection, still air
condition.
2. 2s2p thermal test board per JEDEC JESD51-7.
3. Per JEDEC JESD51-8, with the board temperature on the
center trace near the center lead.
4. Single layer thermal test board per JEDEC JESD51-3.
5. Thermal resistance between the die junction and the
package top surface; cold plate attached to the package top
surface and remaining surfaces insulated.
0.2
1.0
0.2
* All measurements
are in millimeters
28 Pin SOICW
1.27 mm Pitch
16.0 mm x 7.5 mm Body
Figure 38. Surface Mount for SOIC Wide Body
non-Exposed Pad
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ADDITIONAL DOCUMENTATION
THERMAL ADDENDUM (REV 2.0)
RXD
TXD
VDD
RST
INT
GND
GND
GND
GND
V2
V2CTRL
VSUP
HS
L0
1
28
2
27
3
26
4
25
5
24
6
23
7
22
8
21
9
20
10
19
11
18
12
17
13
16
14
15
WDOG
CS
MOSI
MISO
SCLK
GND
GND
GND
GND
CANL
CANH
L3
L2
L1
A
33742 Pin Connections
28-Pin SOICW
1.27 mm Pitch
18.0 mm x 7.5 mm Body
Figure 39. Thermal Test Board
Device on Thermal Test Board
Material:
Single layer printed circuit board
FR4, 1.6 mm thickness
Cu traces, 0.07 mm thickness
Outline:
80 mm x 100 mm board area,
including edge connector for thermal
testing
Area A:
Cu heat-spreading areas on board
surface
Ambient Conditions:
Natural convection, still air
Table 44. Thermal Resistance Performance
A [mm²] RθJA [°C/W]
68
0
52
300
47
600
RθJA is the thermal resistance between die junction and
ambient air.
33742
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ADDITIONAL DOCUMENTATION
THERMAL ADDENDUM (REV 2.0)
Thermal Resistance [ºC/W]
80
70
60
50
40
30
x
20
RθJA
10
0
0
300
Heat spreading area A [mm²]
600
Figure 40. Device on Thermal Test Board RθJA
Thermal Resistance [ºC/W]
100
10
x RθJA
1
0.1
1.00E-03
1.00E-02
1.00E-01 1.00E+00 1.00E+01 1.00E+02 1.00E+03 1.00E+04
Time[s]
Figure 41. Transient Thermal Resistance RθJA,
1 W Step response, Device on Thermal Test Board Area A = 600 (mm2)
33742
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REVISION HISTORY
REVISION HISTORY
REVISION
DATE
DESCRIPTION OF CHANGES
•
•
•
•
Converted to Freescale format
Implemented Revision History page
Added Thermal Addendum (Rev. 1.0)
Changed Data Sheet from “Advanced” to “Final”
3.0
2/2006
4.0
6/2006
5.0
8/2006
• Added MCZ33742EG/R2 and MCZ33742SEG/R2 to the Ordering Information block
6.0
8/2006
7.0
10/2006
• Replaced label for Logic Inputs to Logic Signals (RXD, TXD, MOSI, MISO, CS, SCLK, RST,
WDOG, and INT) on page 7
• Removed all references to the 54 pin package.
• Removed Peak Package Reflow Temperature During Reflow (solder reflow) parameter from
Maximum Ratings on page 7. Added note with instructions from www.freescale.com.
8.0
2/2007
• Restated notes in Maximum Ratings on page 7
9.0
3/2007
• Text corrections to the included thermal addendum
10.0
5/2007
• Added 48 pin QFN package, Part Number PCZ33742EP/R2, and Outline Package drawing
Number 98ARH99048A.
33742
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Analog Integrated Circuit Device Data
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MC33742
Rev. 10.0
5/2007
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