(TriCore) Jul 31, 2012 | PDF

Transcription

Highly Integrated and Performance Optimized
32-bit Microcontrollers for Automotive and Industrial Applications
www.infineon.com/TriCore
2
Contents
TriCore™ Family Concept
04
TriCore™ Based Product Roadmap
06
PRO-SIL™ Safety Concept
07
TriCore™ for Powertrain Applications
08
TriCore™ for Safety Applications
18
TriCore™ for Body Applications
28
TriCore™ for Industrial Applications
30
AUDO Family System Architecture
36
AURIX™ Family System Architecture
44
Embedded Software (AUTOSAR etc.)
48
Development Support
52
Tool Partners
54
3
Evolution of TriCore™ Generations
In 1999, Infineon launched the first generation of AUDO (AUtomotive unifieD processOr)
family. Based on a unified RISC/MCU/DSP processor core, this 32-bit TriCore™ micro
controller was a computational power horse. And the company has evolved and optimized the concept ever since – culminating in what is now the fourth TriCore™ generation. Based on the TriCore™ architecture, the new AUDO MAX family (version 1.6) sets a
new performance standard for automotive microcontrollers. The TriCore™ success story
is continuing with the introduction of the AURIX™ multicore family. AURIX™ combines
easy‑to‑use functional safety support, strong increase in performance and a future-proven
security solution in a highly scalable product family.
AUDO
AUDO NG
(Next Generation)
AUDO Future
AUDO MAX
AURIX™
Infineon’s AUDO families are designed to handle highly complex algorithms. They are
the perfect match for gasoline and diesel engine management systems – meeting rising
market demands for lower emissions and higher efficiency levels. These trends are being
accelerated by the Euro 5 and Euro 6 standards and increasingly stringent CO2 regulations. In addition to engine management, the AUDO family is also ideal for applications
in hybrid and electric vehicles as well as for transmission, active and passive safety and
chassis applications. TriCore™-based products also deliver the versatility required for the
industrial sector, excelling in optimized motor control applications and signal processing.
Infineon’s broad product portfolio allows engineers to choose from a wide range of
memories, peripheral sets, frequencies, temperatures and packaging options. All of these
features are fully compatible across generations. The new core is platform-compatible
and can be used with software developed on existing controllers. Safety software is also
available to help manufacturers meet SIL/ASIL safety standards. All members of the
AUDO family are binary-compatible and share the same development tools. An AUTOSAR
library that enables existing code ready for integration is also available.
4
Family Highlights

Compatibility
and scalability

Lowest system cost

Industry benchmark system performance

Easy to use

Broad portfolio

Certiﬁed to automotive standards
Applications
Powertrain

Gasoline
Direct Injection
Multi-Port Injection

Diesel Direct Injection

Automatic Transmission – Hydraulic Control

Dry Double Clutch Transmission – Hydraulic Control

Dry Double Clutch Transmission – Electrical Control

Integrated (H)EV Control

(H)EV Battery Management System

Gasoline
Safety

Chassis
Domain Control
Power Steering (EPS)

Active Suspension Control System

Advanced Airbag System

Braking ECU

Multi-purpose Camera Configuration

Short Range RADAR (24GHz) System

Long Range RADAR (76/77GHz) System

Electric
Body
Industrial & Multimarket

Body
Domain Controller

Gateway

Advanced Body Applications

Mobile
Controller

Inverter

Wind Turbine Inverter

Solar Panel
5
TriCore™ Based Product Roadmap
Segment
Production
2013
2014
AUDO Family
130
AURIX™ Family
90
65
TC29x
TC1798
300MHz, 8M
300MHz, 4MB
TC1797
180MHz, 4MB
High End
TC1197
180MHz, 2/4MB
EBU
2015
TC290
300MHz, 8M
Bare Die
TC1793
270MHz, 4MB
TC1791
240MHz, 4MB
TC27x
TC1387
200MHz, 4M
150MHz, 3M
TC270
200MHz, 4M
Bare Die
TC1746
TC1768
133MHz, 3M
Bare Die
Mid Range
180MHz, 2.5M
Transmission
TC1784
TC26x
200MHz, 2.5M
180MHz, 2.5MB
TC1367
150MHz, 2MB
TC1782
180MHz, 2.5MB
TC1767
80/133MHz, 2MB
TC1167
TC260
200MHz, 2.5M
Bare Die
TC23x
133MHz, 1MB
200MHz, 2M
TC1728
133MHz, 1.5MB
TC1724
TC24x
133MHz, 1.5M
133MHz, 1.5MB
Low End
TC22x
133MHz, 1M
TC1736
TC21x
80MHz, 1MB
Companion
ICs
xx
6
100MHz, 0.5M
CIC61508
Safety IC
Engine, Safety & Chassis Body
Production
Transmission
Development
Industrial & Multimarket
Concept
Technology
PRO-SIL™
Infineon’s PRO-SIL™ Program, Designed to Protect
The functional complexity and levels of integration of real-time safety-critical applications
continue to increase exponentially. In addition, the product life cycle of these applications has to
meet stringent safety standards. Norms such as IEC 61508 and ISO 26262 mandate more robust
and comprehensive product development processes and functional safety concepts in automotive and industrial applications.
Infineon’s PRO-SIL™ safety program is designed to ease and speed up your automotive and
industrial design to comply with such standards. Across the full certification spectrum from Safety
Integrity Levels (SIL) 1 to 4 and Automotive Safety Integrity Levels (ASIL) A to D, our end-to-end
PRO-SIL™ approach will help you select the right hardware, software and functional safety
concepts to meet your design and compliance needs.
PRO-SIL™ Highlights
Broad hardware portfolio from sensors to microcontrollers, along with analog and power
management ICs providing SIL-supporting features.
For ISO 26262 PRO-SIL™ products, safety concepts are in place to enable the required safety
measures, testing, monitoring and diagnostics capabilities for your safety architecture.
Comprehensive safety software packages for seamless integration are in place, such as the
SafeTlib software for Infineon’s AURIX™ microcontroller family
Full range of support services – from consulting and design advice, including training, documentation and technical support – can be provided.
Safety-focused organization and project management based on Infineon’s Zero Defect Program,
Safety Culture and Quality Management System are in place.
Infineon’s PRO-SIL™ logo guides you to our products (HW, SW, Safety Documentation) with
SIL-supporting features. These products will simplify the implementation of customers’ system
design and improve time-to-market in achieving the desired functional safety level compliance.
PRO-SIL™ Benefits
Scalability
Enables system design in line with
diﬀerent IEC 61508 and ISO 26262 ASIL
Compliant to
IEC 61508, ISO 26262
CMM level 3
High diagnostic coverage
Satisfy requirement for startup
and runtime testing
Application independence
From chassis through body
to powertrain
AUTOSAR supported
Standard AUTOSAR can be used
Free evaluation version
From sales contact
7
TriCore™ for
Powertrain Applications
TriCore™ for Powertrain Applications
Energy Efficiency for Combustion Engine Vehicles
Electronic automotive components are key to raising fuel efficiency levels and cutting
emissions. The latest environment protection agency standards – Euro 5 and Euro 6
for passenger cars and Euro 3 and Euro 4 for motorcycles – are driving developments
in advanced engine management. TriCore™-based products can be found in improved
combustion technologies such as Homogeneous Charge Compression Ignition (HCCI)
as well as in direct injection, smart turbocharger and valve actuation applications. They
are also ideal for a range of innovative transmission technologies such as Double Clutch
Transmission (DCT) and modern Continuous Variable Transmission (CVT).
Driving Hybrid and Electrification
While excelling in fuel economy, being fun-to-drive and reducing CO2 emissions, Hybrid
Electric Vehicles (HEV) and Electric Vehicles (EV) have the drawbacks of higher cost,
limited drive-range and safety concerns (e.g. risk of battery over-charging). TriCore™
products, with their high performance, functional integration and application-based
SW support, are the ideal solution for (H)EV motor drives. TriCore™ offers less than 6%
CPU load at 180MHz frequency, for the complete Field Oriented Control (FOC) algorithm.
TriCore™ AURIX™ family offers multicore architecture, allowing inverter control, hybrid
torque management and DC/DC conversion to be done within one single microcontroller. Nevertheless, the TriCore™ AURIX™ family has built-in resolver functionality,
saving customers the cost of implementing an external resolver IC.
Often seen as master micro in battery balancing topology, the TriCore™ AURIX™ family
proposes a 32-bit standby domain combined with an integrated 8-bit standby controller,
essential for battery balancing under low power mode (e.g. holiday parking). Its unique
Secure Hardware Extension (SHE, details in next paragraph) feature prevents the main
CPU from illegal manipulation, making the billing for battery charging more trustworthy.
8
TriCore™ for
In-Vehicle Security and Tamper-Proofing Electronic Control
By introducing SHE (Secure Hardware Extension), Infineon has met the demand for improved
tamper-proofing and anti-theft protection of automotive control units as expressed by the
“HIS” (Manufacturers’ Software Initiative) Working Group on Security. This working group
consists of Audi, BMW, Daimler, Porsche and Volkswagen. Security solutions have so far been
confined to the software level or were coupled with additional external hardware, meaning
they were easily circumvented. Infineon offers more than this basic software protection
because AUDO MAX SHE monolithically integrates a secure keystore which cannot be read
without access authorization.
In addition, SHE has a cryptographic module, which encrypts access codes with up to
128 bits. SHE is complemented by an array of hardware functions which, for example,
prevent the application code from being illegitimately read and altered. Same risk can also
apply to the identification of ECUs in the system network. These are important functions for
tamper-proofing control units and protecting them against theft. Even if such an ECU were
to be fitted in another identical vehicle, its engine performance characteristics could not be
changed: the cryptographic individual key of an ECU has to match all the cryptographic keys
within the ECU network of a vehicle. And that key is safely stored in the SHE.
The AUDO MAX microcontroller family incorporating SHE currently comprises three products,
each with 4MB flash memory but differing in terms of clock frequency and package:
TC1798 (300MHz, BGA-516), TC1793 (270MHz, BGA-416) and TC1791 (240MHz, BGA‑292).
Infineon’s future 65nm eFlash microcontrollers will offer and significantly extend the SHE
functionality with a Hardware Security Module (HSM).
9
TriCore™ for
Application Example
Engine Management
Battery (KL30)
Key (KL15)
Typical Partitioning for GDI Discrete & Solenoid
1)
TLF35584
System Power Supply
4x
15A pk.
Pedal Position
TLE4997/98
48/60
x
SAR
Swirl/Tumble Flap
TLE4997/98
Throttle Position
TLE4998S
32-bit
Multicore/Lockstep
MCU
AURIX™
3/6
x
DS
e.g. TC26x/TC27x
200MHz
Manifold Air Pressure
KP21x, KP22x
SENT
Knock Sensor(s)
PSI5
Flash 2.5/4MB
RAM 240/472KB
ASCLIN, QSPI, HSSL,
MSB, SAR, DS,
GTM, SENT, PSI5
FlexRay, CAN,
ETHERNET
Temperature
Sensor(s)
Barometric Pressure
KP23x, KP25x
In-Cylinder Pressure
Sensors
GTM
Lambda Sensor
E-Ray
HSSL
Ethernet
2x
MSB
4x
CAN
H-Bridge for Throttle
TLE8209-2SA
H-Bridge for EGR
TLE8209-2SA
CAN
TLE7250G
...
FlexRay
TLE9221SX
LS-Switch Flex8
On-Oﬀ Outputs
TLE8108EM
LIN
TLE7259-2GE
2Ch.
LS-Switch Flex
PWM Outputs
Flex18
TLE8718SA
Powertrain CAN
Solenoid
Injectors
8A Ch.
(eGas) Throttle
8A Ch.
EGR Throttle
O2
8x 0.5A
Relays
4x 2.6A
ASCLIN
...
4x
3/10A
LS-Switch Flex
2x 5/9A
PWM, Current-Sense
Flex02
TLE8102SG
Crankshaft
TLE502x/492x
Camshaft
TLE492x/TLE498x
OptiMOS™
IPD35N10S3L-26
IPD20N06S4L-14
Fuel Level
TLE4997/98
Ignition Plugs
4x
QSPI
Quad LS GDI Driver
P&H
TLE6270R
EGR-Throttle Position
TLE4997/98
Low-Side Ignition
HSM
2x 2.6A
4x 1.7A
2x 1A
Solenoid
VVT
Solenoid
Relais
MIL
Lamp
1) In development
Gasoline Direct Injection
Application Features

Direct injection

Scalable software-based knock
detection

Variable valve control

Throttle and EGR control

Turbo charging

Catalyst after treatment

Start/stop system
Suggested Products

TC27x – TriCore™ 32-bit Microcontroller

10
System Benefits

Microcontroller
with best-in-class
real-time performance

Scalable platform – performance,
memory size and I/Os

Committed to reduce CO2 by 20%

Anti-theft protection and tuning protection

Increased knock detection accuracy
via DS-ADC

Enhanced communication (Ethernet)

Dedicated peripherals for powertrain
TriCore™ for
Application Example
Battery (KL30)/Key (KL15)
Sensor Supply
TLE4250-2
Engine Management
Supply ICs
TLE4271-2
(including Watchdog)
TLE4267
2x 5V/0.05A
5V/0.5A
Typical Partitioning for MPI discrete “Flex”
Safety Watchdog
CIC61508
Reset
4x
15A pk.
Pedal Position
TLE4997/98
TLE4997/98
Fuel Level
TLE4997/98
Ignition Driver
SPI
Swirl/Tumble Flap
TLE4997/98
Throttle Position
TLE4998S
Temperature
Sensor(s)
Bipolar Stepper
Motor Driver
TLE8444
2x
ADC
FAST
ADC
Barometric Pressure
KP23x, KP25x
8A Ch.
Idle Air Throttle
8A Ch.
AUDO MAX
32-bit MCU
TLE8209-2SA
e.g. TC1724
80MHz
LS-Switch Flex
2x 5/9A
PWM, Current-Sense
Flex2
TLE8102SG
LS-Switch Flex8
On-Oﬀ Outputs
TLE8108EM1)
Flash 1.0/1.5MB
RAM 76/112kB
SCI, SPI, MSB,
ADC, FADC,
GPTA, CAN
KP21x, KP22x
Ignition Plugs
(eGas) Throttle
4x 0.5A
Relays
4x 2.6A
2x 2.6A
LS-Switch Flex
PWM Outputs
Flex18
TLE8718SA
GPTA
MSB
Lambda Sensor
2x CAN
2x 1A
CAN
TLE7250GVIO
Camshaft
TLE492x/TLE498x
LIN
TLE7259-2GE
Canister Purge
Valve
EGR-Throttle
4x 1.7A
SCI
Crankshaft
Optional VR
Crankshaft
TLE502x/492x
MPI Injectors
VVT
Knock Sensor(s)
Sensors
O2
2Ch.
Swirl/Tumble
Flap
Relays
MIL
Lamp
Powertrain CAN
1) In development, samples available
Gasoline Multi-Port Injection

Gasoline port injection

Scalable software-based knock
detection

Catalyst after treatment

Start/stop systems

Cost-optimized for entry segment
System Benefits

Scalable
platform – performance,

Single voltage supply (EVR)

Focus on reducing CO2

Easy migration from ultra low-end to
mid-range applications

Best tool/partner support for all
development phases within V-Cycle
Suggested Products

TC1724 – TriCore™ 32-bit Microcontroller

11
TriCore™ for
Application Example
Engine Management
Battery (KL30)
Key (KL15)
Typical Partitioning for DDI Discrete
1)
TLF35584
System Power Supply
Pedal Position
TLE4997/98
TLE4997/98
Fuel Level
TLE4997/98
HSM
60/84
x
SAR
Swirl/Tumble Flap
TLE4997/98
Throttle Position
TLE4998S
Temperature
Sensor(s)
6/10
x
DS
Barometric Pressure
KP23x, KP25x
KP21x, KP22x
SENT
Knock Sensor(s)
PSI5
Sensors
GTM
Lambda Sensor
4-6
QSPI
32-bit
Multicore/Lockstep
MCU
AURIX™
HSSL
2-3
MSB
4-6
CAN
CAN
TLE7250G
...
FlexRay
TLE9221SX
LS-Switch Flex8
On-Oﬀ Outputs
TLE8108EM
LS-Switch Flex
PWM Outputs
Flex18
TLE8718SA
LIN
TLE7259-2GE
2Ch.
Glow Plugs
Piezo Injectors
8A Ch.
(eGas) Throttle
8A Ch.
EGR Throttle
O2
4x 0.5A
Relays
4x 2.6A
ASCLIN
...
6x 8A
LS-Switch Flex
2x 5/9A
PWM, Current-Sense
Flex02
TLE8102SG
Crankshaft
TLE502x/492x
Camshaft
TLE492x/TLE498x
FAST IGBT
e.g. IHD04N60RA/
IDH06N60RA
H-Bridge for EGR
TLE8209-2SA
Flash 4/8MB
RAM 472/728KB
ASCLIN, QSPI, HSSL,
MSB,SAR, DS,
GTM, SENT, PSI5
FlexRay, CAN,
ETHERNET
E-Ray
6x 8A
TLE8209-2SA
e.g. TC27x/TC29x
200–300MHz
Ethernet
PROFET™
BTS500x0-1EGA
BTS500x0-1TMA/B
BTS500x0-1TEA/B
2x 2.6A
4x 1.7A
2x 1A
Solenoids
VVT
Solenoid
Relays
MIL
Lamp
Powertrain CAN
1) In development
Diesel Direct Injection

Direct injection (Piezo/Magnetic)

In-cylinder pressure measurement

Hardware-supported security
enhancements

Turbo charging

Diesel particulate filter

‘Blue’ after-treatment support
(e.g. urea-based SCR)
Suggested Products

12
System Benefits

Microcontroller
with best-in-class
real-time performance

Scalable platform – performance,

Committed to reduce NOx and particulate matter in line with Euro 6 standard

Hardware-supported IP/anti-theft
protection and tuning protection

Increased accuracy with in-cylinder
pressure sensing via DS-ADC

Enhanced communication (Ethernet)

Dedicated peripherals for powertrain
TriCore™ for
Application Example
6-Speed Automatic Transmission
DC/DC Buck
LDO3
Tracker 2
Input Shaft Speed
TLE4951/541)
2x
ADC
FAST
ADC
Tap up/Tap down
Switches
AUDO MAX
32-bit MCU
High-Side Driver
PROFET ™ Family
BTS5014
e.g. TC1784
180MHz
LS-Switch Flex
Multi-Channel
TLE8104
Flash 2.5MB
RAM 176kB
SCI, SPI, MLI, MSB,
ADC, FADC, GPTA,
FlexRay, CAN
Temperature
Sensor
MLI
2x
eRay
GPTA
MSB
3x CAN
Powertrain
FlexRay
FlexRay
TLE9221SX
Typical Partitioning for Constant Current Control
Low-Side Driver
2x SPI
Output Shaft Speed
TLE4951/541)
PRNDL Switches
TLE4964
INH&
HDLD
TLE7368-3
“Super-Sonic”
3.3V/0.7A
5V/0.8A
Window Watchdog
Voltage Monitoring
Stand-By Supply
5V/0.05A
LDO2
Tracker 1
5V/0.1A
LDO1
1.3V/xxxA
Battery (KL30)
Key (KL15)
CAN
TLE7250GVIO
Diagnostic/Instrumentation CAN
1x
1x
Vehicle Speed Out
Solenoid Supply
4x 2A
ON/OFF Solenoids
Constant Current
Control
TLE82453SA1)
3x 1.2A
Variable Force
Solenoid/
Proportional Valve
Constant Current
Control
TLE82453SA1)
3x 1.2A
Variable Force
Solenoid/
Proportional Valve
or
TLE8242-2L
&
3x IPG20N06S4L-26
SCI
LIN
TLE7259-2GE
Diagnostic/
Instrumentation
Automatic Transmission–Hydraulic Control

Smooth gear shifting

Closely coupled with engine control via
high-speed CAN/FlexRay link

Support for four 3-phase DC-brushless
E-drives

High microcontroller junction bare die
temperature
System Benefits

Improved
and fast clutch control

Hot bare die supports modular
temperature-optimized TCU design

Hot bare die capabilities enable microcontrollers to be placed wherever they
are needed in the system

Digital Temperature Sensor (DTS) for
increased accuracy

Scalable product offering ensures
perfect fit for individual application
needs
Suggested Products

TC1746 – Bare Die TriCore™ 32-bit Microcontroller

TC1748 – Bare Die TriCore™ 32-bit Microcontroller

13
TriCore™ for
Application Example
6-Speed Double Clutch Transmission
DC/DC Buck
LDO3
Tracker 2
Input Shaft1 Speed
TLE4951/541)
2x
ADC
System Pressure
Powertrain
FlexRay
e.g. TC1782
180MHz
Constant Current
Control
TLE82453SA1)
3x 1.2A
Variable Force
Solenoid/
Proportional Valve
Flash 2.5MB
RAM 176kB
SCI, SPI, MSB,
ADC, FADC, GPTA,
FlexRay, CAN
Constant Current
Control
TLE82453SA1)
3x 1.2A
Variable Force
Solenoid/
Proportional Valve
2x
eRay
4x 2A
ON/OFF Solenoids
or
TLE8242-2L
&
3x IPG20N06S4L-26
MSB
3x CAN
FlexRay
TLE9221SX
Solenoid Supply
LS-Switch Flex
Multi-Channel
TLE8104
GPTA
Temperature
Sensor
1x
AUDO MAX
32-bit MCU
FAST
ADC
Shift Position Sensor
TLE4997/98/6x
Clutch Pressure
High-Side Driver
PROFET ™ Family
2x SPI
Input Shaft2 Speed
TLE4951/541)
PRNDL Switches
TLE4964
INH&
HDLD
TLE7368-3
“Super-Sonic”
3.3V/0.7A
5V/0.8A
Window Watchdog
Voltage Monitoring
Stand-By Supply
5V/0.05A
LDO2
Tracker 1
5V/0.1A
LDO1
1.3V/xxxA
Battery (KL30)
Key (KL15)
CAN
TLE7250GVIO
High-Current
Half-Bridge
BTN79xxB
SCI
M
Hydraulic Pump
LIN
TLE7259-2GE
Diagnostic/
Instrumentation
Dry Double Clutch Transmission–
Hydraulic Control
gear switching

Support for four 3-phase DC-brushless

E-drives (Dry-DCT)

Microcontroller offered as bare die with
junction temperature up to 170°C

Ultra-fast
Suggested Products

14
System Benefits

Improved
fast clutch control
set optimized for wet and dry
DCT designs

Continuous torque on wheels ensures a
more fun driving experience

Hot bare die capabilities enable microcontrollers to be placed directly where
they are needed in the system

Hot bare die supports modular

increased accuracy

Feature
TriCore™ for
Application Example
6-Speed Double Clutch Transmission
DC/DC Buck
LDO3
Tracker 2
3.3V/0.7A
PRNDL Switches
TLE4964
Shift Position Sensor
TLE4997/98/6x
3-Phase
Driver IC
TLE7185-1E
TLE7189F
TLE7189QK
AUDO MAX
32-bit MCU
3-Phase
Driver IC
TLE7185-1E
TLE7189F
TLE7189QK
e.g. TC1782
180MHz
FAST
ADC
Flash 2.5MB
RAM 176KB
SCI, SPI, MSB,
ADC, FADC, GPTA,
FlexRay, CAN
GPTA
FlexRay
TLE9221SX
3-Phase
Driver IC
TLE7185-1E
TLE7189F
TLE7189QK
MLI
2x
E-Ray
M
Rotor Position
iGMR Sensor
TLE5012B
1st
Clutch
M
Rotor Position
iGMR Sensor
TLE5012B
2nd
Clutch
M
Rotor Position
iGMR Sensor
TLE5012B
Even
Gears
MSB
3x
CAN
Powertrain
FlexRay
Battery (KL30)
Key (KL15)
2x
SPI
2x
ADC
Temperature
Sensor
Rotor Position
iGMR Sensor
TLE5012B
INH&
HDLD
TLE7368-3
“Super-Sonic”
Window Watchdog
5V/0.8A
Voltage Monitoring
Stand-By Supply
5V/0.05A
LDO2
Tracker 1
5V/0.1A
LDO1
1.3V/xxxA
Battery (KL30)
Key (KL15)
CAN
TLE7250GVIO
SCI
LIN
TLE7259-2GE
3-Phase
Driver IC
TLE7185-1E
TLE7189F
TLE7189QK
M
Rotor Position
iGMR Sensor
TLE5012B
Odd
Gears
OptiMOS™-T2 40V
24x IPD90N04S4-04
Diagnostic/
Instrumentation
Dry Double Clutch Transmission–
Electrical Control
gear switching

Ultra-fast

Support
for four 3-phase DC-brushless
E-drives (Dry-DCT)

Microcontroller oﬀered as bare die with
junction temperature of up to 170°C
Suggested Products

System Benefits

Improved
fast clutch control
set optimized for wet and dry
DCT designs

Continuous torque on wheels ensures a
more enjoyable driving experience

Hot bare die capabilities enable microcontrollers to be placed directly where
they are needed in the system

Hot bare die supports a modular

increased accuracy

Infineon e-Motor Driver

Feature
15
TriCore™ for
Application Example
Hybrid Electric Control
32-bit
Multicore/Lockstep
MCU
AURIX™
Transmission
e.g. TC27x
4MB Flash
472KB RAM
4x CAN
Diverse
Lockstep Core
PWM
1x FlexRay
PMSM
A
N
PWM
GTM
PWM
EiceSIL™
Driver IC
IGBT
Hybrid Pack
1 or 2
B
S
C
1x Ethernet
DC/DC Converter
Trigger
PWM
ADC
Diverse
Lockstep Core
200MHz
CPU1
8x
SAR-ADC
Resolver
200MHz
CPU0
Motor Control
Hybrid Domain Control
DC/DC converter
Resolver speed & position
PWM generation
Space vector
modulation
Synchronized 3-phase
current measurement
Resolver interface
200MHz
CPU2
Speed
&
Position
6x
DS-ADC
Integrated (H)EV Control

Multicore & Lockstep architecture

Direct resolver-to-microcontroller

Superior performance

Customized PWM pattern generation
Suggested Products

16
System Benefits

ISO
26262 ASIL-C/D compliant

No resolver IC needed, lower
system cost

Enables sub-system integration
(driving HCU + Inverter + DC/DC)

Fine motor tuning
TriCore™ for
Application Example
TLE8000
#6
32-bit
Multicore/Lockstep
MCU
AURIX™
RS485
Transceiver
Secondary IBCB
(Optional)
e.g. TC26x
TLE8000
#5
2.5MB Flash
240KB RAM
4x CAN
TLE8000
#4
XC2000
16-bit MCU
Diverse
Lockstep Core
1x FlexRay
PWM
PWM
GTM
PWM
4x QSPI
TLE8000
#3
1x I2C
200MHz
CPU0
TLE8000
#2
200MHz
CPU1
SAR-ADC
Primary IBCB
TLE8000
#1
8-bit
Standby
Controller
RS485
Transceiver
DS-ADC
-200V
+200V
(H)EV Battery Management System

Multicore & Diverse Lockstep Core
architecture

Fast communication interface

Integrated low-power 8-bit standby
controller

HW Security Module (HSM)
System Benefits

ISO
26262 ASIL-C/D compliant

IBCB network architecture

Ring topolgy in event of failure

Balancing & monitoring over
long parking period

Charge-billing verification

Active & passive balancing
Suggested Products

TLE8000 – battery balancing IC
17
TriCore™ for
Safety Applications
TriCore™ for Safety Applications
AURIX™ Made for Safety
The AURIX™ architecture has been developed according to an audited ISO 26262
compliant process and designed to efficiently meet ASIL-D on an application level. The
platform uses up to 2 cores in TriCore™ Diverse Lockstep Core technology, a diverse
lockstep architecture combined with cutting-edge safety technology, such as safe
internal communication buses or distributed memory protection system. Innovative
encapsulation techniques allow the integration of software with various safety levels
(QM to ASIL-D) from different sources, thereby significantly reducing system complexity.
Thanks to this optimized approach, multiple applications and operating systems (such
as steering, braking, airbag and advanced driver assistance systems) are seamlessly
hosted on a unified platform. This leads to productivity gains of up to 30%, resulting in a
smaller development outlay and reduced time-to-market for our customers.
Furthermore, Infineon extends the microcontroller safety roadmap with devices
dedicated to the Advanced Driver Assistance System (ADAS) segment, such as radar
or camera applications. Innovation has been focused on system partitioning in order
to further integrate system functionality and consequently reduce the complexity and
area, providing our customers with highly optimized solutions. The new devices include
high‑speed interfaces, integrated hardware acceleration and enhanced ECU validation
and instrumentation tools. All ADAS devices have been designed in accordance with
the ISO 26262 safety methodology, meaning that they can be involved in automatic
decisions to assist drivers, such as emergency braking.
18
TriCore™ for
Safety Applications
AURIX™ Made for Scalability
Thanks to its arket-leading expertise, Infineon has translated customer demands
for individual scalability into a universal product roadmap. Designed to optimize its
customers’ investment, the AURIX™ family comes with a comprehensive range of fully
modular components, thereby ensuring long-term design flexibility. The devices range
in the ultra high-end from a 300MHz triple-core device with 8MB of embedded Flash to
a 200MHz triple core with 4MB of embedded Flash to a 200MHz dual-core device with
2.5MB of embedded Flash right down to 130MHz and 80MHz single-core and singlecore lockstep devices with 1.5MB, 1MB and 0.5MB of embedded Flash. The package
portfolio includes a BGA-516 package with a ball-compatible BGA-292 package (I/O
subset), and compatible QFP-176, QFP-144, QFP‑100 to QFP-64 packages.
19
TriCore™ for
Safety Applications
Application Example
+12V from Battery
4x
Steering Angle
Sensor
2x iGMR
Sensor
TLE5012B
Wheel Speed
Sensor
TLF355841)
Diﬀerential
Hall IC
TLE4941/42
Steering
Angle
Chassis
Domain
Controller
System Power Supply
4x Speed
Vehicle
Stability Control
ECU
Electric
Power Steering
ECU
Steering
Toque
Torque Sensor
TLE4997/98
TLE4906
Chassis CAN-Bus
CAN
Transceiver
TLE7250G
TLE6251D
32-bit
Multicore
Lockstep
MCU
AURIX™
2–4x
X
Y
Z
Pos. Sensor
Linear Hall
TLE4997
TLE4998
Inertia
Sensors
Position
Sensor
Interface
ωx
ωy
Vehicle Level
FlexRay
Transceiver
TLE9221SX
1) In development
ωz
FlexRay
Chassis Domain Control
The new TriCore™ family AURIX™ with state-of-the-art safety features enables systems to
achieve the highest safety level ASIL-D, which is already required in contemporary domain
control systems. The latest diverse lockstep technology with clock delay (Diverse Lockstep
Core) reduces the software overhead significantly and enables fast time-to-market. Thanks to
a scalable multicore system and innovative encapsulation techniques, this supports the
integration of software with mixed-criticality levels from different sources, thereby allowing
multiple applications and operating systems to be seamlessly hosted on a unified platform.
Application Features AURIX™
DSP functionality

Best-in-class performance: triple
TriCore™ with up to 300MHz per core

Supporting floating point and fix point
with all cores

Up to 2.7MB of internal RAM

Communication peripherals:
CAN, LIN, FlexRay, Ethernet

Innovative single supply 5V or 3.3V

External memory interface

ISO 26262 conformance to support
safety requirements up to ASIL-D

Availability of AUTOSAR 4.x

TriCore™
20
System Benefits
communication with FlexRay
and Ethernet

Highest available performance with
integrated FPU

Flexible DMA unit

Scalability over Flash, RAM and peripherals

Proven safety concept to support
ISO 26262

Innovative supply concept leads to
best‑in‑class power consumption

Advanced
TriCore™ for
Safety Applications
Application Example
+12V from Battery
TLF355841)
System Power Supply
Torque Sensor
TLE4997/98
TLE4906
32-bit
Multicore
Lockstep
MCU
AURIX™
Steering
Torque
3-Phase
Driver IC
TLE7183
TLE7185
TLE7189
TLE9180
M
Rotor Position
iGMR Sensor
TLE5009/12
Current Sense
(Shunt Substitute)
TLE4997/98
Electric
Power
Steering
ECU
CAN
Transceiver
TLE7250G
TLE6251D
OptiMOS™-T2 40V
8x IPB180N04S4-01
Rotor Position/Current Sense
HS-CAN
1) In development
Electric Power Steering (EPS)
The new TriCore™ family AURIX™ with state-of-the-art safety features enables systems
to achieve the highest safety level ASIL-D, which is already required in contemporary steering
systems.
The latest diverse lockstep technology with clock delay (Diverse Lockstep Core) reduces the
software overhead significantly and enables fast time-to-market.
Its rich scalability meets a variety of different electric power steering system demands.
Key Features AURIX™
256KB–8MB

Performance from 40MHz–3x 300MHz

Ta = -40°C ... 145°C

Dedicated peripheral set: CAN, SPI, FlexRay

Advanced timer unit for totally flexible PWM
generation and hardware input capture

Redundant flexible 12-bit ADC

Hardware SENT interface for low CPU load

Hardware-focused safety concept for
reduced SW overhead

Safety software: Infineon SafeTcore library

ISO 26262 conformance to support safety
requirements up to ASIL-D

Flash
System Benefits
over Flash, RAM and peripherals
offering the best cost-performance ratio

Serves all kinds of EPS systems, such as
column or belt drive

ISO 26262

Scalability
21
TriCore™ for
Safety Applications
Application Example
+12V from Battery
Suspension
Control ECU
TLF355841)
System Power Supply
+12V
4x
4-Channel
LS-Switch IC
TLE8104E
Valve
Solenoid
+12V
2–4x
Pos. Sensor
Linear Hall
TLE4997/98
Vehicle
Level
32-bit
Multicore
Lockstep
MCU
AURIX™
Vehicle Level
6-Channel
LS-Switch IC
TLE6232GP
6x
+12V
Quad Constant
Current
Control IC
TLE7242G
1) In development
HS-CAN-Bus
Steering Angle Speed
y, z Acceleration
Vertical Acceleration
FlexRay
Transceiver
TLE9221SX
Proportional
Valve Solenoid
4x
N 4x IPD25N06S4L-30
or
2x IPG20N06S4L-26
+12V
CAN
Transceiver
TLE7250G
TLE6251D
Valve
Solenoid
Octal Constant
Current
Control IC
TLE8242-2L
Proportional
Valve Solenoid
8x
N 8x IPD25N06S4L-30
or
4x IPG20N06S4L-26
FlexRay
Active Suspension Control System
The new TriCore™ family AURIX™ with state-of-the-art safety features enables systems
to achieve the highest safety level ASIL-D, which is already required in contemporary
suspension systems.
The latest diverse lockstep technology with clock delay (Diverse Lockstep Core) reduces
the software overhead significantly and enables fast time-to-market .
The scalability supports an optimized fit in order to meet different OEM specifications.
DSP functionality

Best‑in‑class performance:
triple TriCore™ with up to
300MHz per core

Supporting floating point and fix point
with all cores

Communication peripherals:
CAN, LIN, FlexRay, Ethernet

TriCore™

Innovative
single supply 5V or 3.3V
range of packages from
64-Pin – 516-Pin

Wide
22
System Benefits

ISO 26262

best‑in‑class power consumption and
saves external component costs

Scalability
TriCore™ for
Safety Applications
Application Example
LIN
LIN
Transceiver
ADXL180
Door Pressure Sensor
KP200/KP108
Pressure Sensor
KP200/KP108
Sensor SPI Bus
Pedestrian Protection Sensoric
ADXL180
PSI5
Satellite
Sensor
Interface
CAN
Transceiver
TLE7250G
TLE6251D
CAN
Transceiver
TLE7250G
TLE6251D
32-bit
Multicore
Lockstep
MCU
AURIX™
Pressure Sensor
KP200/KP108
Door Pressure Sensor
KP200/KP108
CAN
Squib Driver
8 Channels
TLE8758
Yaw, Roll, Pitch
+
Low-g
x-, y-, zSensors
4/8
Channels
Squib
Squib
Squib
Squib
Squib
Squib
Squib
Squib
Squib
Squib
Squib
8/12
Channels
Squib
Squib
Squib
Squib
Squib
Squib
Squib
Squib
Saving
Engine
Vfire
Squib
Squib
Driver
ADXL278
Vsat
Airbag System IC
TLE8771/72
Airbag ECU
Firing SPI Bus
Reversible Belt
Pretensioners
CAN
Vlogic
Power Supply
2 Buck, Boost, Linear, Watchdog, Reset,
Buckle Switch IF
Buckle Switch
TLE4976
Buckle Switch
TLE4976
Warning Lamp
Airbag Oﬀ
+12V from Battery
Advanced Airbag System
achieve the highest safety level up to ASIL-D.
The scalability allows the selection of a single-core solution for basic airbag systems and
multicore solutions for airbag systems with an integrated sensor cluster.
The best cost-performance fit is offered by the wide range of Flash, performance and peripheral
options available within the AURIX™ family.
MCU family from single to
multicore

Flash 256KB–8MB

Embedded EEPROM

Dedicated peripheral set:
CAN, SPI, FlexRay

reduced SW overhead

Safety software: Infineon SafeTcore
library

Scalable
System Benefits

ISO 26262

Scalability
23
TriCore™ for
Safety Applications
Application Example
ABS/VSC ECU
3x MOSFET
IPD15-N06S2L-64
Pump
Braking System IC
Multiple
Supply Control
w. Reset
Generation
Window/Signature
Watchdog
Supervision
Safety Logic
Pump MOSFET
Driver
MOSFET
IPB80Nxxx
Safety MOSFET
Driver
MOSFET
IPD60Nxxx
M
Solenoid
4x
Wheel Speed Sensor
TLE4941/42
TLE5041
Wheel Speed
Sensor Supply
&
Signal
Conditioning
SPI
32-bit
Multicore
Lockstep
MCU
AURIX™
Solenoid
Solenoid
Driver
2x
TLE6217
K-Line
Transceiver
Sensor
Cluster
(ESC only)
Solenoid
Solenoid
Solenoid
Solenoid
High Voltage
Outputs
High Voltage
Enable Outputs
Solenoid
Solenoid
Solenoid
CAN
Transceiver
TLE7250G
TLE6251D
Solenoid
Driver
TLE6217
ESC
only
Solenoid
Solenoid
Solenoid
HS-CAN
Braking ECU
achieve the highest safety level ASIL-D, which is already required in contemporary braking systems. The latest diverse lockstep technology with clock delay (Diverse Lockstep
Core) reduces the software overhead significantly and enables fast time-to-market.
The scalability supports an optimized cost-performance fit for basic ABS systems up to
highly-integrated ESC systems.
MCU family with diverse lockstep

Flash 256KB–8MB

reduced SW overhead

SENT interface for low CPU load

Safety software:
Infineon SafeTcore library

Scalable
24
System Benefits
over Flash, RAM,
performance and peripherals leads
to an optimized cost-performance fit

ISO 26262 validated by 3rd party

best‑in‑class power consumption and
saves external component costs

Scalability
TriCore™ for
Safety Applications
Application Example
+12V from Battery
TLF355841)
System Power Supply
e.g. Aptina OmniVision
External RAM
2.4MB
Optional
CIF
HSSL
Ext. Memory IF
CIF
IIC
Automotive
High
Dynamic
Range Camera
32-bit
Multicore
Lockstep
MCU
AURIX™
CAN
Transceiver
TLE7250G
TLE6251D
Optional
“Number Cruncher”
e.g. for
Pedestrian
Detection
FlexRay
Transceiver
TLE9221SX
Ethernet
Transceiver
Multi-purpose
Camera ECU
Optional
1) In development
Multi-purpose Camera Configuration
The new TriCore™ family AURIX™ will enhance classic safety features with dedicated
features to cater for multi-purpose camera systems.
The combination of new features, such as a picture pre-processing unit, camera interface,
DSP functionality and increased SRAM, in conjunction with outstanding safety features
enables a high level of scalability in order to achieve the best cost-performance ratio.
DSP functionality

Best-in-class performance: triple TriCore™
with up to 300MHz per core

Supporting floating point and fix point with
all cores

Up to 2.7MB of internal RAM for picture
information storage

Picture
System Benefits
scalability option allows a
dedicated performance feature fit for
multiple camera applications from
single automatic high beam systems up
to multi-function systems (lane departure warning, forward collision warning,
traffic sign recognition, pedestrian
recognition etc.)

Camera

High

TriCore™
pre-processing unit
interface up to 100MHz

High
integration leads to reduced
complexity

Support for ISO 26262 decisions such
as emergency braking

25
TriCore™ for
Safety Applications
Application Example
+12V from Battery
24GHz
Short Range
Radar
TLF355841)
System Power Supply
Targets
Low-noise
Supply
Coarse DAC
Fine DAC
Tx1
Y
Y
Y
Y
Y
Y
32-bit
Multicore
Lockstep
MCU
AURIX™
200MHz
Input Timer
BGT24ATR12
Y
100MHz
PWMs
Rx1
SPI
Acquisition
RAM
4x
ADCs
FFT
Engine
Rx2
Rx3
Rx4
BGT24AR2
MUXes
Rx5
Rx6
1) In development
CAN
Transceiver
TLE7250G
TLE6251D
BGT24AR2
HS-CAN
FlexRay
Transceiver
TLE9221SX
FlexRay-Bus
Short Range RADAR (24GHz) System
The new TriCore™ family AURIX™ will enhance classic safety features with dedicated
features to serve the needs of 24GHz RADAR systems.
The combination of new features and increased SRAM, in conjunction with outstanding
safety features, enables a high level of integration and reduction of complexity.

Up to 752KB RAM for RADAR image storage

RADAR signal processing with windowing
functionality

Flexibility in RADAR signal acquisition with
4x internal ADCs

Possibility to connect external ADCs
(Interface to connect up to 16-bit ADCs)

High-precision input timers

High-precision output timers for DAC

ISO 26262 compliance to support safety

26
System Benefits

High integration leads to significant
cost savings

High integration leads to reduced
complexity

ISO 26262 compliance supports safe
input for functions such as emergency
braking

TriCore™ for
Safety Applications
Application Example
+12V from Battery
Targets
Low-noise
Power Supply
TLF355841)
System Power Supply
Radar ICs
Tx1
Y
Tx2
Y
Y
RCC1010
Wave Form
Generator
SPI
RRN7740
Quad Channel
76/77GHz
Receiver
LNA
ADC
32-bit
Multicore
Lockstep
MCU
AURIX™
Rx1
Y
Y
RTN7730
76/77GHz
Transmitter
& local Oscillator
Rx4
Acquisition
RAM
Y
CAN
Transceiver
TLE7250G
TLE6251D
76-77GHz
Proximity
RADAR
ECU
FlexRay
Transceiver
TLE9221SX
HS-CAN
FlexRay-Bus
1) In development
Long Range RADAR (76/77GHz) System
The new TriCore™ family AURIX™ will enhance classic safety features with dedicated features
to serve the needs of 77GHz RADAR systems.
The combination of new features and increased SRAM, in conjunction with outstanding safety
features, enables a high level of integration and reduction of complexity.

TriCore™ DSP functionality

Best-in-class performance: triple TriCore™
with up to 300MHz per core

Up to 2.7MB RAM for RADAR image storage

RADAR signal processing with windowing
functionality

Flexibility in RADAR signal acquisition with
4x internal ADCs

Possibility to connect external ADCs
(Interface to connect up to 16-bit ADCs)

High-precision input timers

High-precision output timers for DAC

ISO 26262 compliance to support safety

System Benefits

High
integration leads to significant
cost savings

High integration leads to reduced
complexity

ISO 26262 compliance supports safe input
for functions such as emergency braking

27
TriCore™ for
Body Applications
TriCore™ for Body Applications
Body electronics systems embrace a broad variety of applications inside the car,
covering comfort, safety and security as well as high-performance computing and
in-vehicle networking. This leads to the key strengths of the AURIX™ family:

AUTOSAR – With AUTOSAR 4, multicore architectures can be easily designed into
vehicles. Infineon is one of the first implementers of a multicore architecture with
AURIX™ ready for AUTOSAR 4.x. Furthermore, Infineon also provides the MCAL drivers
developed according to CMM 3 level.

Power Consumption – Innovative supply concept automatically adapts the power
consumption to the actual performance needs. Furthermore, the new trend of pretended networking and ECU degradation is actively supported.

Enhanced communication – As cars incorporate an increasing amount of
electronics, the body electronics module’s responsibilities increase to handle the
additional components and message traffic. Because of the gateway functionality of
the BCM, the AURIX™ has enhanced communication capabilities to support communication between CAN, LIN, FlexRay™ and Ethernet buses.

Safety – The trend is toward the integration of safety targets in the requirements of
advanced body systems such as lighting, BCM etc. To achieve the required ASIL level
according to ISO2626, AURIX™ has the capability to cover targets up to the highest
safety integrity level ASIL-D.

Security – In the future, the need for a high level of security will also expand into
body applications. Cars are expected to hold even more information as they become
smart cards on wheels to simplify financial transactions at gas pumps, charging stations, parking lots, toll booths, drive-through shops and more. The vehicle will act as a
smart card and pay your fee/fare – sometimes automatically. Hardware-based security
is more robust than software-only security. AURIX™ provides a dedicated module,
HSM (Hardware Secure Module), to cover the highest level of security.
28
TriCore™ for
Body Applications
Application Example
Left
Front-Light Control
Right
Front-Light Control
PROFET™ – Single, Dual, Quad Channel High-Side Driver
SPOC – SPI based Multichannel High-Side Driver Family
I/O
FlexRay
Ethernet
PHY
Relays
CAN Bus
+12V from
Battery
32-bit
Multicore/Lockstep
MCU
AURIX™
TLE7250G
TLE6251-3G
TLE6251D
TLF355841)
TC1.6E
I/O
TLE7259-2GE
TLE7258LE
TLE7269G
LIN Bus
Communication
TLE7250G
TLE6251-3G
TLE6251D
HITFET™
Low-Side
Driver
Interior Light
Logic Signals on VBAT Level
e.g. Switched VBAT Rails
Ambient
LEDs
Basic LED
Current Sources
for LED
Applications
Supply
CAN Bus
SPIDER
SPI based
Multichannel
High-/Low-Side
Driver
TC1.6P
+
Diverse Lockstep Core
TLE9221SX
SPI
Ethernet
LEDs
SPI
Interior
LEDs
I/O
SPI
PROFET™ – Single, Dual, Quad Channel High-Side Driver
SPOC – SPI-based Multichannel High-Side Driver Family
Left
Rear-Light Control
Right
Rear-Light Control
1) In development
High-Feature Body Control Module with
Integrated Gateway Functionality
Body Control Module (BCM) application comprising internal and external lighting systems, as
well as control of relays and voltage rails and further comfort functions such as door and wiper
control. The central gateway manages all internal interfaces (i.e. motor management, in-car
entertainment, dashboard or convenience control) and communication with external interfaces
for after-sales software updates. The AURIX™ multicore concept enables the integration of two
applications in one device, e.g. BCM and Gateway
Key Features

Scalable MCU family from single to multicore

Encapsulation feature allows software
development without interference for
multiple applications

Embedded EEPROM

Advanced communication peripherals:
CAN, LIN, SPI, FlexeRay, Ethernet

ISO26262 conformance to support safety

System Benefits

Enables pretended networking
and ECU degradation

High integration leads to significant
cost savings

High integration leads to
reduced complexity

ISO26262 compliance supports
ASIL requirements

Innovative supply concept leads
to best-in-class power consumption
29
TriCore™ for
Industrial Applications
TriCore™ for Industrial Applications
High Performance for Demanding Applications
While the primary focus of the TriCore™-based microcontrollers is on the automotive
market, they also provide significant advantages for industrial applications. Featuring a
combination of high calculation performance, large memory sizes, a comprehensive set
of peripherals and integrated safety & security measures, the MCUs can meet even the
most demanding application requirements.
The devices of the AUDO MAX family reach more than 400 DMIPS at clock rates of up to
300MHz and combine MCU & DSP instructions with an integrated FPU. Memory sizes
reach up to 4MB Flash and 192KB of SRAM and all memory is protected by hardware
Error Correction Code (ECC).
The integrated peripheral set is primarily targeted toward motor control and power conversion providing up to 4 ADCs, an additional fast ADC and a full set of high-performance
timers – namely the General Purpose Timer Array (GPTA). This is is one of the very few in
the industry that is able to drive the upcoming three-level inverter topologies.
30
TriCore™ for
Providing Security and Functional Safety
In a global economy, IP protection plays an increasingly important role. This demand
is accounted for by the integration of special security modules providing the required
means of safe key storage, along with secure boot and encryption on the hardware level.
As one of the leaders in functional safety, Infineon has designed the TriCore™ MCUs
to meet the growing demand for functional safety in the industrial market as specified
in IEC 61508. Via our cooperation partner Hitex, Infineon offers a complete package
comprising a microcontroller, external signature watchdog (CIC61508), software and
documentation, achieving safety integrity levels up to SIL3.
The next generation of TriCore™-based microcontrollers – AURIX™ – will provide
another significant performance milestone by integrating up to three cores in one
device. The multicore concept is targeted at running concurrent applications in parallel.
Some of the integrated cores integrate lockstep functionality and the peripherals can be
allocated to individual cores. This allows running a combination of safety-critical tasks,
such as controlling an inverter, with non-critical tasks, such as network communication,
on a single MCU.
31
TriCore™ for
Application Example
Power Supply
TLE7368
CAN Transceiver
TLE62xx
> 50x PWM
4x FREQ
CAN
Intelligent Safety
Watchdog
CIC61508
GPTA
CCU6
ADC
SDRAM
EBU
Low-Side Switch
TLE6244
MSC
32-bit MCU
TC1793N
IO
FADC
48x ADC
> 100x GPIO
Condition
Monitoring Sensor
Mobile Controller

Closed-loop control of solenoid currents

Multitasking
to drive hydraulic and
electric actuators

IEC 61131-3 support

GNU toolchain

Ready for harsh environments

Compliance with IEC 61508 for Safety

Integrity Level (SIL) 1 to 3
Suggested Products

TC1793N – TriCore™ 32-bit Microcontroller

32
System Benefits

High-speed 270MHz asymmetric
dual core

Up to 50 Pulse-Width-Modulated (PWM)
outputs

Three Analog to Digital Converters (ADC)

12-bit, up to 44 channels

Four fast ADC inputs 10-bit
(262.5ns @ fFADC = 80MHz)

Four frequency inputs

Fast, 10-bit ADC

Industrial and automotive temperature
range

SAE J1939 supported by four CAN nodes

32KB EEPROM for parameter

Hitex PRO-SIL™ support
TriCore™ for
Application Example
IGBT
EconoPIM™
Power Supply
TLE7368
M
~
EiceDRIVER™
R
PWM
CAN Transceiver
TLE62xx
Fieldbus/FPGA
EBU
32-bit MCU
TC1784N
ADC
EBU
IO
FADC
Inverter

Multi-axis controller for two 3-phase
complementary PWMs

Multiple
modulation strategies (SVPWM,
DPWM, Soft-PWM, direct torque control)
to support requirements for reduced noise
emissions and increased efficiency

Ready for four Q-inverters, matrix-inverters

Field-oriented control with less than
10% CPU load

Multiprocessor support for reliability and
safety

Support for 3-Level inverter topologies
System Benefits

Generic flexibility timer (GPTA)

Two Analog to Digital Converters (ADC)

Fast, 10-bit ADC

Resolver I/F

Encoder I/F with digital noise filter

Optimized motion control library

Very fast control loop
Suggested Products

33
TriCore™ for
Application Example
AC
AC
Generator
Inverter
Rectifier
~230V
PWM
PWM
Blade Pitch
Control
ADC
Wind
Sensor
ADC
32-bit MCU
TC1784N
Grid Phase
Monitoring
Wind Turbine Inverter

Reliable blade pitch control

Increased
wind turbine efficiency

Multiple modulation strategies
(SVPWM, DPWM, Soft-PWM, direct
torque control) to support requirements for reduced noise emissions and
increased efficiency

Multiprocessor support for reliability
and safety

Support for 3-level inverter topologies
Suggested Products

34
System Benefits

Generic
flexibility timer (GPTA)

Fast, 10-bit ADC

Resolver I/F

Encoder I/F with digital noise filter

Optimized motion control library
TriCore™ for
Application Example
DC
AC
IGBT
EconoPIM™
~230V
EiceDRIVER™
Grid Phase
Monitoring &
Synchronization
MPPT
PWM
ADC
Intelligent Safety
Watchdog
CIC61508
ADC
32-bit MCU
TC1784N
Solar Panel
multiple modulation strategies
(SVPWM, DPWM, Soft-PWM, direct torque
control) to support requirements for
reduced noise emissions and increased
efficiency

Maximum Power Point Tracking (MPPT) to
extract maximum power from solar panels

Grid phase monitoring and synchronization
to ensure power factor unity

Current control to avoid disharmonics and
to determine the feed in refund

Support for 3-level inverter topologies
Suggested Products

Maximum Power Point Tracking (MPPT)
(Cell Temperature: 25°C)
0
0
Power [W]

Runs
System Benefits

Generic flexibility timer (GPTA)

Fast, 10-bit ADC (262.5ns @ fFADC = 80MHz)

Optimized DSP library
Current [A]

Multi-phase PWM controller for single or
multiple strings
Voltage [V]
0
Current vs. Voltage
Power vs. Voltage
35
Program Memory i/f
Floating Point Unit
TriCore™
32KB D SPR
16KB ICACHE
TC1.6
300MHz
Data Memory i/f
LMU
124KB D SPR
16KB DCACHE
128KB
SRAM
XBAR
1.3V/3.3V
Ext. Supply
EBU
PMU 0
PMU 1
2MB Flash
16KB DFlash
8KB BROM
key Flash
2MB Flash
16KB Parameter RAM
FPI-Bus Interface
Interrupts
MemCheck
STM
PCP2
Core
200MHz
Interrupts
FlexRay
(2 Channels)
MLI0
MLI1
ASC0
ASC1
Bridge
OCDS L1 Debug
Interface/JTAG
DMA
2x 8 Channels
32KB Code Memory
MultiCAN
(4 Nodes,
128 MO)
SCU
Ports
External
Request Unit
GPT120
SDMA
(8x safe DMA Channels)
SHE
FCE
BMU
5V (3.3V supported as well)
GPT121
SENT
(8 Channels)
SBCU
PLL
E-RAY
fE-Ray
FM-PLL
fCPU
SSC0
Ext. ADC Supply
ADC0
SSC1
ADC1
GPTA1
SSC2
ADC2
LTCA2
SSC3
ADC3
SSCG
SSC Guardian
FADC
GPTA0
CCU60
CCU61
CCU62
CCU63
MSC0
LVDS
MSC1
LVDS
(5V max)
(3.3V max)
3.3V
Ext. FADC Supply
AUDO MAX TriCore™ TC1798 Architecture
36
AUDO Family System Architecture
TriCore™ is the first unified, single-core
32-bit-microcontroller DSP architecture
that has been optimized for real-time
embedded systems. The TriCore™ Instruction Set Architecture (ISA) combines the
real-time capability of a microcontroller,
the computational power of a DSP plus
the high performance and price features
of an RISC load/store architecture in a
compact reprogrammable core.
The ISA supports a uniform, 32-bit
address space with optional virtual
addressing and a memory-mapped I/O.
It enables a wide range of implementations, from scalar to superscalar, and
is capable of interacting with different
system architectures, including multiprocessing environments. This flexibility at
implementation and system level enables
manufacturers to balance performance
and cost requirements to meet individual
needs.
The architecture supports both 16-bit and
32-bit instruction formats. 16-bit instructions are a subset of 32-bit instructions
and were chosen due to their widespread
popularity. They also significantly reduce
code space and memory requirements, as
well as system and power consumption.
Real-time responsiveness is largely determined by interrupt latency and context
switch time. The high-performance architecture minimizes interrupt latency by
avoiding long multi-cycle instructions and
providing a flexible hardware-supported
interrupt scheme. The architecture also
supports fast context switching.
The Peripheral Control Processor (PCP2)
is a programmable, single-cycle, 32-bit
processing unit with its own code and
data memory unit (Harvard architecture).
It is used as an interrupt service provider,
delivering hardware interrupt priority arbitration with 255 priority levels. Instead of
static implementation, the PCP provides
programmable improved peripheral intelligence.
The General Purpose Timer Array (GPTA)
delivers extremely flexible filtering and
high-resolution signal acquisition, as well
as a digital PLL to generate higher resolution input signals. It enables all types of
enhanced counting, capture/compare and
PWM functionality thanks to its universal
cell structure.
37
TriCore™ TC1.6
y i/f
Data Memory i/f
Floating Point Unit
TriCore™
TC1.6
300MHz
PMU 1
2MB Flash
Bridge
TriCore™
Interrupts
FPI-Bus Interface
16KB Parameter RAM
Floating Point Unit
TC1.6 PCP2
300MHzCore
200MHz
32KB Code Memory
PMU 1
MB Flash
Bridge
LMU
Features
124KB D SPR
128KB

1.3V/3.3V
Up to SRAM
300MHz
16KB DCACHE
XBAR
Ext. Supply

Six-stage pipeline

Dedicated integer division unit in
hardware

Optimized Floating Point Unit (FPU)
OCDS L1 Debug

Enhanced branch prediction
DMA
Interface/JTAG
2x 8 Channels
(branch history and target buffers)
MLI0

Optimized crossbar interconnect with
64-bit data width (shared
MLI1resource
interconnect)
Interrupts
Data Memory i/f
LMU
MemCheck

16-bit and 32-bit instruction
formats
STM

32-bit
load-store Harvard
architecture
124KB D SPR
128KB
SDMA
1.3V/3.3V
16KB DCACHE Superscalar
SRAM
XBAR
(8x
safe DMA Channels)
execution
SCU
Ext. Supply

Sustained throughput
by dual
SHE
Ports
16x32 MACs
FCE
ExternalSIMD (Single Instruction
Multiple Data)
Request Unit
OCDS L1 Debug
packed arithmetic
BMU
DMA
Interface/JTAG
GPT120Zero overhead loops
2x 8 Channels
(loop recognition buffer)
MLI0
GPT121
CCU60
CCU61
60
61
PCP2
Core
200MHz
Interrupts
FPI-Bus Interface
PLL
fE-Ray
E-RAY
SBCU
16KB Parameter RAM f
FM-PLL
CPU
CCU62
MSC0
MSC1
CCU63
LVDS
LVDS
32KB Code Memory
SBCU
PLL
E-RAY
fE-Ray
FM-PLL
fCPU
SSC0
Interrupts
SSC1
STM
SSC2
SCU
SSC3
MSC0
LVDS
MSC1
LVDS
ADC0
SSC1
Features
SDMA
ADC2
data and adds it to
previously read
ADC0 data

Reads two data values and performs
ADC1
(5V max)
arithmetic or logical operations and
ADC2
stores results
SSC3
ADC3
SSCG
SSC Guardian
FADC
(3.3V max)
3.3V
Ext. FADC Supply
38
Benefits

Highest performance for complex engine
management systems

Integrated MCU-DSP instructions in
one core

Very fast context switching for interrupt
driven system

Fast and efficient processing of multiple
tasks on one engine

Low code size and inherent high level
language support

One development toolset for both MCU
and DSP tasks

Higher flexibility and lower cost

Support and supply of complete
system chipset
MemCheck
ADC1
Peripheral Control
Processor
(PCP2)
(5V max)

Reads/moves
SSC0
addressing modes and
saturated math
MLI1
ADC3 any two memory

Moves data SHE
between
Ports
(3.3V max)
SSCG or I/O locations
FADC
FCE
SSC Guardian
External

Up to 200MHz
Request Unit
3.3V

Read-modify-write
capabilities
BMU
Ext. FADC Supply
GPT120 Full computation capabilities including
basic MUL/DIV
GPT121
Ext. ADC Supply
SSC2
CCU62
CCU63
Ext. ADC Supply

DSP

Bit
handling capabilities
(testing, setting, clearing)

Flow control instructions (conditional/
unconditional jumps, breakpoint)
Benefits

Data preconditioning

First level of defense for frequently
occurring peripheral interrupts

Programmable implementation
of state machines

Intelligent DMA assistance
SRAM
SRAM
Features

Up to 288KB

Overlay RAM

Error Code Correction (ECC)
with Single Error Correction (SEC)
and Double Error Detection (DED)
Benefits

Fast memory access

Safety
288KB RAM
32KB CACHE
Data Flash
Data Memory
Features

60k cycles EEPROM emulation and data
retention for a minimum of five years

Read-while-write feature supported for
EEPROM emulation
Benefits

EEPROM emulations eliminate need for
external EEPROM

Alternative to stand-by RAM
EEPROM emulation
192KB DFlash @ 60K
w/e cycles
Program Memory i/f
Program Flash
Features

Two banks offering concurrent
read/write/erase

Dynamic error correction of single-bit
errors and detection of double-bit
errors (SEC-DED-ECC)

Margin check control

Flash read/write protection for each
sector with three levels

Flash read/write protection based on
two-tier password
32KB D SPR
Program Memory
16KB ICACHE

One-Time
Programmable (OTP)

Tuning protection

End-to-end protection of Flash data
with ECC

Detection of addressing errors
Benefits

Fast end-of-line programming

Faster access speeds

Safety and security
EBU
PMU 0
2MB Flash
16KB DFlash
8KB BROM
key Flash
2
ASC0
ASC1
FlexRay
(2 Channels)
MultiCAN
Features & Benefits

Full CAN with CAN 2.0B active

Up to four independent CAN nodes

Up to 128 message objects

Programmable acceptance filtering

Data transfer rate of up to 1Mbit/s
individually programmable for each node
4MB PFlash
16KB Boot ROM

Powerful
analysis capability
data handling support

Automatic gateway support

Flexible interrupt handling

FIFO
MultiCAN
(4 Nodes,
128 MO)
SENT
(8 Channels)
GPTA0
GPTA1
LTCA2
CCU
CCU
39
124KB D SPR
16KB DCACHE
128KB
SRAM
XBAR
Program Memory i/f
TriCore™
Direct Memory Access
(DMA)
124KB D SPR
f
fE-Ray
fCPU
DMA
2x 8 Channels
16KB DCACHE
LMU
128KB
SRAM
Features

MLI0
Up to 16 independent DMA channels
EBU

Programmable priority of DMA
MLI1
PMU 0
PMU 1
sub-blocks on bus interfaces
DMA
Interrupts

Buffer capability for move
actions on
2MB Flash
2MB Flash MemCheck
2x 8 Channels
Bridge
16KB DFlash
buses (at least one move per bus is
STM
8KB BROM
SDMA
buffered)
key Flash
SCU

Individually programmable operation
Interrupts
16KB Parameter RAM
SHE
Ports
modes for each DMA channel
ASC0

Full 32-bit addressing capability
of
STM
FCE
External
ASC1
PCP2DMA channel
Request Unit
each
SCU
LMU
Core
BMU

Programmable data width of DMA trans200MHz
GPT120
FlexRay
Portsor 32-bit
8-bit, 16-bit
128KB (2 Channels)
5V (3.3V supportedfer/transaction:
as well)
1.3V/3.3V
SRAM
GPT121
XBAR
Ext. ADC
Supply

Micro link bus interface External
support
Ext. Supply
32KB Code Memory
Request

MultiCAN
One
register
set
for
each
DMAUnit
channel
SSC0
ADC0
(4 Nodes,

Flexible interrupt generation
GPT120
128 MO)
SSC1
ADC1
OCDS L1 Debug
SSC2
SENT
Interface/JTAG
(8 Channels)
SSC3
MLI0
els
MSC1
LVDS
Interrupts
mory
TC1.6
OCDS L1 Debug
300MHz
Interface/JTAG
FPI-Bus Interface
Interrupts
RAM
Data Memory i/f
Floating Point Unit
32KB D SPR
16KB ICACHE
ge
1.3V/3.3V
Ext. Supply
GPTA0
SSCG
SSC Guardian MLI1
GPTA1
MemCheck
LTCA2
ADC2
ADC3SBCU
FCE
it
PLL
check unit built in
controller operates as bus bridge
OCDS L1
Debug peripheral bus and
between
system
Interface/JTAG
remote peripheral bus (AUDO NG) or to
LMB busMLI0
(AUDO Future)

DMA
MLI1
Benefits

Flexible
use for single event or
MemCheck
continuous transfer operation
SDMA

Flexible
interrupt generation

Maximum flexibility to adapt to
SHE
customer
needs

Maximum
adaptation to application
FCE
requirements
BMU
fE-Ray
Ext. ADC Supply
SSC0
E-RAY Purpose Timer
General
Array (GPTA)
FM-PLL
(3.3V
max)
Ext. Supply

Memory
GPT121
FADC
CCU60
SDMA
(8x safe DMA Channels)CCU61
SHE
(5V max)
1.3V/3.3V
XBAR
fCPU
SSC1
Features & Benefits
SSC2

Very
flexible digital input filtering
3.3V
Ext. FADC
Supply of all kinds of rotating

Tracking
SSC3 shafts
CCU62Scalable
MSC0 high
MSC1resolution
SSCG
CCU63Independent
LVDS
LVDS
access to
time
and
SSC
Guardian
angle domain

All types of PWM generation supported*
thanks to Local Timer Cell (LTC) array
ADC0
ADC1
(5V max)
ADC2

Digital
PLL for fine grain angle resolution
is the ideal coprocessor to
handle critical
short and real-time GPTA
(3.3V max)
FADC
interrupt tasks from the GPTA

Ideal for field 3.3V
test and repair work

PCP2
ADC3
Ext. FADC Supply
BMU
Ext. ADC Supply
ADC0
ADC1
(5V max)
ADC2
ADC3
(3.3V max)
FADC
an
3.3V
Ext. FADC Supply
40
Enhanced Analog-Digital Converter (ADC)
Features & Benefits
synchronizable A/D converters
with up to 64 channels

8/10/12-bit resolution, ±2LSB @ 10-bit

Conversion time down to 1.0μs

1–4

Data
reduction pre-processing

Result accumulation and limit check

External or internal trigger events and
automatic conversion sequencing SSC0
E-RAY
FM-PLL
GPTA0
GPTA1
LTCA2
Fast Analog to Digital Converter (FADC)
Features & Benefits

Unique solution for knock detection
without external ASICs or dedicated DSP

Reduced software load for FIR filter
thanks to integrated decimation comb filter
(e.g. data reduction by a factor of
six from 1200 to 200k samples)

Quick adaptation of overall filter quality
to meet application requirements
CCU60
CCU61
CCU62
CCU63
MSC0
LVDS
EBU
ADC0
fCPU
SSC1
Program Memory i/f
SSC2
32KB D SPR
16KB ICACHE SSC3
MSC1
LVDS
Ext. FADC
Supplyi/f
Program
Memory
D
32KB D SPR2x 8 C
Bridge
16KB ICACHE
2MB Flash
FPI-Bus Interface
EBU
16KB Parameter RAM
PCP2
Core
200MHz
PMU 0
S
2MB Flash
16KB DFlash
8KB BROM
key Flash
2
S
GP
GP
SENT
(8 Channels)
SBCU
GPTA0
PLLFlexRayf
E-Ray
(2 Channels)
E-RAY
S
fCPU
FM-PLL
S
MultiCAN
(4 Nodes,
128 MO)
GPTA1
S
S
LTCA2
The MSC module sets a new open standard
for serial high-speed communication
Programwhen
Memory i/f
powering ASIC modules such as multi32KB D SPR
switches (for ignition or injection drivers).
16KB ICACHE
It transfers command frames, data frames and
asynchronous diagnosis feedback from the
device. The MSC module helps designers
reduce EMC for high bandrates
(up
to i/f
Data
Memory
Floating Point Unit
45Mbit/s) by supporting low-voltage
TriCore™
124KB D SPR
differentialTC1.6
swing (LVDS) for high-speed
16KB DCACHE
300MHz
downstream
data and clock rates.
CCU60
CCU61
CCU62
CCU63
MSC0SENTMSC1
(8 Channels)
LVDS
LVDS
S
SSC G
LMU
GPTA0
128KB
SRAM
XBAR
1.3V/3.3V
GPTA1
Ext. Supply
LTCA2
CCU
CCU
EBU
PMU 1
2MB Flash
Bridge
16KB DFlash
8KB BROM
key Flash
FlexRay
(2 Channels)
MultiCAN
(4 Nodes,
128 MO)
200MHz
32KB Code Memory
OCDS L1 Debug
Interface/JTAG
DMA
2x 8 Channels
MLI0
thus enabling scalable processing
Interrupts
Parameter
RAM
power16KB
within
an application

Fast interconnection to Infineon STM
companion
chips e.g. CIC310 FlexRay
PCP2
Core CIC751 16-channel SCU
controller and
ADC
FPI-Bus Interface
Features & Benefits
high-speed interface up to MLI/2
(e.g. 45Mbit/s for TC1797)ASC0
used for
inter-processor key Flash communication
ASC1
between the AUDO family members,

Serial
Interrupts
PMU 0
Multiprocessor Link Interface
(MLI)
2MB Flash
Ports
External
Request Unit
GPT120
MLI1
MemCheck
SDMA
SHE
FCE
BMU
GPT121
SENT
(8 Channels)
SBCU
PLL
E-RAY
fE-Ray
FM-PLL
fCPU
SSC0
Ext. ADC Supply
ADC0
SSC1
ADC1
GPTA1
SSC2
ADC2
LTCA2
SSC3
ADC3
GPTA0
P
Ext
Requ
ASC1
synchronous
communication up to 11.25Mbit/s
Micro Second Channel (MSC)
Inte
32KB Code Memory
ASC0
MultiCAN
(4 Nodes,
128 MO)

Half-duplex
(3.3V max)
FADC
PMU 1
FlexRay
(2 Channels)
Features & Benefits
off-board communication
via LIN or K-line

Full-duplex asynchronous
communication up to 5.625Mbit/s
124KB D
16KB DC
TC1.6 ADC3
300MHz
3.3V
ASC1

Convenient
(5V max)
Data Mem
TriCore™
SSCG
SSC Guardian
by programming data rate used for the
PMU 0
COMB filter
2MBto
Flash

Increased ADC accuracy thanks
16KB DFlash
data reduction filter and by moving
8KB BROM
key Flash
averaging filter (e.g. from 10-bit
to
11-bit by selected oversampling by
ASC0
a factor of four)
Asynchronous Serial Channel (ASC)
ADC1
Floating Point Unit
ADC2
Interrupts
SBCU
(5V max)
41
I
FPI-
FlexRay
(2 Channels)
32KB Code Memory
MultiCAN
(4 Nodes,
128 MO)
f
SRAM
XBAR
GPTA0
SHE
FCE
BMU
SENT – New Digital Sensor Interface
GPT121
PLL
fE-Ray
Features
SSC0
E-RAY & Benefits

SENT
stands
fCPUfor Single (falling) Edge
FM-PLL
SSC1
Nibble Transmission

Eight SENT channels workSSC2
independently
in parallel
SSC3

Point-to-point digital protocol
CCU62
MSC0
MSC1
SSCG
complex
CCU63Less
LVDS
LVDSand lower cost alternative
SSC Guardian
to CAN and LIN digital busses

Good fit for environments with high
noise level (e.g. powertrain) complies
1.3V/3.3V
SBCU
Ext. Supply
GPTA1
LTCA2
OCDS L1 Debug
Interface/JTAG CCU60
CCU61
MLI0
els
External
Request Unit
GPT120
LMU
SENT
128KB (8 Channels)
Ports
Data Memory i/f MLI1 LMU
124KB D SPR MemCheck
128KB
16KB DCACHE
SRAM
XBAR
SDMA
Ext. ADC Supply
ADC0
with SENT standard (unidirectional) as
ADC1
(5V max)
well as Short
PWM Code (SPC) protocol
extensions
ADC2

SPC
enables use of enhanced protocol
functionalities such as synchronous,
(3.3V max)
range
FADC selection and ID selection

Data rates of up to 65.8Kbit/s at 3μs
3.3V
tick length and six data nibbles on
Ext. FADC Supply
each channel
ADC3
1.3V/3.3V
Ext. Supply
Secure Hardware Extension (SHE)
SHE
Features & Benefits
OCDS L1 Debug

Interface/JTAG
Fulfills HIS consortium specifications
FCE
DMA
2x 8 Channels
BMU
it
ge
(BMW, Audi, Daimler, Porsche, VW)
MLI0

Supports
Ext. ADC Supply
Interrupts
RAM
Interrupts
ADC0
STM
ADC1
SCU
(5V max)
ADC2
Ports
ADC3
External
(3.3V max)
Request Unit
FADC
mory
an
GPT120
MLI1
––Encoding/decoding of data
––Secure hash
––Secure keys stored in secure Flash
SDMA –– Prevention of access by hardware or
software
MemCheck
SHE
FCE
BMU
General Purpose Timer 12 (GPT12)
3.3V
5V (3.3V supported
as well) & Benefits
Features
Ext. FADC Supply
GPT121
Ext. ADC
Supply

Multifunctional
timer structure
fE-Ray
SSC0
fCPU
MSC1
LVDS
ADC0
SSC1
ADC1
SSC2
ADC2
SSC3
ADC3
SSCG
SSC Guardian
FADC
––Timing
––Event counting
(5V
max) width measurement
––Pulse
––Pulse generation
––Frequency multiplication
(3.3V max)
3.3V
Ext. FADC Supply
42
––Key programming by OEM
––True random number generator
––Key exchange protocols

Enables
––Manipulation protection
––Authentication
––Secure boot

Modes
––Gated timer
––Counter mode
––Concatenation of different timers
Program Memory i/
PLL
E-RAY
SBCU
32KB D SPR
FM-PLL
16KB ICACHE
(8 Channels)
GPTA0
GPTA1
Capture/Compare Unit 6 (CCU 6)
Program Memory i/f

Also
supports BLDC control, block commutation and multi-phase machines
EBU

Center-aligned and edge-aligned PWM
can be generated
1)
PMU 1
2MB Flash
ASC0
DMA
2x 8 Channels
ASC1
Bridge
FlexRay
(2
Channels)
Interrupts
16KB Parameter RAM
ASC0

Supports
demand for higher bandwidth
(whereASC1
CAN is bottleneck)
PCP2

Enables new vehicle partitioning
Core
200MHz
FlexRay
concepts such as domain control
(2 Channels)

Deterministic bus system
(supports safety applications)
32KB Code Memory
STM
MultiCAN
(4 Nodes,
SCUMO)
128
Interrupts
Features & Benefits

Conformance with FlexRay protocol

Specification V2.1

Data rates of up to 10Mbit/s on each channel

Up to 128 configurable message buffers

8KB of message RAM

ERAY IP
PMU 0
2MB Flash
16KB DFlash
8KB BROM
key Flash
LMU
CCU60D SPR
CCU62
MSC0
124KB
128KB
PMU 0
CCU61
CCU63
LVDS
16KB
DCACHE
SRAM
2MB Flash
16KB DFlash
8KB BROM
key Flash
TC1.6
300MHz
FPI-Bus Interface
FlexRay™
TriCore™
32KB D SPR
16KB ICACHE
Features & Benefits

High resolution 16-bit capture and
compare unit

Mainly for AC drive control
EBU
Data
Memory i/f
Floating Point Unit
LTCA2
(8
Ports
SENT
(8External
Channels)
Request Unit
MultiCAN
(4 Nodes,
128 MO)
GPT120
GPTA0
5V (
Synchronous Serial Channel (SSC)
GPTA1
GPT121
SENT
(8 Channels)
SBCU
PLL
E-RAY
Features & Benefits
FM-PLL
GPTA0

rates up to 45Mbit/s
Full-duplex
and half-duplex serial

Communication link for powerProgram
devices,
communication Data Memory i/f
Memory i/f synchronous
GPTA1Point Unit
Floating

memories and sensors
Hardware support for up to six slave
TriCore™
32KB D SPR
124KB D SPR
LTCA2
select lines
TC1.6
16KB ICACHE
16KB DCACHE

Supports
CCU60
CCU61
300MHz
CCU62
CCU63
fE-Ray
LTCA2
SSC0
fCPU
CCU
CCU
SSC1
SSC2
LMU
128KB
MSC0 SRAM
MSC1
LVDS
LVDS
XBAR
SSC3
1.3V/3.3V
Ext. Supply
SSCG
SSC Guardian
EBU
Enhanced On-Chip Debug Support (OCDS)
FlexRay
(2 Channels)
OCDS L1 Debug
Interface/JTAG
DMA
16KB Parameter RAM
MLI0
MLI1
Interrupts
MemCheck
STM
PCP2
Core
200MHz
Interrupts
ASC1
PMU 1
only
2MBtwo
Flashpins. Flexible cross triggering
2x 8 Channels
Bridge
with internal and external sources and
targets helps analyze and debug hard
real-time systems.
FPI-Bus Interface
PMU 0
TriCore™ V1.6 features enhanced2MB
On-Chip
Flash
16KB
Debug Support (OCDS) with programDFlash
flow
8KB BROM
and data access breakpoint capabilities.
key Flash
Debuggers can connect using JTAG or a
high-speed Device Access Port
(DAP) with
ASC0
32KB Code Memory
MultiCAN
(4 Nodes,
128 MO)
SCU
Ports
External
Request Unit
GPT120
SDMA
SHE
FCE
BMU
GPT121
SENT
(8 Channels)
SBCU
PLL
E-RAY
fE-Ray
FM-PLL
fCPU
SSC0
Ext. ADC Supply
ADC0
SSC1
ADC1
GPTA1
SSC2
ADC2
LTCA2
SSC3
ADC3
SSCG
SSC Guardian
FADC
GPTA0
1) FlexRay™ is a trademark of the FlexRay Consortium and used under license.
CCU60
CCU61
CCU62
CCU63
MSC0
LVDS
MSC1
LVDS
(5V max)
43
(3.3V max)
FPU
PMI
PMU
LMU
DMI
Overlay
TriCore™
1.6P
RAM
Data Flash
BROM
Key Flash
Progr.
Flash
Progr.
Flash
SRI Cross Bar
Diverse
Lockstep Core
FPU
PMI
Diverse
Lockstep Core
DMI
Overlay
TriCore™
1.6P
PMI
FPU
TriCore™
1.6E
Bridge
DMI
Standby
Overlay
SDMA
OCDS
System Peripheral Bus
PLL &
PLL ERAY
HSSL
BCU
SCU
STM
SHE2
DS-ADCx
ADCx
IOM
FCE
I2C
PSI5
SENT
EVR
QSPIx
GPT12x
ASCLINx
MultiCAN+
FlexRay
Ethernet
GTM
MSCx
CCU6x
Ports
5V or 3.3V
Single Supply
AURIX™ Family System Architecture
AURIX™ is Infineon’s brand new family of microcontrollers serving exactly the needs of the
automotive industry in terms of performance and safety. Its innovative multicore architecture, based on up to three independent 32-bit TriCore™ CPUs, has been designed to meet
the highest safety standards while significantly increasing performance at the same time.
Using the AURIX™ platform, automotive developers will be able to control powertrain
and safety applications with one single MCU platform. Developments using AURIX™ will
require less effort to achieve the ASIL-D standard than with a classical Lockstep archi
tecture. Customers wanting to reduce their time-to-market can now cut down their MCU
safety development by 30%. By the same token, a performance surplus of 50% up to
100% allows for more functionality and offers a sufficient resource buffer for future
requirements, keeping the power consumption on the single-core microcontroller level.
While protecting IP, and preventing theft and fraud, AURIX™ provides an already built-in
Hardware Security Module.
With its special feature set, AURIX™ is the perfect match for powertrain applications
(including hybrid and electrical vehicles) as well as safety applications (such as steering,
braking, airbag and advanced driver assistance systems).
44
AURIX™ Family Package Scalability
LQFP-64
LQFP-100
LQFP-144
LQFP-176
9x Series
TC297
up to 8MB
up to 300 MHz
7x Series
TC275
up to 4MB
up to 200MHz
6x Series
TC264
up to 1.5MB
up to 133MHz
2)
4x Series
TC243
3x Series
TC233
TC234
2x Series
TC223
TC224
up to 1.5MB
up to 2MB
up to 1MB
1x Series
up to 512KB
LFBGA-292
TC211
LBGA-416
LFBGA-516
TC298
TC299
1)
1)
TC277
TC265
TC244
TC213
Upgrade/Downgrade with pin-compatible packages

Advanced
package technologies deliver the best price/performance ratio

Customers can choose between different devices in the same pin-compatible package
TriCore™ Upgrade Paths
LBGA-516
LFBGA-292
BGA Scalability
25 x 25 mm
17 x 17 mm

LFBGA-292
and LFBGA-516 are ball compatible so that customers can build one PCB for
both packages
1) The LFBGA-516 package is a superset of the LFBGA-292.
Combination PCBs can be designed for I/O and feature upgrades.
2) The TC24x device is also planned in LQFP-80.
45
AURIX™ (HW and SW) Development According to ISO 26262 Process

Independent
Functional Safety Management established at Infineon

Compliance certificate available
––SDHB to ISO 26262 Gap Analysis
performed by Exida
––Close-the-gap activities performed by
Infineon
––Exida has issued a compliance
certificate (Jan 2012) for Infineon HW
and SW development processes for
building systems up to ASIL-D
Final ISO 26262
Functional Safety Audit
Report
Project
Functional Safety Audit
Customer
Infineon Technologie AG
Infineon® Diverse Lockstep Concept

Lockstep
architecture designed to control and mitigate common cause factors
––Physical isolation
––Instruction-level execution diversity:
2-cycle delay
––Circuit-level design&timing diversity

Layout-level diversity

Diversity controlled and verified by
state‑of‑the‑art design methods

Special design of clock&reset networks

Careful design of lockstep comparator

Main
core and diverse lockstep core run
the same software in parallel to detect
computational errors

Like normal locksteps, both cores are
physically separated and have a time
delay between their execution

Diverse Lockstep core has been
additionally transformed to provide
architectural hardware diversity and
further reduce common cause failures
BUS
Main Core
Delay
Delay
Delay
Delay
Lockstep
Core
Compare
BUS
Lockstep
46
Lockstep CPU
Error
Multi-AUTOSAR OS Support on One Microcontroller

AURIX™
provides a memory protection
system for each core plus an additional
distributed hardware-based resource
management system

Each peripheral and shared SRAM has a
resource management unit that works as a
local access protection mechanism to allow
or deny access

When combined with the memory
protection system, this hardware can be
used to prevent selected direct access from
certain tasks or cores to peripherals or
regions of SRAMs and instead redirect the
attempted access to a hypervisor function
Safety
Agent

The
hypervisor can arbitrate/grant/
deny access and therefore provide
paravirtualization of mixed-criticality
tasks in a unified sub-system architecture with a minimal CPU overhead

AURIX™ therefore provides the ability
to run mixed-criticality software
requiring real-time access while still
enforcing encapsulation and freedom
of interference between cores, even
when the cores are not running timeand memory-protected operating
systems
APP
...
APP
Safety
Monitor
... ...
AUTOSAR
Hypervisor
Supervisor/User
AURIX™
AURIX™ Protection System Overview

Hardware
Support for Freedom of
Interference
––Between SW components
APP
APP
AUTOSAR
Core 0
––Between HW parts
––Between HW parts & SW components

Timing protection
APP
APP
AUTOSAR
Core 1
APP
APP
AUTOSAR
Core 2
Hypervisor
Hardware
47
Embedded Software
TriCore™ Performance
Real-life application benchmark (software controlling a four-cylinder diesel engine)
228%
100%
100%
TC1797
TC1782
128%
113%
170%
152%
140%
46%
TC1767
TC1.3.1
@ 80MHz

Assuming
TC1791/
TC1791
TC1793
TC1798
TC1793
TC1.3.1
TC1.3.1
TC1.6
TC1.6
TC1.6
TC1.6
@ 180MHz @ 180MHz @ 200MHz @ 240MHz @ 270MHz @ 300MHz
TC27x
TC29x
1x TC16E&
1x TC16P 2x TC16P
@ 200MHz @ 300MHz
multicore performance gain of 1.5 times
Infineon Software Product Overview
Modeling
Tools
Tools
abstraction drivers
––AUTOSAR MCAL
––DAVE™

Safety driver
––PRO-SIL™ SafeTcore (AUDO MAX)
––PRO-SIL™ SafeTlib (AURIX)

Application drivers
––DAVE™ Drive (IMM)
––3-phase eMotor driver
48
Libraries
Hardware
Focus Areas

Microcontroller
Configuration
Tools
Microcontroller
Abstraction Drivers
Applications Driver
Safety Driver
System Software
(Services, OS, Communication,
Memory Manager etc.)
Security Driver
Application Software
HW
Operation Software
Appl. Software
Software

System
software

Configuration tool
––DAVE™

Libraries
––TriLib
––XC2000 DSP library

Tools
––MemTool etc.
Via 3rd Parties
Infineon AUTOSAR MCAL Drivers
MC-ISAR Product Overview
Application Layer
AUTOSAR Runtime Environment (RTE)
System Services
On-board
Device
Abstraction
Memory
Services
Communication
Services
Memory
Abstraction
Communication
Abstraction
FLS
RAM
Test
Complex Device
Driver
CanTrcv
FEE
MCU WDG GPT
I/O Hardware
Abstraction
SPI
LIN
CAN FlexRay
PORT
DIO
ICU
PWM ADC
MCAL
UART
MEM
FADC
Check
...
MCAL Complex Driver
Microcontroller
Infineon MC-ISAR Drivers (MicroController Infineon Software ARchitecture)
MC-ISAR
MC-ISAR:
MC-ISAR COM Basic:
MC-ISAR COM Enhanced:
MC-ISAR MEM:
MC-ISAR MCAL CD:
Enabled via Partners
MicroController – Infineon Software ARchitecture
MCU, WDG, GPT, SPI, PORT, DIO, ICU, PWM, ADC
CAN, CanTrcv, LIN
FlexRay, Ethernet
FLASH, FEE
UART, MEMCheck, FADC, ect. for TriCore™

Supported
AUTOSAR releases and devices
––V2.0: AUDO NG (TC1796, TC1766 )
––V2.1, V3.0: XC2287, AUDO Future
(TC1797, TC1767), AUDO S
––V3.1, V3.2: XC2000, AUDO MAX
––V4.03: AUDO MAX
––V3.2, V4.03: AURIX™
––ISO 26262 support

Complex
driver for non-standardized
modules (for TriCore™)

CMM L3 process

AUTOSAR BSW suite via partners:
Electrobit, Vector, KPIT

Delivery packages include:
source code, user manual, Tresos
configuration tool
MC-ISAR Product Overview
Documented product
release
Easy to use
Standardized driver
Compatibility and reduced
time-to-market
Qualified release
Compliant with CMM L3,
lower development cost
Free evaluation version
From sales contact
MC-ISAR
Eﬃcient implementation
Lowest resource
consumption
Application independence
From chassis through body
to powertrain
49
Embedded Software
Infineon’s MC-ISAR eMotor Driver
3–Phase Motor Control for Mass Production
Electrical 3-phase motors, such as PMSM (Permanent Magnetic Synchronous Motors)
and BLDC (Brushless DC) motors, are used across the automotive application domains
(e.g. chassis control, (H)EV inverter, dry double clutch transmission etc.).
3–phase sinusoidal distributed and mechanically displaced windings are the characteristic of PMSM. The rotating magnetic field, activated by sinusoidal and time-displaced
current, drives the motor. Three-phase current is switched into the motor windings via
MOSFETs. The Field Oriented Control (FOC) algorithm generates the PWM pattern needed
for the current control. The rotor position and current are continuously sensed. The highperformance microcontroller plays the key role in the FOC algorithm, allowing higher
accuracy, safer execution and improved efficiency for motor control.
The MC-ISAR eMotor driver collects the common feature of current and torque control,
acting as a perfect solution for motor drive applications. Position and speed control can
be achieved on an application-specific basis, supporting multiple position acquisition
modes and satisfying different customer needs.
Feature Highlights

Control PMSM motors via Field Oriented
Control (FOC), including Space Vector
Modulation SVM

Control BLDC motors via
Block Communication (BC)

Mixed control of FOC / BC motors

Integrated with AUTOSAR drivers

Supports safety applications
Sensors in FOC Mode

Hall sensors/Incremental encoder

Direct resolver mode (without resolver IC)

Resolver mode (with resolver IC)

Sensorless FOC

Current Measurement: 3 phases,
2-phase parallel and sequential,
DC link sequential
50
Sensors in BC Mode

Hall sensors

Sensorless via back EMF

Current Measurement: DC link single
MC-ISAR eMotor Benefits:
for mass production,
off-the-shelf implementation

Limited software outlay

Direct resolver mode (no external
resolver IC), reduced system cost

Compliant to ISO 26262 process and
CMM level 3

Seamless configuration under the same
configuration tool for AUTOSAR MCAL
driver

Easy to use

Developed
FOC Mode
Motor
Debugging
Position
Control
Velocity
Control
AUTOSAR Run Time Environment (RTE)
EmoControl
PIC
INV IF
PARK LIB
FOC
CLARKE LIB
PA
RES IF
SVM LIB
FOC LIBs
ADC
Driver
SPI
Handler
Driver
EmoICU
DIO
EmoPWM
eMotor
MCAL CDs
µC
AUTOSAR Module
Customer-Specific Module
MC-ISAR eMotor Module
BC Mode
Position
Control
Motor
Debugging
Velocity
Control
AUTOSAR Run Time Environment (RTE)
EmoControl
PIC
PA
ADC
Driver
EmoICU
EmoPWM
eMotor
MCAL CDs
µC
AUTOSAR Module
Customer-Specific Module
MC-ISAR eMotor Module
51
Development Support
Emulation Device

Emulation
Devices (ED) are a very powerful
solution for calibration, measurement,
rapid prototyping and debugging

Emulation logic and RAM is added next
to the unchanged Production Device (PD)
part on the same chip

Cost-optimized PD, feature rich ED

Same package for ED and PD and minimum
or no additional external circuitry allows
highly cost-optimized ECU design

Proven solution with broad tool support
by leading automotive and
debug tool vendors
PD and ED in same package
AURIX™ Highlights

Up to 2Mbyte RAM for calibration with
same access speed as on-chip flash

Cold start access via the regular two pin
DAP interface when the ECU is unpowered

Automotive measurement bandwidth (XCP)
15/30Mbyte/s via regular 2/3 pin DAP interface
Trace and Measurement
Today’s vehicles are designed to meet rising market demands for engine performance,
engine responsiveness, torque, drivability, fuel economy and emissions. Infineon’s
proven Multicore Debug Solution (MCDS) enables manufacturers to design and optimize
features to support these automotive trends.
Multicore Debug Solution (MCDS)
Key Features

Tracing of CPUs, busses, performance events and peripheral internal states

Real-time, cycle-accurate and in parallel

Up to 1Mbyte on-chip trace RAM (40Gbit/s bandwidth)

Very powerful trigger capabilities

No additional pins needed beside the DAP interface

New Compact Function Trace (CFT) mode for continuous program trace via DAP

New fine grained data trace qualification for automotive measurement
52
DAVE™ – Digital Application Virtual Engineer
DAVE™ is a tool that helps engineers program Infineon microcontrollers. It provides intelligent
wizards that configure chips to specific requirements and automatically generate C-code with appropriate driver functions for all on-chip peripherals and interrupt controls.
DAVE™ interacts directly with the IDEs from leading tool suppliers and with Infineon’s free toolchain
DAVE™ Bench.
The DAVE™ mother system and DIP file for the microcontroller in question are needed to use DAVE™.
Key Features
generates initialization code for Infineon microcontrollers

DAVE™ displays all available peripherals in a block diagram at the start

Click on a peripheral to define its functionality

DAVE™
Starter Kits
Infineon AUDO family starter kits are powerful evaluation systems that enable evaluation and
development well before the target hardware is available. They offer a solid platform for both
hardware and software engineers to evaluate and prototype designs that are closely aligned with
their final applications.
Our Starter Kits include
Evaluation Board

USB cable

Easy connectivity to all peripheral modules

Extension Board

Development tools for evaluation such as compilers, debuggers and DAVE™

Technical documentation – user manuals, architecture manuals,
application notes, data sheets, board documentation

Full-Featured
Further information for TriCore™ Starter Kits: http://ehitex.com/starter-kits/for-tricore
53
TriCore™ Tool Partners
Embedded Software
Simulation/Virtual Prototyping
Integrated Compiler Environments
Auto Code Generation Tools
Timing/Scheduling Analysis
Operating Systems
Emulators/Debugger Development Systems
Data Measurement/Calibration/Rapid Prototyping
Programmer/Flash Tools
Software Verification
Training/Services
Free Tooling
DAVE
54
TM
Free TriCore™ Entry Tool Chain [Compiler/Debugger/Eclipse IDE]
Important Links/Contact
Local
Field application
Engineers via Infineon, distributors and sales representatives
www.infineon.com/sales
Regional Application engineering teams
Detroit, Munich, Shanghai, Singapore and Tokyo
Global Microcontroller R&D teams
Service center: www.infineon.com/service
Technical training: www.infineon.com/mc-training
55
Ask Infineon. Get connected with the answers.
Where you need it. When you need it.
Infineon offers its toll-free 0800/4001 service hotline as one central number, available 24/7 in English, Mandarin and German.
Our global connection service goes way beyond standard switchboard services by
offering qualified support on the phone. Call us!
nGermany ......................
0800 951 951 951 (German/English)
n China, mainland ..........
4001 200 951 (Mandarin/English)
nIndia ...........................
000 800 4402 951 (English)
nUSA .............................
1-866 951 9519 (English/German)
n Other countries ............
00* 800 951 951 951 (English/German)
n Direct access ...............
+49 89 234-0 (interconnection fee, German/English)
* Please note: Some countries may require you to dial a code other than “00” to access this international number,
please visit www.infineon.com/service for your country!
Where to Buy
Infineon Distribution Partners and Sales Offices
Please use our location finder to get in contact with your nearest
Infineon distributor or sales office.
www.infineon.com/WhereToBuy
Infineon Technologies – innovative semiconductor solutions for energy efficiency, mobility and security.
Published by
Infineon Technologies AG
85579 Neubiberg, Germany
© 2012 Infineon Technologies AG.
All Rights Reserved.
Visit us:
www.infineon.com
Order Number: B158-H9282-G3-X-7600
Date: 08 / 2012
Attention please!
The information given in this document shall in no event
be regarded as a guarantee of conditions or characteristics
(“Beschaffenheitsgarantie”). With respect to any examples
or hints given herein, any typical values stated herein and/
or any information regarding the application of the device,
Infineon Technologies hereby disclaims any and all warranties and liabilities of any kind, including without limitation warranties of non-infringement of intellectual property
rights of any third party.
Information
For further information on technology, delivery terms and
conditions and prices please contact your nearest Infineon
Technologies Office (www.infineon.com).
Warnings
Due to technical requirements components may contain
dangerous substances. For information on the types in
question please contact your nearest Infineon Technologies
Office. Infineon Technologies Components may only be
used in life-support devices or systems with the express
written approval of Infineon Technologies, if a failure of
such components can reasonably be expected to cause
the failure of that life-support device or system, or to affect
the safety or effectiveness of that device or system. Life
support devices or systems are intended to be implanted
in the human body, or to support and/or maintain and
sustain and/or protect human life. If they fail, it is reason-able
to assume that the health of the user or other persons may
be endangered.
Feature Overview TriCore™ Family
Number of ADC
Channels
Timed IO Channels
(PWM, CAPCOM, GPTA)
External Bus Interface
CAN Nodes
Communication
Interfaces 2)
Temperature Ranges 3)
Packages
81
32
48
no
2
2xASC, 2xSSC, MSC, 2xMLI
K
PG-LQFP-176
FPU, PCP
123
44
126
yes 4
2xASC, 2xSSC, 2xMSC, 2xMLI
K
PG-BGA-416
Additional Features/
Remarks 4)
Digital I/O Lines
FPU, PCP
2000 192
SRAM (incl. Cache)
[KByte]
1500 88
150
Program Memory
[KByte]
80
TC1796
Max Clock Frequency
[MHz]
TC1766
Product Type
Co-Processor 1)
TriCore™ Microcontroller for Automotive Applications
AUDO – Next Generation Family
AUDO – Future Family
TC1736
80
1000 48
FPU
70
24
53
no
2
2xASC, 2xSSC, MSC, MLI
K
PG-LQFP-144
TC1767
133
2000 104
FPU, PCP
88
36
80
no
2
K
PG-LQFP-176
TC1797
180
4000 176
FPU, PCP
221
48
118
yes 4
2xASC, 2xSSC, 2xMSC, 2xMLI, 2xFlexRay K
PG-BGA-416
AUDO MAX – Family
TC1724
133
1500 152
FPU, PCP
89
28
77
no
3
K
PG-LQFP-144
EVR
TC1728
133
1500 152
FPU, PCP
113
36
94
no
3
K
PG-LQFP-176
EVR
TC1782
180
2500 176
FPU/PCP
88
36
80
no
3
2xASC, 3xSSC, MSC, MLI, FlexRay
K
PG-LQFP-176
TC1784
180
2500 176
FPU/PCP
141
36
122
yes 3
2xASC, 3xSSC, MSC, MLI, FlexRay
K
PG-LFBGA-292
TC1791
240
4000 288
FPU/PCP
130
48
100
no
4
2xASC, 4xSSC, 2xMSC, 2xMLI, 8xSENT,
FlexRay
K
PG-LFBGA-292
TC1793
270
4000 288
FPU/PCP
221
44
112
yes 4
FlexRay
K
PG-LBGA-416
TC1798
300
4000 288
FPU/PCP
238
72
138
yes 4
FlexRay
K
PG-BGA-516
TC275T
200
4000 472
FPU
112
60 / 6 DS
110
no
4
4xASCLIN, 4xQSPI, 2xMSC, HSSL, I²C,
10xSENT, 3xPSI5, FlexRay,Ethernet
K
PG-LQFP-176
EVR
TC277T
200
4000 472
FPU
151
60 / 6 DS
134
no
4
4xASCLIN, 4xQSPI, 2xMSC, HSSL, I²C,
10xSENT, 3xPSI5, FlexRay,Ethernet
K
PG-LFBGA-292
EVR
AURIX™ – Family
www.infineon.com/TriCore
Feature Overview TriCore™ Family
80
no
TC1197
180
4000 176
FPU, PCP
221
48
118
2
F
PG-LQFP-176
yes 4
2xASC, 2xSSC, 2xMSC, 2xMLI
K
PG-BGA-416
Additional Features/
Remarks 4)
External Bus Interface
36
Packages
Timed IO Channels
(PWM, CAPCOM, GPTA)
88
Temperature Ranges 3)
Number of ADC
Channels
FPU, PCP
Communication
Interfaces 2)
Digital I/O Lines
1000 104
CAN Nodes
Co-Processor 1)
133
SRAM (incl. Cache)
[KByte]
Program Memory
[KByte]
TC1167
Product Type
Max Clock Frequency
[MHz]
TriCore™ Microcontroller for Industrial Applications
TC1x Family
AUDO MAX – Family
TC1724
133
1500 152
FPU, PCP
89
28
77
no
3
K
PG-LQFP-144
EVR
TC1728
133
1500 152
FPU, PCP
113
36
94
no
3
K
PG-LQFP-176
EVR
TC1782
180
2500 176
FPU, PCP
88
36
80
no
3
K
PG-LQFP-176
TC1784
180
2500 176
FPU, PCP
141
36
122
yes 3
K
PG-LFBGA-292
TC1791
240
3000 288
FPU, PCP
130
48
100
no
4
2xASC, 4xSSC, 2xMSC, 2xMLI, 8xSENT
K
PG-LFBGA-292
TC1793
270
4000 288
FPU, PCP
221
44
112
yes 4
K
PG-BGA-416
TC1798
300
4000 288
FPU, PCP
238
72
138
yes 4
K
PG-BGA-516
1) MAC = Multiply-Accumulate-Unit (DSP), FPU = Floating Point Unit, PCP = Peripheral Control Processor
2) I²C = Inter-Integrated Circuit, USART = Universal Synchronous Asynchronous Receiver Transmitter, UART = Universal Asynchronous Receiver Transmitter, SSC = Synchronous Serial Channel,
ASC = Asynchronous Serial Channel, MLI = Micro Link Interface, MSC = Micro Second Channel, LIN = Local Interconnect Network
3) Ambient Temperature Range: B = 0 … 70°C, F = -40 … 85°C, X = -40 … 105°C, K = -40 … 125°C, A = -40 … 140°C, L = -40 … 150°C, H = -40 … 110°C
4) ROM = Read Only Memory, EVR = Embedded Voltage Regulator
Published by
Infineon Technologies AG
85579 Neubiberg, Germany
© 2012 Infineon Technologies AG.
All Rights Reserved.
Visit us:
www.infineon.com
Date: 08 / 2012
Attention please!
The information given in this document shall in no event
be regarded as a guarantee of conditions or characteristics
(“Beschaffenheitsgarantie”). With respect to any examples
or hints given herein, any typical values stated herein and/
or any information regarding the application of the device,
Infineon Technologies hereby disclaims any and all warranties and liabilities of any kind, including without limitation warranties of non-infringement of intellectual property
rights of any third party.
Information
For further information on technology, delivery terms and
conditions and prices please contact your nearest Infineon
Technologies Office (www.infineon.com).
Warnings
Due to technical requirements components may contain
dangerous substances. For information on the types in
question please contact your nearest Infineon Technologies
Office. Infineon Technologies Components may only be
used in life-support devices or systems with the express
written approval of Infineon Technologies, if a failure of
such components can reasonably be expected to cause
the failure of that life-support device or system, or to affect
the safety or effectiveness of that device or system. Life
support devices or systems are intended to be implanted
in the human body, or to support and/or maintain and
sustain and/or protect human life. If they fail, it is reasonable to assume that the health of the user or other persons
may be endangered.