INFINEON TC1762

D a t a S h e e t , V 1 . 0 , A p r . 2 008
TC1762
32-Bit Single-Chip Microcontroller
TriCore
Microcontrollers
Edition 2008-04
Published by
Infineon Technologies AG
81726 München, Germany
© Infineon Technologies AG 2008.
All Rights Reserved.
Legal Disclaimer
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 noninfringement 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.
D a t a S h e e t , V 1 . 0 , A p r . 2 008
TC1762
32-Bit Single-Chip Microcontroller
TriCore
Microcontrollers
TC1762
Preliminary
TC1762 Data Sheet
Revision History: V1.0, 2008-04
Previous Version: V0.5 2007-03
Page
Subjects (major changes since last revision)
7
VSSOSC3 is deleted from the TC1762 Logic Symbol.
8, 10
TDATA0 of Pin 17, TCLK0 of Pin 20, TCLK0 of Pin 74 and TDATA0 of Pin
77 are updated in the Pinning Diagram and Pin Definition and Functions
Table.
33
Transmit DMA request in Block Diagram of ASC Interfaces is updated.
35
Alternate output functions in block diagram of SSC interfaces are updated.
41
Programmable baud rate of the MLI is updated.
42
TDATA0 and TCLK0 of the block diagram of MLI interfaces are updated.
54
The description for WDT double reset detection is updated.
91
The power sequencing details is updated.
102
MLI timing, maximum operating frequency limit is extended, t31 is added.
106
Thermal resistance junction leads is updated.
Trademarks
TriCore® is a trademark of Infineon Technologies AG.
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Data Sheet
V1.0, 2008-04
TC1762
Preliminary
Table of Contents
Table of Contents
1
Summary of Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3
2
2.1
2.2
2.3
2.4
2.5
General Device Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6
Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6
Logic Symbol . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7
Pin Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8
Pad Driver and Input Classes Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . .9
Pin Definitions and Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10
3
3.1
3.2
3.3
3.4
3.5
3.6
3.7
3.8
3.9
3.10
3.11
3.12
3.12.1
3.13
3.14
3.15
3.16
3.17
3.18
3.19
3.20
3.21
3.22
3.23
Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .24
System Architecture and On-Chip Bus Systems . . . . . . . . . . . . . . . . . . . . .24
On-Chip Memories . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .25
Architectural Address Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .27
Memory Protection System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .28
DMA Controller and Memory Checker . . . . . . . . . . . . . . . . . . . . . . . . . . . . .29
Interrupt System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .31
Asynchronous/Synchronous Serial Interfaces (ASC0, ASC1) . . . . . . . . . . .33
High-Speed Synchronous Serial Interface (SSC0) . . . . . . . . . . . . . . . . . . .35
Micro Second Bus Interface (MSC0) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .37
MultiCAN Controller (CAN) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .39
Micro Link Serial Bus Interface (MLI0) . . . . . . . . . . . . . . . . . . . . . . . . . . . . .41
General Purpose Timer Array . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .43
Functionality of GPTA0 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .44
Analog-to-Digital Converter (ADC0) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .47
Fast Analog-to-Digital Converter Unit (FADC) . . . . . . . . . . . . . . . . . . . . . . .49
System Timer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .51
Watchdog Timer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .54
System Control Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .55
Boot Options . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .56
Power Management System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .57
On-Chip Debug Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .58
Clock Generation and PLL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .60
Power Supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .63
Identification Register Values . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .64
4
4.1
4.1.1
4.1.2
4.1.3
4.1.4
4.2
Electrical Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .66
General Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .66
Parameter Interpretation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .66
Pad Driver and Pad Classes Summary . . . . . . . . . . . . . . . . . . . . . . . . . .67
Absolute Maximum Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .68
Operating Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .69
DC Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .72
Data Sheet
1
V1.0, 2008-04
TC1762
Preliminary
Table of Contents
4.2.1
4.2.2
4.2.3
4.2.4
4.2.5
4.2.6
4.3
4.3.1
4.3.2
4.3.3
4.3.4
4.3.5
4.3.6
4.3.7
4.3.8
4.3.8.1
4.3.8.2
4.3.8.3
Input/Output Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .72
Analog to Digital Converter (ADC0) . . . . . . . . . . . . . . . . . . . . . . . . . . . . .75
Fast Analog to Digital Converter (FADC) . . . . . . . . . . . . . . . . . . . . . . . . .82
Oscillator Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .86
Temperature Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .87
Power Supply Current . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .88
AC Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .89
Testing Waveforms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .89
Output Rise/Fall Times . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .90
Power Sequencing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .91
Power, Pad and Reset Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .93
Phase Locked Loop (PLL) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .95
Debug Trace Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .98
Timing for JTAG Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .99
Peripheral Timings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .102
Micro Link Interface (MLI) Timing . . . . . . . . . . . . . . . . . . . . . . . . . . .102
Micro Second Channel (MSC) Interface Timing . . . . . . . . . . . . . . . .104
Synchronous Serial Channel (SSC) Master Mode Timing . . . . . . . . .105
5
5.1
5.2
5.3
5.4
Packaging . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .106
Package Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .106
Package Outline . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .107
Flash Memory Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .108
Quality Declaration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .109
Data Sheet
2
V1.0, 2008-04
TC1762
Preliminary
1
Summary of Features
Summary of Features
The TC1762 has the following features:
•
•
•
•
•
•
High-performance 32-bit super-scaler TriCore v1.3 CPU with 4-stage pipeline
– Superior real-time performance
– Strong bit handling
– Fully integrated DSP capabilities
– Single precision Floating Point Unit (FPU)
– 66 or 80 MHz operation at full temperature range
Multiple on-chip memories
– 32 Kbyte Local Data Memory (SRAM)
– 4 Kbyte Overlay Memory
– 8 Kbyte Scratch-Pad RAM (SPRAM)
– 8 Kbyte Instruction Cache (ICACHE)
– 1024 Kbyte Flash Memory
– 16 Kbyte Data Flash (2 Kbyte EEPROM emulation)
– 16 Kbyte Boot ROM
8-channel DMA Controller
Fast-response interrupt system with 255 hardware priority arbitration levels serviced
by CPU
High-performance on-chip bus structure
– 64-bit Local Memory Bus (LMB) to Flash memory
– System Peripheral Bus (SPB) for interconnections of functional units
Versatile on-chip Peripheral Units
– Two Asynchronous/Synchronous Serial Channels (ASCs) with baudrate
generator, parity, framing and overrun error detection
– One High Speed Synchronous Serial Channel (SSC) with programmable data
length and shift direction
– One Micro Second Bus (MSC) interface for serial port expansion to external power
devices
– One high-speed Micro Link Interface (MLI) for serial inter-processor
communication
– One MultiCAN Module with two CAN nodes and 64 free assignable message
objects for high efficiency data handling via FIFO buffering and gateway data
transfer
– One General Purpose Timer Array Module (GPTA) with a powerful set of digital
signal filtering and timer functionality to realize autonomous and complex
Input/Output management
– One 16-channel Analog-to-Digital Converter unit (ADC) with selectable 8-bit, 10bit, or 12-bit, supporting 32 input channels
– One 2-channel Fast Analog-to-Digital Converter unit (FADC) with concatenated
comb filters for hardware data reduction: supporting 10-bit resolution, with
minimum conversion time of 262.5ns (@ 80 MHz) or 318.2ns (@ 66 MHz)
Data Sheet
3
V1.0, 2008-04
TC1762
Preliminary
•
•
•
•
•
•
•
•
•
•
•
Summary of Features
32 analog input lines for ADC and FADC
81 digital general purpose I/O lines
Digital I/O ports with 3.3 V capability
On-chip debug support for OCDS Level 1 and 2 (CPU, DMA)
Dedicated Emulation Device chip for multi-core debugging, tracing, and calibration
via USB V1.1 interface available (TC1766ED)
Power Management System
Clock Generation Unit with PLL
Core supply voltage of 1.5 V
I/O voltage of 3.3 V
Full automotive temperature range: -40° to +125°C
PG-LQFP-176-2 package
Data Sheet
4
V1.0, 2008-04
TC1762
Preliminary
Summary of Features
Ordering Information
The ordering code for Infineon microcontrollers provides an exact reference to the
required product. This ordering code identifies:
•
•
The derivative itself, i.e. its function set, the temperature range, and the supply
voltage
The package and the type of delivery
For the available ordering codes for the TC1762, please refer to the “Product Catalog
Microcontrollers” that summarizes all available microcontroller variants.
This document describes the derivatives of the device.The Table 1-1 enumerates these
derivatives and summarizes the differences.
Table 1-1
TC1762 Derivative Synopsis
Derivative
Ambient Temperature Range
SAK-TC1762-128F66HL
TA = -40oC to +125oC; 66 MHz operation frequency
SAK-TC1762-128F80HL
TA = -40oC to +125oC; 80 MHz operation frequency
Data Sheet
5
V1.0, 2008-04
TC1762
Preliminary
2
General Device Information
General Device Information
Chapter 2 provides the general information for the TC1762.
2.1
Block Diagram
Figure 2-1 shows the TC1762 block diagram.
FPU
PMI
8 KB SPRAM
8 KB ICACHE
DMI
32 KB LDRAM
TriCore
(TC1.3M)
Abbreviations:
ICACHE:
SPRAM:
LDRAM:
OVRAM:
BROM:
PFlash:
DFlash:
LMB:
SPB:
CPS
Local Memory Bus (LMB)
LFI Bridge
OCDS Debug
Interface/JTAG
SCU
PLL
PLL
Ports
f FPI
f CPU
DMA
BI0
GPTA
SBCU
8 ch.
SMIF
Ext.
Request
Unit
Multi CAN
(2 Nodes,
64 Buffer)
SSC0
ADC0
32 ch.
FADC
2 ch.
Ana log Inp ut
Assi gnme nt
ASC1
System Peri phe ral Bus (SPB)
ASC0
STM
DMA Bus
4 KB OVRAM
LBCU
BI1
16 KB BROM
1024 KB Pflash
16 KB DFlash
Overl ay
Me chan ism
PMU
Instruction Cache
Scratch-Pad RAM
Local Data RAM
Overlay RAM
Boot ROM
Program Flash
Data Flash
Local Memory Bus
System Peripheral Bus
MSC0
MLI0
Mem
Check
MCB06056
Figure 2-1
Data Sheet
TC1762 Block Diagram
6
V1.0, 2008-04
TC1762
Preliminary
2.2
General Device Information
Logic Symbol
Figure 2-2 shows the TC1762 logic symbol.
Alternate Functions
PORST
Port 0 16-bit
GPTA, SCU
Port 1 15-bit
GPTA, ADC
Port 2 14-bit
SSC0, MLI0, GPTA , MSC0
FCLP 0A
FCLN0
Port 3 16-bit
ASC0/1, SSC0, SCU, CAN
SOP0A
SON0
Port 4 4-bit
GPTA, SCU
Port 5 16-bit
GPTA, OCDS L 2, MLI0
HDRST
General Control
MSC0 Control
ADC Analog Inputs
NMI
BYPASS
TESTMODE
AN[35:0]
VDDM
TRST
VSSM
V DDMF
ADC/FADC Analog
Power Supply
TCK
TDI
TDO
TMS
BRKIN
TC1762
VSSMF
V DDAF
VSSAF
V AREF0
VAGND0
VFAREF
VFAGND
BRKOUT
TRCLK
XTAL1
XTAL2
VDDOSC3
VDDFL3
Digital Circuitry
Power Supply
VDD
OCDS / JTAG Control
7
Oscillator
VDDP
8
VDDOSC
V SS
9
VSSOSC
MCB06066
Figure 2-2
Data Sheet
TC1762 Logic Symbol
7
V1.0, 2008-04
TC1762
Preliminary
2.3
General Device Information
Pin Configuration
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
TC1762
132
131
130
129
128
127
126
125
124
123
122
121
120
119
118
117
116
115
114
113
112
111
110
109
108
107
106
105
104
103
102
101
100
99
98
97
96
95
94
93
92
91
90
89
P3.4/MTSR0
P3.7/SLSI0/SLSO02
P3.3/MRST0
P3.2/SCLK0
P3.8/SLSO06/TXD1A
P3.6/SLSO01/SLSO01
P3.5/SLSO00/SLSO00
VSS
VDDP
VDD
HDRST
PORST
NMI
BYPASS
TESTMODE
BRKIN
BRKOUT
TCK
TRST
TDO
TMS
TDI
P1.7/IN23/OUT23/OUT79
P1.6/IN22/OUT22/OUT78
P1.5/IN21/OUT21/OUT77
P1.4/IN20/EMG_IN/OUT20/OUT76
VDDOSC3
VDDOSC
VSSOSC
XTAL2
XTAL1
VSS
VDDP
VDD
P1.3/IN19/OUT19/OUT75
P1.11/IN27/IN51/OUT27/OUT51
P1.10/IN26/IN50/OUT26/OUT50
P1.9/IN25/IN49/OUT25/OUT49
P1.8/IN24/IN48/OUT24/OUT48
P1.2/IN18/OUT18/OUT74
P1.1/IN17/OUT17/OUT73
P1.0/IN16/OUT16/OUT72
P4.3/IN31/IN55/OUT31/OUT55/SYSCLK
N.C.
AN19
AN18
AN17
AN16
AN15
AN14
VAGND0
VAREF0
VSSM
VDDM
AN13
AN12
AN11
AN10
AN9
AN8
AN6
AN5
AN4
AN3
AN2
AN1
AN0
VDD
VDDP
VSS
AD0EMUX2/P1.14
AD0EMUX1/P1.13
AD0EMUX0/P1.12
TCLK0/OUT32/IN32/P2.0
SLSO03/OUT33/TREADY0A/IN33/P2.1
TVALID0A/OUT34/IN34/P2.2
TDATA0/OUT35/IN35/P2.3
OUT36/RCLK0A/IN36/P2.4
RREADY0A/OUT37/IN37/P2.5
OUT38/RVALID0A/IN38/P2.6
OUT39/RDATA0A/IN39/P2.7
VSS
VDDP
VDD
VSS
OUT52/OUT28/HWCFG0/IN52/IN28/P4.0
OUT53/OUT29/HWCFG1/IN53/IN29/P4.1
OUT54/OUT30/HWCFG2/IN54/IN30/P4.2
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
OCDSDBG0/OUT40/IN40/P5.0
OCDSDBG1/OUT41/IN41/P5.1
OCDSDBG2/OUT42/IN42/P5.2
OCDSDBG3/OUT43/IN43/P5.3
OCDSDBG4/OUT44/IN44/P5.4
OCDSDBG5/OUT45/IN45/P5.5
OCDSDBG6/OUT46/IN46/P5.6
OCDSDBG7/OUT47/IN47/P5.7
TRCLK
VDD
VDDP
VSS
OCDSDBG8/RDATA0B/P5.8
OCDSDBG9/RVALID0B/P5.9
OCDSDBG10/RREADY0B/P5.10
OCDSDBG11/RCLK0B/P5.11
OCDSDBG12/TDATA0/P5.12
OCDSDBG13/TVALID0B/P5.13
OCDSDBG14/TREADY0B/P5.14
OCDSDBG15/TCLK0/P5.15
N.C.
VSSAF
VDDAF
VDDMF
VSSMF
VFAREF
VFAGND
AN35
AN34
AN33
AN32
AN31
AN30
AN29
AN28
AN7
AN27
AN26
AN25
AN24
AN23
AN22
AN21
AN20
176
175
174
173
172
171
170
169
168
167
166
165
164
163
162
161
160
159
158
157
156
155
154
153
152
151
150
149
148
147
146
145
144
143
142
141
140
139
138
137
136
135
134
133
P0.15/IN15/SWCFG15/REQ5/OUT15/OUT71
P0.14/IN14/SWCFG14/REQ4/OUT14/OUT70
P0.7/IN7/SWCFG7/REQ3/OUT7/OUT63
P0.6/IN6/SWCFG6/REQ2/OUT6/OUT62
VSS
VDDP
VDD
P0.13/IN13/SWCFG13/OUT13/OUT69
P0.12/IN12/SWCFG12/OUT12/OUT68
P0.5/IN5/SWCFG5/OUT5/OUT61
P0.4/IN4/SWCFG4/OUT4/OUT60
P2.13/SDI0
P2.8/SLSO04/EN00
P2.12/SOP0B
P2.11/FCLP0B
P2.10/GPIO
P2.9/SLSO05/EN01
SOP0A
SON0
FCLP0A
FCLN0
VSS
VDDP
VDD
P0.11/IN11/SWCFG11/OUT11/OUT67
P0.10/IN10/SWCFG10/OUT10/OUT66
P0.9/IN9/SWCFG9/OUT9/OUT65
P0.8/IN8/SWCFG8/OUT8/OUT64
P0.3/IN3/SWCFG3/OUT3/OUT59
P0.2/IN2/SWCFG2/OUT2/OUT58
P0.1/IN1/SWCFG1/OUT1/OUT57
P0.0/IN0/SWCFG0/OUT0/OUT56
P3.11/REQ1
P3.12/RXDCAN0/RXD0B
P3.13/TXDCAN0/TXD0B
VDDFL3
VSS
VDDP
P3.9/RXD1A
P3.10/REQ0
P3.0/RXD0A
P3.1/TXD0A
P3.14/RXDCAN1/RXD1B
P3.15/TXDCAN1/TXD1B
Figure 2-3 shows the TC1762 pin configuration.
MCP06067
Figure 2-3
Data Sheet
TC1762 Pinning for PG-LQFP-176-2 Package
8
V1.0, 2008-04
TC1762
Preliminary
2.4
General Device Information
Pad Driver and Input Classes Overview
The TC1762 provides different types and classes of input and output lines. For
understanding of the abbreviations in Table 2-1 starting at the next page, Table 4-1
gives an overview on the pad type and class types.
Data Sheet
9
V1.0, 2008-04
TC1762
Preliminary
2.5
General Device Information
Pin Definitions and Functions
Table 2-1 shows the TC1762 pin definitions and functions.
Table 2-1
Symbol
Pin Definitions and Functions
Pins I/O Pad
Driver
Class
Power
Supply
Functions
VDDP
Port 0
Port 0 is a 16-bit bi-directional generalpurpose I/O port which can be alternatively
used for GPTA I/O lines or external trigger
inputs.
Parallel Ports
P0
I/O A1
P0.0
P0.1
P0.2
P0.3
P0.4
P0.5
P0.6
145
146
147
148
166
167
173
P0.7
174
P0.8
P0.9
P0.10
P0.11
P0.12
P0.13
P0.14
149
150
151
152
168
169
175
P0.15
176
IN0 / OUT0 /
IN1 / OUT1 /
IN2 / OUT2 /
IN3 / OUT3 /
IN4 / OUT4 /
IN5 / OUT5 /
IN6 / OUT6 /
REQ2
IN7 / OUT7 /
REQ3
IN8 / OUT8 /
IN9 / OUT9 /
IN10 / OUT10 /
IN11 / OUT11 /
IN12 / OUT12 /
IN13 / OUT13 /
IN14 / OUT14 /
REQ4
IN15 / OUT15 /
REQ5
OUT56 line of GPTA
OUT57 line of GPTA
OUT58 line of GPTA
OUT59 line of GPTA
OUT60 line of GPTA
OUT61 line of GPTA
OUT62 line of GPTA
External trigger input 2
OUT63 line of GPTA
External trigger input 3
OUT64 line of GPTA
OUT65 line of GPTA
OUT66 line of GPTA
OUT67 line of GPTA
OUT68 line of GPTA
OUT69 line of GPTA
OUT70 line of GPTA
External trigger input 4
OUT71 line of GPTA
External trigger input 5
In addition, the state of the port pins are
latched into the software configuration input
register SCU_SCLIR at the rising edge of
HDRST. Therefore, Port 0 pins can be used
for operating mode selections by software.
Data Sheet
10
V1.0, 2008-04
TC1762
Preliminary
Table 2-1
Symbol
General Device Information
Pin Definitions and Functions (cont’d)
Pins I/O Pad
Driver
Class
P1
I/O
Power
Supply
Functions
VDDP
Port 1
Port 1 is a 15-bit bi-directional general
purpose I/O port which can be alternatively
used for GPTA I/O lines and ADC0 interface.
P1.0
P1.1
P1.2
P1.3
P1.4
P1.5
P1.6
P1.7
P1.8
P1.9
P1.10
P1.11
P1.12
91
92
93
98
107
108
109
110
94
95
96
97
73
A1
A1
A1
A1
A1
A1
A1
A1
A2
A2
A2
A2
A1
IN16 / OUT16 /
IN17 / OUT17 /
IN18 / OUT18 /
IN19 / OUT19 /
IN20 / OUT20 /
IN21 / OUT21 /
IN22 / OUT22 /
IN23 / OUT23 /
IN24 / OUT24 /
IN25 / OUT25 /
IN26 / OUT26 /
IN27 / OUT27 /
AD0EMUX0
P1.13
72
A1
AD0EMUX1
P1.14
71
A1
AD0EMUX2
OUT72 line of GPTA
OUT73 line of GPTA
OUT74 line of GPTA
OUT75 line of GPTA
OUT76 line of GPTA
OUT77 line of GPTA
OUT78 line of GPTA
OUT79 line of GPTA
IN48 / OUT48 line of GPTA
IN49 / OUT49 line of GPTA
IN50 / OUT50 line of GPTA
IN51 / OUT51 line of GPTA
ADC0 external multiplexer
control output 0
ADC0 external multiplexer
control output 1
ADC0 external multiplexer
control output 2
In addition, P1.4 also serves as emergency
shut-off input for certain I/O lines (e.g. GPTA
related outputs).
Data Sheet
11
V1.0, 2008-04
TC1762
Preliminary
Table 2-1
Symbol
Pin Definitions and Functions (cont’d)
Pins I/O Pad
Driver
Class
P2
P2.0
P2.1
General Device Information
I/O
74
75
Power
Supply
Functions
VDDP
Port 2
Port 2 is a 14-bit bi-directional generalpurpose I/O port which can be alternatively
used for GPTA I/O, and interface for MLI0,
MSC0 or SSC0.
A2
TCLK0
A2
IN32 / OUT32
TREADY0A
P2.2
76
A2
IN33 / OUT33
SLSO03
TVALID0A
P2.3
77
A2
IN34 / OUT34
TDATA0
A1
IN35 / OUT35
RCLK0A
A2
IN36 / OUT36
RREADY0A
P2.4
P2.5
78
79
P2.6
80
A1
IN37 / OUT37
RVALID0A
P2.7
81
A1
IN38 / OUT38
RDATA0A
IN39 / OUT39
Data Sheet
12
MLI0 transmit channel clock
output A
line of GPTA
MLI0 transmit channel ready
input A
line of GPTA
SSC0 slave select output 3
MLI0 transmit channel valid
output A
line of GPTA
MLI0 transmit channel data
output A
line of GPTA
MLI0 receive channel clock
input A
line of GPTA
MLI0 receive channel ready
output A
line of GPTA
MLI0 receive channel valid
input A
line of GPTA
MLI0 receive channel data
input A
line of GPTA
V1.0, 2008-04
TC1762
Preliminary
Table 2-1
General Device Information
Pin Definitions and Functions (cont’d)
Symbol
Pins I/O Pad
Driver
Class
P2.8
164
A2
P2.9
160
A2
P2.10
P2.11
P2.12
P2.13
161
162
163
165
A2
A2
A2
A1
Data Sheet
Power
Supply
Functions
SLSO04
EN00
SLSO05
EN01
SSC0 Slave Select output 4
MSC0 enable output 0
SSC0 Slave Select output 5
MSC0 enable output 1
FCLP0B
SOP0B
SDI0
MSC0 clock output B
MSC0 serial data output B
MSC0 serial data input
13
V1.0, 2008-04
TC1762
Preliminary
Table 2-1
Symbol
General Device Information
Pin Definitions and Functions (cont’d)
Pins I/O Pad
Driver
Class
P3
P3.0
P3.1
I/O
136
135
A2
A2
Power
Supply
Functions
VDDP
Port 3
Port 3 is a 16-bit bi-directional generalpurpose I/O port which can be alternatively
used for ASC0/1, SSC0 and CAN lines.
RXD0A
TXD0A
ASC0 receiver inp./outp. A
ASC0 transmitter output A
This pin is sampled at the rising edge of
PORST. If this pin and the BYPASS input pin
are both active, then oscillator bypass mode
is entered.
P3.2
P3.3
129
130
A2
A2
SCLK0
MRST0
P3.4
132
A2
MTSR0
P3.5
P3.6
P3.7
126
127
131
A2
A2
A2
P3.8
128
A2
P3.9
P3.10
P3.11
P3.12
138
137
144
143
A2
A1
A1
A2
P3.13
142
A2
P3.14
134
A2
P3.15
133
A2
SLSO00
SLSO01
SLSI0
SLSO02
SLSO06
TXD1A
RXD1A
REQ0
REQ1
RXDCAN0
RXD0B
TXDCAN0
TXD0B
RXDCAN1
RXD1B
TXDCAN1
TXD1B
Data Sheet
14
SSC0 clock input/output
SSC0 master receive input/
slave transmit output
SSC0 master transmit
output/slave receive input
SSC0 slave select output 0
SSC0 slave select output 1
SSC0 slave select input
SSC0 slave select output 2
SSC0 slave select output 6
ASC1 transmitter output A
ASC1 receiver inp./outp. A
External trigger input 0
External trigger input 1
CAN node 0 receiver input
ASC0 receiver inp./outp. B
CAN node 0 transm. output
ASC0 transmitter output B
CAN node 1 receiver input
ASC1 receiver inp./outp. B
CAN node 1 transm. output
ASC1 transmitter output B
V1.0, 2008-04
TC1762
Preliminary
Table 2-1
Symbol
General Device Information
Pin Definitions and Functions (cont’d)
Pins I/O Pad
Driver
Class
P4
I/O
P4.[3:0]
Power
Supply
Functions
VDDP
Port 4 / Hardware Configuration Inputs
HWCFG[3:0]
Boot mode and boot location
inputs; inputs are latched
with the rising edge of
HDRST.
During normal operation, Port 4 pins may be
used as alternate functions for GPTA or
system clock output.
P4.0
P4.1
P4.2
P4.3
Data Sheet
86
87
88
90
A1
A1
A2
A2
IN28 / OUT28 /
IN29 / OUT29 /
IN30 / OUT30 /
IN31 / OUT31 /
SYSCLK
15
IN52 / OUT52 line of GPTA
IN53 / OUT53 line of GPTA
IN54 / OUT54 line of GPTA
IN55 / OUT55 line of GPTA
System Clock Output
V1.0, 2008-04
TC1762
Preliminary
Table 2-1
Symbol
Pin Definitions and Functions (cont’d)
Pins I/O Pad
Driver
Class
P5
P5.0
General Device Information
I/O A2
Power
Supply
Functions
VDDP
Port 5
Port 5 is a 16-bit bi-directional generalpurpose I/O port. In emulation, it is used as a
trace port for OCDS Level 2 debug lines. In
normal operation, it is used for GPTA I/O or
the MLI0 interface.
1
OCDSDBG0
2
IN40 / OUT40
OCDSDBG1
P5.2
3
IN41 / OUT41
OCDSDBG2
P5.3
4
IN42 / OUT42
OCDSDBG3
5
IN43 / OUT43
OCDSDBG4
6
IN44 / OUT44
OCDSDBG5
7
IN45 / OUT45
OCDSDBG6
8
IN46 / OUT46
OCDSDBG7
P5.1
P5.4
P5.5
P5.6
P5.7
IN47 / OUT47
Data Sheet
16
OCDS L2 Debug Line 0
(Pipeline Status Sig. PS0)
line of GPTA
OCDS L2 Debug Line 1
(Pipeline Status Sig. PS1)
line of GPTA
OCDS L2 Debug Line 2
(Pipeline Status Sig. PS2)
line of GPTA
OCDS L2 Debug Line 3
(Pipeline Status Sig. PS3)
line of GPTA
OCDS L2 Debug Line 4
(Pipeline Status Sig. PS4)
line of GPTA
OCDS L2 Debug Line 5
(Break Qualification Line
BRK0)
line of GPTA
OCDS L2 Debug Line 6
(Break Qualification Line
BRK1)
line of GPTA
OCDS L2 Debug Line 7
(Break Qualification Line
BRK2)
line of GPTA
V1.0, 2008-04
TC1762
Preliminary
Table 2-1
General Device Information
Pin Definitions and Functions (cont’d)
Symbol
Pins I/O Pad
Driver
Class
P5.8
13
Power
Supply
Functions
OCDSDBG8
RDATA0B
P5.9
14
OCDSDBG9
RVALID0B
P5.10
15
OCDSDBG10
RREADY0B
P5.11
16
OCDSDBG11
RCLK0B
P5.12
17
OCDSDBG12
TDATA0
P5.13
18
OCDSDBG13
TVALID0B
P5.14
19
OCDSDBG14
TREADY0B
P5.15
20
OCDSDBG15
TCLK0
Data Sheet
17
OCDS L2 Debug Line 8
(Indirect PC Addr. PC0)
MLI0 receive channel data
input B
OCDS L2 Debug Line 9
(Indirect PC Addr. PC1)
MLI0 receive channel valid
input B
OCDS L2 Debug Line 10
(Indirect PC Addr. PC2)
MLI0 receive channel ready
output B
OCDS L2 Debug Line 11
(Indirect PC Addr. PC3)
MLI0 receive channel clock
input B
OCDS L2 Debug Line 12
(Indirect PC Addr. PC04)
MLI0 transmit channel data
output B
OCDS L2 Debug Line 13
(Indirect PC Addr. PC05)
MLI0 transmit channel valid
output B
OCDS L2 Debug Line 14
(Indirect PC Address PC6)
MLI0 transmit channel ready
input B
OCDS L2 Debug Line 15
(Indirect PC Address PC7)
MLI0 transmit channel clock
output B
V1.0, 2008-04
TC1762
Preliminary
Table 2-1
Symbol
General Device Information
Pin Definitions and Functions (cont’d)
Pins I/O Pad
Driver
Class
Power
Supply
Functions
VDDP
LVDS MSC Clock and Data Outputs2)
MSC0 Differential Driver Clock Output
Positive A
MSC0 Differential Driver Clock Output
Negative
MSC0 Differential Driver Serial Data Output
Positive A
MSC0 Differential Driver Serial Data Output
Negative
MSC0 Outputs
C
FCLP0A 157
O
FCLN0
156
O
SOP0A
159
O
SON0
158
O
Data Sheet
18
V1.0, 2008-04
TC1762
Preliminary
Table 2-1
Symbol
General Device Information
Pin Definitions and Functions (cont’d)
Pins I/O Pad
Driver
Class
Power
Supply
Functions
–
Analog Input Port
The Analog Input Port provides altogether 36
analog input lines to ADC0 and FADC.
AN[31:0]: ADC0 analog inputs [31:0]
AN[35:32]: FADC analog differential inputs
Analog input 0
Analog input 1
Analog input 2
Analog input 3
Analog input 4
Analog input 5
Analog input 6
Analog input 7
Analog input 8
Analog input 9
Analog input 10
Analog input 11
Analog input 12
Analog input 13
Analog input 14
Analog input 15
Analog input 16
Analog input 17
Analog input 18
Analog input 19
Analog input 20
Analog input 21
Analog input 22
Analog input 23
Analog input 24
Analog input 25
Analog input 26
Analog input 27
Analog input 28
Analog input 29
Analog input 30
Analog Inputs
AN[35:0]
AN0
AN1
AN2
AN3
AN4
AN5
AN6
AN7
AN8
AN9
AN10
AN11
AN12
AN13
AN14
AN15
AN16
AN17
AN18
AN19
AN20
AN21
AN22
AN23
AN24
AN25
AN26
AN27
AN28
AN29
AN30
Data Sheet
I
67
66
65
64
63
62
61
36
60
59
58
57
56
55
50
49
48
47
46
45
44
43
42
41
40
39
38
37
35
34
33
D
19
V1.0, 2008-04
TC1762
Preliminary
Table 2-1
General Device Information
Pin Definitions and Functions (cont’d)
Symbol
Pins I/O Pad
Driver
Class
Power
Supply
Functions
AN31
AN32
AN33
AN34
AN35
32
31
30
29
28
I
D
–
Analog input 31
Analog input 32
Analog input 33
Analog input 34
Analog input 35
VDDP
VDDP
VDDP
VDDP
VDDP
VDDP
VDDP
JTAG Module Reset/Enable Input
Trace Clock for OCDS_L2 Lines2)
System I/O
TRST
114
I
A21)
TCK
115
I
A21)
TDI
111
I
A11)
TDO
113
O
A2
A2
1)
JTAG Module Clock Input
JTAG Module Serial Data Input
JTAG Module Serial Data Output
TMS
112
I
BRKIN
117
I/O A3
BRK
OUT
116
I/O A3
TRCLK
9
O
A4
NMI
120
I
A24)5)
HDRST
122
I/O A26)
VDDP
VDDP
VDDP
PORST
121
I
A24)
VDDP
Power-on Reset Input
BYPASS 119
I
A11)
VDDP
PLL Clock Bypass Select Input
This input has to be held stable during poweron resets. With BYPASS = 1, the spike filters
in the HDRST, PORST and NMI inputs are
switched off.
TEST
MODE
118
I
A24)8)
VDDP
Test Mode Select Input
For normal operation of the TC1762, this pin
should be connected to high level.
XTAL1
XTAL2
102
103
I
O
n.a.
VDDOSC
Oscillator/PLL/Clock Generator
Input/Output Pins
N.C.
21,
89
–
–
–
Not Connected
These pins are reserved for future extension
and must not be connected externally.
7)
Data Sheet
JTAG Module State Machine Control Input
OCDS Break Input (Alternate Output)2)3)
OCDS Break Output (Alternate Input)2)3)
Non-Maskable Interrupt Input
Hardware Reset Input /
Reset Indication Output
20
V1.0, 2008-04
TC1762
Preliminary
Table 2-1
Symbol
General Device Information
Pin Definitions and Functions (cont’d)
Pins I/O Pad
Driver
Class
Power
Supply
Functions
Power Supplies
VDDM
VSSM
VDDMF
VSSMF
VDDAF
54
–
–
–
ADC Analog Part Power Supply (3.3 V)
53
–
–
–
ADC Analog Part Ground for VDDM
24
–
–
–
FADC Analog Part Power Supply (3.3 V)
25
–
–
–
FADC Analog Part Ground for VDDMF
23
–
–
–
FADC Analog Part Logic Power Supply
(1.5 V)
VSSAF
VAREF0
VAGND0
VFAREF
VFAGND
VDDOSC
22
–
–
–
FADC Analog Part Logic Ground for VDDAF
52
–
–
–
ADC Reference Voltage
51
–
–
–
ADC Reference Ground
26
–
–
–
FADC Reference Voltage
27
–
–
–
FADC Reference Ground
105
–
–
–
Main Oscillator and PLL Power Supply
(1.5 V)
VDDOSC3
VSSOSC
VDDFL3
VDD
106
–
–
–
Main Oscillator Power Supply (3.3 V)
104
–
–
–
Main Oscillator and PLL Ground
141
–
–
–
Power Supply for Flash (3.3 V)
10, –
68,
84,
99,
123,
153,
170
–
–
Core Power Supply (1.5 V)
Data Sheet
21
V1.0, 2008-04
TC1762
Preliminary
Table 2-1
General Device Information
Pin Definitions and Functions (cont’d)
Symbol
Pins I/O Pad
Driver
Class
Power
Supply
Functions
VDDP
11, –
69,
83,
100,
124,
154,
171,
139
–
–
Port Power Supply (3.3 V)
VSS
12, –
70,
85,
101,
125,
155,
172,
140,
82
–
–
Ground
1) These pads are I/O pads with input only function. Its input characteristics are identical with the input
characteristics as defined for class A pads.
2) In case of a power-fail condition (one or more power supply voltages drop below the specified voltage range),
an undefined output driving level may occur at these pins.
3) Programmed by software as either break input or break output.
4) These pads are input only pads with input characteristics.
5) Input only pads with input spike filter.
6) Open drain pad with input spike filter.
7) The dual input reset system of TC1762/TC1766ED, assumes that the PORST reset pin is used for power-on
reset only. It has to be taken into account that if a system uses the PORST reset input for other system resets,
the emulation part of the TC1766ED Emulation Device is reset as well. Thus, it will always force a complete
re-initialization of the emulator and will prevent the user debugging across these types of resets.
8) Input only pads without input spike filter.
Data Sheet
22
V1.0, 2008-04
TC1762
Preliminary
Table 2-2
General Device Information
List of Pull-up/Pull-down Reset Behavior of the Pins
Pins
PORST = 0
All GPIOs, TDI, TMS, TDO
Pull-up
HDRST
Drive-low
Pull-up
BYPASS
Pull-up
High-impedance
TRST, TCK
High-impedance
Pull-down
TRCLK
High-impedance
BRKIN, BRKOUT, TESTMODE
Pull-up
NMI, PORST
Pull-down
Data Sheet
23
PORST = 1
V1.0, 2008-04
TC1762
Preliminary
3
Functional Description
Functional Description
Chapter 3 provides an overview of the TC1762 functional description.
3.1
System Architecture and On-Chip Bus Systems
The TC1762 has two independent on-chip buses (see also TC1762 block diagram on
Page 2-6):
•
•
Local Memory Bus (LMB)
System Peripheral Bus (SPB)
The LMB Bus connects the CPU local resources for data and instruction fetch. The Local
Memory Bus interconnects the memory units and functional units, such as CPU and
PMU. The main target of the LMB bus is to support devices with fast response times,
optimized for speed. This allows the DMI and PMI fast access to local memory and
reduces load on the FPI bus. The Tricore system itself is located on LMB bus.
The Local Memory Bus is a synchronous, pipelined, split bus with variable block size
transfer support. It supports 8-, 16-, 32- and 64-bit single transactions and variable
length 64-bit block transfers.
The SPB Bus is accessible to the CPU via the LMB Bus bridge. The System Peripheral
Bus (SPB Bus) in TC1762 is an on-chip FPI Bus. The FPI Bus interconnects the
functional units of the TC1762, such as the DMA and on-chip peripheral components.
The FPI Bus is designed to be quick to be acquired by on-chip functional units, and quick
to transfer data. The low setup overhead of the FPI Bus access protocol guarantees fast
FPI Bus acquisition, which is required for time-critical applications.The FPI Bus is
designed to sustain high transfer rates. For example, a peak transfer rate of up to 320
Mbyte/s can be achieved with a 80 MHz bus clock and 32-bit data bus. With a 66 MHz
bus clock, the peak transfer rate is up to 264 Mbytes/s. Multiple data transfers per bus
arbitration cycle allow the FPI Bus to operate at close to its peak bandwidth.
Both the LMB Bus and the SPB Bus runs at full CPU speed. The maximum CPU speed
is 66 or 80 MHz depending on the derivative.
Additionally, two simplified bus interfaces are connected to and controlled by the DMA
Controller:
•
•
DMA Bus
SMIF Interface
Data Sheet
24
V1.0, 2008-04
TC1762
Preliminary
3.2
Functional Description
On-Chip Memories
As shown in the TC1762 block diagram on Page 2-6, some of the TC1762 units provide
on-chip memories that are used as program or data memory.
•
•
•
•
•
Program memory in PMU
– 16 Kbyte Boot ROM (BROM)
– 1024 Kbyte Program Flash (PFlash)
Program memory in PMI
– 8 Kbyte Scratch-Pad RAM (SPRAM)
– 8 Kbyte Instruction Cache (ICACHE)
Data memory in PMU
– 16 Kbyte Data Flash (DFlash)
– 4 Kbyte Overlay RAM (OVRAM)
Data memory in DMI
– 32 Kbyte Local Data RAM (LDRAM)
On-chip SRAM with parity error protection
Features of Program Flash
•
•
•
•
•
•
•
•
•
•
•
•
•
1024 Kbyte on-chip program Flash memory
Usable for instruction code or constant data storage
256-byte program interface
– 256 bytes are programmed into PFLASH page in one step/command
256-bit read interface
– Transfer from PFLASH to CPU/PMI by four 64-bit single cycle burst transfers
Dynamic correction of single-bit errors during read access
Detection of double-bit errors
Fixed sector architecture
– Eight 16 Kbyte, one 128 Kbyte, one 256 Kbyte and one 512 Kbyte sectors
– Each sector separately erasable
– Each sector separately write-protectable
Configurable read protection for complete PFLASH with sophisticated read access
supervision, combined with write protection for complete PFLASH (protection against
“Trojan horse” software)
Configurable write protection for each sector
– Each sector separately write-protectable
– With capability to be re-programmed
– With capability to be locked forever (OTP)
Password mechanism for temporary disabling of write and read protection
On-chip generation of programming voltage
JEDEC-standard based command sequences for PFLASH control
– Write state machine controls programming and erase operations
– Status and error reporting by status flags and interrupt
Margin check for detection of problematic PFLASH bits
Data Sheet
25
V1.0, 2008-04
TC1762
Preliminary
Functional Description
Features of Data Flash
•
•
•
•
•
•
•
•
•
•
•
•
•
•
16 Kbyte on-chip data Flash memory, organized in two 8 Kbyte banks
Usable for data storage with EEPROM functionality
128 Byte of program interface
– 128 bytes are programmed into one DFLASH page by one step/command
64-bit read interface (no burst transfers)
Dynamic correction of single-bit errors during read access
Detection of double-bit errors
Fixed sector architecture
– Two 8 Kbyte banks/sectors
– Each sector separately erasable
Configurable read protection (combined with write protection) for complete DFLASH
together with PFLASH read protection
Password mechanism for temporary disabling of write and read protection
Erasing/programming of one bank possible while reading data from the other bank
Programming of one bank while erasing the other bank possible
On-chip generation of programming voltage
JEDEC-standard based command sequences for DFLASH control
– Write state machine controls programming and erase operations
– Status and error reporting by status flags and interrupt
Margin check for detection of problematic DFLASH bits
Data Sheet
26
V1.0, 2008-04
TC1762
Preliminary
3.3
Functional Description
Architectural Address Map
Table 3-1 shows the overall architectural address map as defined for the TriCore and as
implemented in TC1762.
Table 3-1
TC1762 Architectural Address Map
Segment
Contents
Size
Description
0-7
Global
8 x 256
Mbyte
Reserved (MMU space); cached
8
Global
Memory
256 Mbyte
Reserved (246 Mbyte); PMU, Boot ROM;
cached
9
Global
Memory
256 Mbyte
FPI space; cached
10
Global
Memory
256 Mbyte
Reserved (246 Mbyte), PMU, Boot ROM; noncached
11
Global
Memory
256 Mbyte
FPI space; non-cached
12
Local LMB
Memory
256 Mbyte
Reserved; bottom 4 Mbyte visible from FPI bus
in segment 14; cached
13
DMI
64 Mbyte
Local Data Memory RAM; non-cached
PMI
64 Mbyte
Local Code Memory RAM; non-cached
EXT_PER
96 Mbyte
Reserved; non-cached
EXT_EMU
16 Mbyte
Reserved; non-cached
BOOTROM
16 Mbyte
Boot ROM space, Boot ROM mirror;
non-cached
EXTPER
128 Mbyte
Reserved;
non-speculative; non-cached; no execution
CPU[0 ..15]
image region
16 x 8
Mbyte
Non-speculative; non-cached; no execution
LMB_PER
CSFRs
INT_PER
256
Mbyte
CSFRs of CPUs[0 ..15];
LMB & FPI Peripheral Space;
non-speculative; non-cached;
no execution
14
15
Data Sheet
27
V1.0, 2008-04
TC1762
Preliminary
3.4
Functional Description
Memory Protection System
The TC1762 memory protection system specifies the addressable range and read/write
permissions of memory segments available to the current executing task. The memory
protection system controls the position and range of addressable segments in memory.
It also controls the types of read and write operations allowed within addressable
memory segments. Any illegal memory access is detected by the memory protection
hardware, which then invokes the appropriate Trap Service Routine (TSR) to handle the
error. Thus, the memory protection system protects critical system functions against both
software and hardware errors. The memory protection hardware can also generate
signals to the Debug Unit to facilitate tracing illegal memory accesses.
There are two Memory Protection Register Sets in the TC1762, numbered 0 and 1,
which specify memory protection ranges and permissions for code and data. The
PSW.PRS bit field determines which of these is the set currently in use by the CPU. As
the TC1762 uses a Harvard-style memory architecture, each Memory Protection
Register Set is broken down into a Data Protection Register Set and a Code Protection
Register Set. Each Data Protection Register Set can specify up to four address ranges
to receive a particular protection modes. Each Code Protection Register Set can specify
up to two address ranges to receive a particular protection modes.
Each Data Protection Register Sets and Code Protection Register Sets determines the
range and protection modes for a separate memory area. Each set contains a pair of
registers which determine the address range (the Data Segment Protection Registers
and Code Segment Protection Registers) and one register (Data Protection Mode
Register) which determines the memory access modes that applies to the specified
range.
Data Sheet
28
V1.0, 2008-04
TC1762
Preliminary
3.5
Functional Description
DMA Controller and Memory Checker
The DMA Controller of the TC1762 transfers data from data source locations to data
destination locations without intervention of the CPU or other on-chip devices. One data
move operation is controlled by one DMA channel. Eight DMA channels are provided in
one DMA Sub-Block. The Bus Switch provides the connection of the DMA Sub-Block to
the two FPI Bus interfaces and an MLI bus interface. In the TC1762, the FPI Bus
interfaces are connected to the System Peripheral Bus and the DMA Bus. The third
specific bus interface provides a connection to the Micro Link Interface module (MLI0 in
the TC1762) and other DMA-related devices (Memory Checker module in the TC1762).
Clock control, address decoding, DMA request wiring, and DMA interrupt service request
control are implementation-specific and managed outside the DMA controller kernel.
Figure 3-1 shows the implementation details and interconnections of the DMA module.
fDMA
DMA Sub-Block 0
DMA
Requests
of
On-chip
Periph.
Units
Request
Selection/
CH0n_OUT
Arbitration
DMA
Channels
00-07
Address
Decoder
Interrupt
Request
Nodes
System
Periphera
Bus
DMA Bus
MLI
Interfac e
Transaction
Control Unit
Bus
Switch
FPI Bus
Int erface 0
DMA Controller
FPI Bus
Interface 1
Clock
Control
SR[15:0]
DMA Interrupt Control
MLI0
Memory
Checker
Arbiter/
Switch
Control
MCB06149
Figure 3-1
DMA Controller Block Diagram
Features
•
8 independent DMA channels
Data Sheet
29
V1.0, 2008-04
TC1762
Preliminary
•
•
•
•
•
•
•
•
•
•
Functional Description
– 8 DMA channels in the DMA Sub-Block
– Up to 8 selectable request inputs per DMA channel
– 2-level programmable priority of DMA channels within the DMA Sub-Block
– Software and hardware DMA request
– Hardware requests by selected on-chip peripherals and external inputs
Programmable priority of the DMA Sub-Blocks on the bus interfaces
Buffer capability for move actions on the buses (at least 1 move per bus is buffered).
Individually programmable operation modes for each DMA channel
– Single Mode: stops and disables DMA channel after a predefined number of DMA
transfers
– Continuous Mode: DMA channel remains enabled after a predefined number of
DMA transfers; DMA transaction can be repeated.
– Programmable address modification
Full 32-bit addressing capability of each DMA channel
– 4 Gbyte address range
– Support of circular buffer addressing mode
Programmable data width of DMA transfer/transaction: 8-bit, 16-bit, or 32-bit
Micro Link bus interface support
Register set for each DMA channel
– Source and destination address register
– Channel control and status register
– Transfer count register
Flexible interrupt generation (the service request node logic for the MLI channels is
also implemented in the DMA module)
All buses connected to the DMA module must work at the same frequency.
Read/write requests of the System Bus side to the peripherals on DMA Bus are
bridged to the DMA Bus (only the DMA is the master on the DMA bus), allowing easy
access to these peripherals by CPU
Memory Checker
The Memory Checker Module (MCHK) makes it possible to check the data consistency
of memories. Any SPB bus master may access the memory checker. It is preferable the
DMA does it as described hereafter. It uses DMA 8-bit, 16-bit, or 32-bit moves to read
from the selected address area and to write the value read in a memory checker input
register. With each write operation to the memory checker input register, a polynomial
checksum calculation is triggered and the result of the calculation is stored in the
memory checker result register.
The memory checker uses the standard Ethernet polynomial, which is given by:
G32 = x32+ x26+ x23+ x22+ x16+ x12+ x11+ x10+ x8+ x7+ x5+ x4+ x2+ x +1
Note: Although the polynomial above is used for generation, the generation algorithm
differs from the one that is used by the Ethernet protocol.
Data Sheet
30
V1.0, 2008-04
TC1762
Preliminary
3.6
Functional Description
Interrupt System
The TC1762 interrupt system provides a flexible and time-efficient means of processing
interrupts. An interrupt request is serviced by the CPU, which is called the “Service
Provider”. Interrupt requests are called “Service Requests” rather than “Interrupt
Requests” in this document.
Each peripheral in the TC1762 can generate service requests. Additionally, the Bus
Control Units, the Debug Unit, and even the CPU itself can generate service requests to
the Service Provider.
As shown in Figure 3-2, each TC1762 unit that can generate service requests is
connected to one or multiple Service Request Nodes (SRN). Each SRN contains a
Service Request Control Register mod_SRCx, where “mod” is the identifier of the
service requesting unit and “x” an optional index. The CPU Interrupt Arbitration Bus
connects the SRNs with the Interrupt Control Unit (ICU), which arbitrates service
requests for the CPU and administers the CPU Interrupt Arbitration Bus.
The Debug Unit can generate service requests to the CPU. The CPU makes service
requests directly to itself (via the ICU). The CPU Service Request Nodes are activated
through software.
Depending on the selected system clock frequency fSYS, the number of fSYS clock cycles
per arbitration cycle must be selected as follows:
•
•
fSYS < 60 MHz: ICR.CONECYC = 1
fSYS > 60 MHz: ICR.CONECYC = 0
Data Sheet
31
V1.0, 2008-04
TC1762
Preliminary
Functional Description
Service
Requestors
MSC0
Service Req.
Nodes
2
4
MLI0
SSC0
ASC0
ASC1
MultiCAN
ADC0
FADC
GPTA0
3
4
4
6
4
2
38
2
STM
1
FPU
1
Flash
Ext. Int
2
2 SRNs
4 SRNs
3 SRNs
CPU
Interrupt
Arbitration Bus
2
4
3
4 SRNs
4
4 SRNs
4
6 SRNs
4 SRNs
2 SRNs
38 SRNs
2 SRNs
1 SRN
1 SRN
2 SRNs
Interrupt
Service
Provider
CPU Interrupt
Control Unit
5
5 SRNs
6
CPU Interrupt
Control Unit
4
ICU
Int. Req.
2
PIPN
38
5
CPU
Int. Ack.
CCPN
Service Req.
Nodes
2
1
1
1
1
4
2
1
1 SRN
1
1 SRN
1 SRN
1 SRN
4 SRNs
Software
and
Breakpoint
Interrupts
Service
Requestors
1
1
4
1
1
LBCU
SBCU
DMA
Cerberus
DMA Bus
MCA06181
Figure 3-2
Data Sheet
Block Diagram of the TC1762 Interrupt System
32
V1.0, 2008-04
TC1762
Preliminary
3.7
Functional Description
Asynchronous/Synchronous Serial Interfaces (ASC0, ASC1)
Figure 3-3 shows a global view of the functional blocks and interfaces of the two
Asynchronous/Synchronous Serial Interfaces, ASC0 and ASC1.
Clock
Control
fASC
A2
P3.0 /
RXD0A
A2
P3.1 /
TXD0A
A2
P3.12 /
RXD0B
A2
P3.13 /
TXD0B
RXD_I0
Address
Decoder
Interrupt
Control
RXD_I1
ASC0
Module
(Kernel)
RXD_O
TXD_O
EIR
TBIR
TIR
RIR
ASC0_RDR
To
DMA
Port 3
Control
ASC0_TDR
RXD_I0
RXD_I1
ASC1
Module
(Kernel)
To
DMA
Figure 3-3
A2
P3.8 /
TXD1A
RXD_O
TXD_O
Interrupt
Control
P3.9 /
A2 RXD1A
EIR
TBIR
TIR
RIR
P3.14 /
A2 RXD1B
A2
P3.15 /
TXD1B
ASC1_RDR
ASC1_TDR
MCB06211c
Block Diagram of the ASC Interfaces
The ASC provides serial communication between the
microcontrollers, microprocessors, or external peripherals.
TC1762
and
other
The ASC supports full-duplex asynchronous communication and half-duplex
synchronous communication. In Synchronous Mode, data is transmitted or received
synchronous to a shift clock that is generated by the ASC internally. In Asynchronous
Mode, 8-bit or 9-bit data transfer, parity generation, and the number of stop bits can be
Data Sheet
33
V1.0, 2008-04
TC1762
Preliminary
Functional Description
selected. Parity, framing, and overrun error detection are provided to increase the
reliability of data transfers. Transmission and reception of data is double-buffered. For
multiprocessor communication, a mechanism is included to distinguish address bytes
from data bytes. Testing is supported by a loop-back option. A 13-bit baud rate generator
provides the ASC with a separate serial clock signal, which can be accurately adjusted
by a prescaler implemented as fractional divider.
Features
•
•
•
•
Full-duplex asynchronous operating modes
– 8-bit or 9-bit data frames, LSB first
– Parity-bit generation/checking
– One or two stop bits
– Baud rate from 5.0 Mbit/s to 1.19 bit/s (@ 80 MHz module clock) and 4.1Mbit/s to
0.98 bit/s (@ 66 MHz module clock)
– Multiprocessor mode for automatic address/data byte detection
– Loop-back capability
Half-duplex 8-bit synchronous operating mode
– Baud rate from 10.0 Mbit/s to 813.8 bit/s (@ 80 MHz module clock) and 8.25 Mbit/s
to 671.4 bit/s (@ 66 MHz module clock)
Double-buffered transmitter/receiver
Interrupt generation
– On a transmit buffer empty condition
– On a transmit last bit of a frame condition
– On a receive buffer full condition
– On an error condition (frame, parity, overrun error)
Data Sheet
34
V1.0, 2008-04
TC1762
Preliminary
3.8
Functional Description
High-Speed Synchronous Serial Interface (SSC0)
Figure 3-4 shows a global view of the functional blocks and interfaces of the high-speed
Synchronous Serial Interface, SSC0.
fSSC 0
Clock
Control
Master
fC L C0
Slave
Address
Decoder
Interrupt
Control
Slave
EIR
TIR
RIR
SSC0
Module
(Kernel)
Master
MRSTA
MRSTB
MTSR
A2 P3.4 /MTSR0
MTSRA
MTSRB
MRST
A2 P3.3 /MRST0
SCLKA
SCLKB
SCLK
A2 P3.2 /SCLK0
SLSI1
Slave
SLSI[7:2] 1 )
Port 3
Control
A2 P3.7 /SLSI0
A2 P3.5 /SLSO00
SLSO[2:0]
A2 P3.6 /SLSO01
SSC0_RDR
To
DMA
SSC0_TDR
Master
M/S Select 1 )
Enable 1 )
SLSO[5:3]
SLSO6
A2 P3.7 /SLSO02
SLSO7 1)
A2 P3.8 /SLSO06
A2 P2.1 /SLSO03
A2 P2.8 /SLSO04
Port 2
Control
A2 P2.9 /SLSO05
1) These lines are not connected
MCB06225
Figure 3-4
Block Diagram of the SSC Interfaces
The SSC supports full-duplex and half-duplex serial synchronous communication up to
40.0 MBaud at 80 MHz module clock and up to 33 MBaud at 66 MHz module clock. The
serial clock signal can be generated by the SSC itself (Master Mode) or can be received
from an external master (Slave Mode). Data width, shift direction, clock polarity and
phase are programmable. This allows communication with SPI-compatible devices.
Transmission and reception of data is double-buffered. A shift clock generator provides
the SSC with a separate serial clock signal. Seven slave select inputs are available for
Data Sheet
35
V1.0, 2008-04
TC1762
Preliminary
Functional Description
Slave Mode operation. Eight programmable slave select outputs (chip selects) are
supported in Master Mode.
Features
•
•
•
•
•
•
•
Master and Slave Mode operation
– Full-duplex or half-duplex operation
– Automatic pad control possible
Flexible data format
– Programmable number of data bits: 2 to 16 bits
– Programmable shift direction: LSB or MSB shift first
– Programmable clock polarity: Idle low or idle high state for the shift clock
– Programmable clock/data phase: Data shift with leading or trailing edge of the shift
clock
Baud rate generation from 40.0 Mbit/s to 610.36 bit/s (@ 80 MHz module clock) and
503.5 bit/s to 33 Mbit/s (@ 66 MHz module clock)
Interrupt generation
– On a transmitter empty condition
– On a receiver full condition
– On an error condition (receive, phase, baud rate, transmit error)
Flexible SSC pin configuration
Seven slave select inputs SLSI[7:1] in Slave Mode
Eight programmable slave select outputs SLSO[7:0] in Master Mode
– Automatic SLSO generation with programmable timing
– Programmable active level and enable control
Data Sheet
36
V1.0, 2008-04
TC1762
Preliminary
3.9
Functional Description
Micro Second Bus Interface (MSC0)
The MSC interface provides a serial communication link typically used to connect power
switches or other peripheral devices. The serial communication link includes a fast
synchronous downstream channel and a slow asynchronous upstream channel.
Figure 3-5 shows a global view of the MSC interface signals.
SR15 (from CAN)
fMSC0
FCLP
fCLC0
Address
Decoder
Interrupt
Control
SR[1:0]
To DMA
SR[3:2]
EMGSTOPMSC
(from SCU)
MSC0
Module
(Kernel)
C SON0
A2 P2.11 / FCLP0B
A2 P2.12 / SOP0B
EN0
SDI[0]1)
1) SDI[7:1] are connected to high level
Figure 3-5
C SOP0A
SON
16
16
C FCLN0
SOP
EN1
Upstream
Channel
ALTINL[15:0]
(from GPTA)
ALTINH[15:0]
C FCLP0A
FCLN
Downstream Channel
Clock
Control
A2 P2.8 / EN00
Port 2
Control
A2 P2.9 / EN01
A1 P2.13 / SDI0
MCA06255
Block Diagram of the MSC Interfaces
The downstream and upstream channels of the MSC module communicate with the
external world via nine I/O lines. Eight output lines are required for the serial
communication of the downstream channel (clock, data, and enable signals). One out of
eight input lines SDI[7:0] is used as serial data input signal for the upstream channel. The
source of the serial data to be transmitted by the downstream channel can be MSC
register contents or data that is provided at the ALTINL/ALTINH input lines. These input
lines are typically connected to other on-chip peripheral units (for example with a timer
unit like the GPTA). An emergency stop input signal makes it possible to set bits of the
serial data stream to dedicated values in emergency cases.
Data Sheet
37
V1.0, 2008-04
TC1762
Preliminary
Functional Description
Clock control, address decoding, and interrupt service request control are managed
outside the MSC module kernel. Service request outputs are able to trigger an interrupt
or a DMA request.
Features
•
•
•
Fast synchronous serial interface to connect power switches in particular, or other
peripheral devices via serial buses
High-speed synchronous serial transmission on downstream channel
– Serial output clock frequency: fFCL = fMSC/2
– Fractional clock divider for precise frequency control of serial clock fMSC
– Command, data, and passive frame types
– Start of serial frame: Software-controlled, timer-controlled, or free-running
– Programmable upstream data frame length (16 or 12 bits)
– Transmission with or without SEL bit
– Flexible chip select generation indicates status during serial frame transmission
– Emergency stop without CPU intervention
Low-speed asynchronous serial reception on upstream channel
– Baud rate: fMSC divided by 4, 8, 16, 32, 64, 128, or 256
– Standard asynchronous serial frames
– Parity error checker
– 8-to-1 input multiplexer for SDI lines
– Built-in spike filter on SDI lines
Data Sheet
38
V1.0, 2008-04
TC1762
Preliminary
3.10
Functional Description
MultiCAN Controller (CAN)
Figure 3-6 shows a global view of the MultiCAN module with its functional blocks and
interfaces.
fCAN
Clock
Control
MultiCAN Module Kernel
fCLC
Address
Decoder
Message
Object
Buffer
DMA
INT_O
[1:0]
Interrupt
Control
64
Objects
Linked
List
Control
CAN
Node 1
TXDC1
CAN
Node 0
TXDC0
RXDC1
RXDC0
P3.15 /
TXDCAN1
P3.14 /
A2
RXDCAN1
A2
Port 3
Control
P3.13 /
TXDCAN0
P3.12 /
A2
RXDCAN0
A2
INT_O
[5:2]
INT_O15
CAN Control
MCA06281
Figure 3-6
Block Diagram of MultiCAN Module
The MultiCAN module contains two independently-operating CAN nodes with Full-CAN
functionality that are able to exchange Data and Remote Frames via a gateway function.
Transmission and reception of CAN frames is handled in accordance with CAN
specification V2.0 B (active). Each CAN node can receive and transmit standard frames
with 11-bit identifiers as well as extended frames with 29-bit identifiers.
Both CAN nodes share a common set of message objects. Each message object can be
individually allocated to one of the CAN nodes. Besides serving as a storage container
for incoming and outgoing frames, message objects can be combined to build gateways
between the CAN nodes or to setup a FIFO buffer.
The message objects are organized in double-chained linked lists, where each CAN
node has its own list of message objects. A CAN node stores frames only into message
objects that are allocated to the message object list of the CAN node, and it transmits
only messages belonging to this message object list. A powerful, command-driven list
controller performs all message object list operations.
The bit timings for the CAN nodes are derived from the module timer clock (fCAN), and
are programmable up to a data rate of 1 Mbit/s. External bus transceivers are connected
to a CAN node via a pair of receive and transmit pins.
Data Sheet
39
V1.0, 2008-04
TC1762
Preliminary
Functional Description
MultiCAN Features
•
•
•
•
•
•
•
•
•
•
CAN functionality conforms to CAN specification V2.0 B active for each CAN node
(compliant to ISO 11898)
Two independent CAN nodes
64 independent message objects (shared by the CAN nodes)
Dedicated control registers for each CAN node
Data transfer rate up to 1Mbit/s, individually programmable for each node
Flexible and powerful message transfer control and error handling capabilities
Full-CAN functionality: message objects can be individually
– assigned to one of the two CAN nodes
– configured as transmit or receive object
– configured as message buffer with FIFO algorithm
– configured to handle frames with 11-bit or 29-bit identifiers
– provided with programmable acceptance mask register for filtering
– monitored via a frame counter
– configured for Remote Monitoring Mode
Automatic Gateway Mode support
6 individually programmable interrupt nodes
CAN analyzer mode for bus monitoring
Data Sheet
40
V1.0, 2008-04
TC1762
Preliminary
3.11
Functional Description
Micro Link Serial Bus Interface (MLI0)
The Micro Link Interface is a fast synchronous serial interface that allows data exchange
between microcontrollers of the 32-bit AUDO microcontroller family without intervention
of a CPU or other bus masters. Figure 3-7 shows how two microcontrollers are typically
connected together via their MLI interface. The MLI operates in both microcontrollers as
a bus master on the system bus.
Controller 1
Controller 2
CPU
CPU
Peripheral
A
Peripheral
B
Peripheral
C
Peripheral
D
Memory
MLI
MLI
Memory
System Bus
System Bus
MCA06061
Figure 3-7
Typical Micro Link Interface Connection
Features
•
•
•
•
•
•
•
•
•
Synchronous serial communication between MLI transmitters and MLI receivers
located on the same or on different microcontroller devices
Automatic data transfer/request transactions between local/remote controller
Fully transparent read/write access supported (= remote programming)
Complete address range of remote controller available
Specific frame protocol to transfer commands, addresses and data
Error control by parity bit
32-bit, 16-bit, and 8-bit data transfers
Programmable baud rates
– MLI transmitter baud rate: max. fMLI/2 (= 40 Mbit/s @ 80 MHz module clock)
– MLI receiver baud rate: max. fMLI
Multiple remote (slave) controllers are supported
MLI transmitter and MLI receiver communicate with other off-chip MLI receivers and MLI
transmitters via a 4-line serial I/O bus each. Several I/O lines of these I/O buses are
available outside the MLI module kernel as four-line output or input buses.
Data Sheet
41
V1.0, 2008-04
TC1762
Preliminary
Functional Description
Figure 3-8 shows a global view of the functional blocks of the MLI module with its
interfaces.
A2 P2.0 / TCLK0
TCLK
A2 P2.1 / TREADY0A
Transmitter
TREADYA
fML I0
Clock
Control
Address
Decoder
SR[3:0]
Interrupt
Control
TREADYD
Port 2
Control
TVALIDA
TVALIDB
TVALIDD
TDATA
A2 P2.3 / TDATA0
A1 P2.4 / RCLK0A
A2 P2.5 / RREADY0A
A1 P2.6 / RVALID0A
MLI 0
Module
(Kernel)
RCLKA
A1 P2.7 / RDATA0A
RCLKB
RCLKD
Receiver
BRKOUT
A2 P5.15 / TCLK0
RREADYA
RREADYB
SR[4:7]
To DMA
Cerberus
A2 P2.2 / TVALID0A
TREADYB
A2 P5.14 / TREADY0B
RREADYD
A2 P5.13 / TVALID0B
RVALIDA
RVALIDB
Port 5
Control
RVALIDD
RDATAA
RDATAB
A2 P5.12 / TDATA0
A2 P5.11 / RCLK0B
A2 P5.10 / RREADY0B
RDATAD
A2 P5.9 / RVALID0B
A2 P5.8 / RDATA0B
MCB06322
Figure 3-8
Data Sheet
Block Diagram of the MLI Module
42
V1.0, 2008-04
TC1762
Preliminary
3.12
Functional Description
General Purpose Timer Array
The GPTA provides a set of timer, compare, and capture functionalities that can be
flexibly combined to form signal measurement and signal generation units. They are
optimized for tasks typical of engine, gearbox, electrical motor control applications, but
can also be used to generate simple and complex signal waveforms needed in other
industrial applications.
The TC1762 contains one General Purpose Timer Array (GPTA0). Figure 3-9 shows a
global view of the GPTA module.
GPTA
Clock Generation Unit
FPC0
FPC1
DCM0
PDL0
DCM1
FPC2
FPC3
FPC4
DCM2
DIGITAL
PLL
PDL1
DCM3
FPC5
Clock
Conn.
Clock Bus
fGPTA Clock Distribution Unit
GT0
GT1
Signal
Generation Unit
GTC00
GTC01
GTC02
GTC03
LTC00
LTC01
LTC02
LTC03
Global
Timer
Cell Array
Local
Timer
Cell Array
GTC30
GTC31
LTC62
LTC63
I/O Line Sharing Unit
Interrupt Sharing Unit
MCB06063
Figure 3-9
Data Sheet
Block Diagram of the GPTA Module
43
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Preliminary
3.12.1
Functional Description
Functionality of GPTA0
The General Purpose Timer Array GPTA0 provides a set of hardware modules required
for high-speed digital signal processing:
•
•
•
•
•
•
•
Filter and Prescaler Cells (FPC) support input noise filtering and prescaler operation.
Phase Discrimination Logic units (PDL) decode the direction information output by a
rotation tracking system.
Duty Cycle Measurement Cells (DCM) provide pulse-width measurement
capabilities.
A Digital Phase Locked Loop unit (PLL) generates a programmable number of GPTA
module clock ticks during an input signal’s period.
Global Timer units (GT) driven by various clock sources are implemented to operate
as a time base for the associated Global Timer Cells.
Global Timer Cells (GTC) can be programmed to capture the contents of a Global
Timer on an external or internal event. A GTC may also be used to control an external
port pin depending on the result of an internal compare operation. GTCs can be
logically concatenated to provide a common external port pin with a complex signal
waveform.
Local Timer Cells (LTC) operating in Timer, Capture, or Compare Mode may also be
logically tied together to drive a common external port pin with a complex signal
waveform. LTCs — enabled in Timer Mode or Capture Mode — can be clocked or
triggered by various external or internal events.
Input lines can be shared by an LTC and a GTC to trigger their programmed operation
simultaneously.
The following list summarizes the specific features of the GPTA unit.
Clock Generation Unit
•
•
Filter and Prescaler Cell (FPC)
– Six independent units
– Three basic operating modes:
Prescaler, Delayed Debounce Filter, Immediate Debounce Filter
– Selectable input sources:
Port lines, GPTA module clock, FPC output of preceding FPC cell
– Selectable input clocks:
GPTA module clock, prescaled GPTA module clock, DCM clock, compensated or
uncompensated PLL clock
– fGPTA/2 maximum input signal frequency in Filter Modes
Phase Discriminator Logic (PDL)
– Two independent units
– Two operating modes (2- and 3-sensor signals)
– fGPTA/4 maximum input signal frequency in 2-sensor Mode, fGPTA/6 maximum input
signal frequency in 3-sensor Mode
Data Sheet
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TC1762
Preliminary
•
•
•
Functional Description
Duty Cycle Measurement (DCM)
– Four independent units
– 0 - 100% margin and time-out handling
– fGPTA maximum resolution
– fGPTA/2 maximum input signal frequency
Digital Phase Locked Loop (PLL)
– One unit
– Arbitrary multiplication factor between 1 and 65535
– fGPTA maximum resolution
– fGPTA/2 maximum input signal frequency
Clock Distribution Unit (CDU)
– One unit
– Provides nine clock output signals:
fGPTA, divided fGPTA clocks, FPC1/FPC4 outputs, DCM clock, LTC prescaler clock
Signal Generation Unit
•
•
•
Global Timers (GT)
– Two independent units
– Two operating modes (Free-Running Timer and Reload Timer)
– 24-bit data width
– fGPTA maximum resolution
– fGPTA/2 maximum input signal frequency
Global Timer Cell (GTC)
– 32 units related to the Global Timers
– Two operating modes (Capture, Compare and Capture after Compare)
– 24-bit data width
– fGPTA maximum resolution
– fGPTA/2 maximum input signal frequency
Local Timer Cell (LTC)
– 64 independent units
– Three basic operating modes (Timer, Capture and Compare) for 63 units
– Special compare modes for one unit
– 16-bit data width
– fGPTA maximum resolution
– fGPTA/2 maximum input signal frequency
Interrupt Control Unit
•
111 interrupt sources, generating up to 38 service requests
Data Sheet
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TC1762
Preliminary
Functional Description
I/O Sharing Unit
•
Interconnecting inputs and outputs from internal clocks, FPC, GTC, LTC, ports, and
MSC interface
Data Sheet
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V1.0, 2008-04
TC1762
Preliminary
3.13
Functional Description
Analog-to-Digital Converter (ADC0)
Section 3.13 shows the global view of the ADC module with its functional blocks and
interfaces and the features which are provided by the module.
VDDM
VDD
VAGND0 VSS VSSM VAREF0
Clock
Control
fADC
GPRS
fCLC
EMUX0
A1
Port 1
Control
A1 P1.13 /AD0EMUX1
EMUX1
To DMA
SR[3:0]
SR[7:4]
ADC0
Module
Kernel
AIN0
Group 0
Analog Multiplexer
Interrupt
Control
A1 P1.12 /AD0EMUX0
ASGT
SW0TR, SW0GT External
ETR, EGT
Request
Unit
QTR, QGT
(SCU)
TTR, TGT
Address
Decoder
AIN15
AIN16
Group 1
0
P1.14 /
AD0EMUX2 (GRPS)
AIN30
AIN31
1
8
From Ports
2
From MSC0
6
From GPTA
D
AN0
D
AN15
D
AN16
D
AN30
D
AN31
Die
Temperature
Measurement
SCU_CON.DTSON
MCA06427
Figure 3-10 Block Diagram of the ADC Module
The ADC module has 16 analog input channels. An analog multiplexer selects the input
line for the analog input channels from among 32 analog inputs. Additionally, an external
analog multiplexer can be used for analog input extension. External Clock control,
address decoding, and service request (interrupt) control are managed outside the ADC
module kernel. External trigger conditions are controlled by an External Request Unit.
This unit generates the control signals for auto-scan control (ASGT), software trigger
control (SW0TR, SW0GT), the event trigger control (ETR, EGT), queue control (QTR,
QGT), and timer trigger control (TTR, TGT).
An automatic self-calibration adjusts the ADC module to changing temperatures or
process variations. Figure 3-10 shows the global view of the ADC module with its
functional blocks and interfaces.
Data Sheet
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TC1762
Preliminary
Functional Description
Features
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
8-bit, 10-bit, 12-bit A/D conversion
Conversion time below 2.5µs @ 10-bit resolution
Extended channel status information on request source
Successive approximation conversion method
Total Unadjusted Error (TUE) of ±2 LSB @ 10-bit resolution
Integrated sample & hold functionality
Direct control of up to 16 analog input channels
Dedicated control and status registers for each analog channel
Powerful conversion request sources
Selectable reference voltages for each channel
Programmable sample and conversion timing schemes
Limit checking
Flexible ADC module service request control unit
Automatic control of external analog multiplexers
Equidistant samples initiated by timer
External trigger and gating inputs for conversion requests
Power reduction and clock control feature
On-chip die temperature sensor output voltage measurement
Data Sheet
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V1.0, 2008-04
TC1762
Preliminary
3.14
Functional Description
Fast Analog-to-Digital Converter Unit (FADC)
The on-chip FADC module of the TC1762 basically is a 2-channel A/D converter with 10bit resolution that operates by the method of the successive approximation.
As shown in Figure 3-11, the main FADC functional blocks are:
•
•
•
•
•
•
The Input Stage — contains the differential inputs and the programmable amplifier
The A/D Converter — is responsible for the analog-to-digital conversion
The Data Reduction Unit — contains programmable antialiasing and data reduction
filters
The Channel Trigger Control block — determines the trigger and gating conditions
for the two FADC channels
The Channel Timers — can independently trigger the conversion of each FADC
channel
The A/D Control block is responsible for the overall FADC functionality
The FADC module is supplied by the following power supply and reference voltage lines:
•
•
•
VDDMF/VDDMF:FADC Analog Part Power Supply (3.3 V)
VDDAF/VDDAF:FADC Analog Part Logic Power Supply (1.5 V)
VFAREF/VFAGND:FADC Reference Voltage (3.3 V)/FADC Reference Ground
Data Sheet
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V1.0, 2008-04
TC1762
Preliminary
Functional Description
VFAREF VDDAF VDDMF
VFAGND VSSAF
VSSMF
fFADC
Clock
Control
fCLC
FAIN0P
Address
Decoder
FAIN0N
FAIN1P
Interrupt
Control
SR[1:0]
FAIN1N
FADC
Module
Kernel
SR[3:2]
D AN32
D AN33
D AN34
D AN35
DMA
GPTA0
OUT1
OUT9
OUT18
OUT26
OUT2
OUT10
OUT19
OUT27
A1 P3.10 / REQ0
A1 P3.11 / REQ1
GS[7:0]
TS[7:0]
A1 P0.14 / REQ4
A1 P0.15 / REQ5
PDOUT2
External Request Unit
(SCU)
PDOUT3
MCA06445
Figure 3-11 Block Diagram of the FADC Module
Features
•
•
•
•
•
•
•
•
•
•
Extreme fast conversion, 21 cycles of fFADC clock (262.5 ns @ fFADC = 80 MHz and
318.2 ns @ fFADC = 66 MHz)
10-bit A/D conversion
– Higher resolution by averaging of consecutive conversions is supported
Successive approximation conversion method
Two differential input channels
Offset and gain calibration support for each channel
Differential input amplifier with programmable gain of 1, 2, 4 and 8 for each channel
Free-running (Channel Timers) or triggered conversion modes
Trigger and gating control for external signals
Built-in Channel Timers for internal triggering
Channel timer request periods independently selectable for each channel
Data Sheet
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TC1762
Preliminary
•
Functional Description
Selectable, programmable anti-aliasing and data reduction filter block
3.15
System Timer
The TC1762’s STM is designed for global system timing applications requiring both high
precision and long period.
Features
•
•
•
•
•
•
•
•
•
Free-running 56-bit counter
All 56 bits can be read synchronously
Different 32-bit portions of the 56-bit counter can be read synchronously
Flexible interrupt generation based on compare match with partial STM content
Driven by maximum 66 or 80 MHz (= fSYS, default after reset = fSYS/2) depending on
derivative
Counting starts automatically after a reset operation
STM is reset by:
– Watchdog reset
– Software reset (RST_REQ.RRSTM must be set)
– Power-on reset
STM (and clock divider STM_CLC.RMC) is not reset at a hardware reset (HDRST =
0)
STM can be halted in debug/suspend mode (via STM_CLC register)
The STM is an upward counter, running either at the system clock frequency fSYS or at a
fraction of it. The STM clock frequency is fSTM = fSYS/RMC with RMC = 0-7 (default after
reset is fSTM = fSYS/2, selected by RMC = 010B). RMC is a bit field in register STM_CLC.
In case of a power-on reset, a watchdog reset, or a software reset, the STM is reset. After
one of these reset conditions, the STM is enabled and immediately starts counting up. It
is not possible to affect the content of the timer during normal operation of the TC1762.
The timer registers can only be read but not written to.
The STM can be optionally disabled for power-saving purposes, or suspended for
debugging purposes via its clock control register. In suspend mode of the TC1762
(initiated by writing an appropriate value to STM_CLC register), the STM clock is
stopped but all registers are still readable.
Due to the 56-bit width of the STM, it is not possible to read its entire content with one
instruction. It needs to be read with two load instructions. Since the timer would continue
to count between the two load operations, there is a chance that the two values read are
not consistent (due to possible overflow from the low part of the timer to the high part
between the two read operations). To enable a synchronous and consistent reading
operation of the STM content, a capture register (STM_CAP) is implemented. It latches
the content of the high part of the STM each time when one of the registers STM_TIM0
to STM_TIM5 is read. Thus, STM_CAP holds the upper value of the timer at exactly the
Data Sheet
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TC1762
Preliminary
Functional Description
same time when the lower part is read. The second read operation would then read the
content of the STM_CAP to get the complete timer value.
The STM can also be read in sections from seven registers, STM_TIM0 through
STM_TIM6, that select increasingly higher-order 32-bit ranges of the STM. These can
be viewed as individual 32-bit timers, each with a different resolution and timing range.
The content of the 56-bit System Timer can be compared with the content of two
compare values stored in the STM_CMP0 and STM_CMP1 registers. Interrupts can be
generated on a compare match of the STM with the STM_CMP0 or STM_CMP1
registers.
The maximum clock period is 256 × fSTM. At fSTM = 80 MHz, for example, the STM counts
28.56 years before overflowing. Thus, it is capable of timing the entire expected product
life-time of a system without overflowing continuously.
Figure 3-12 shows an overview on the System Timer with the options for reading parts
of the STM contents.
Data Sheet
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TC1762
Preliminary
Functional Description
STM Module
31
23
STM_CMP0
15
7
0
Compare Register 0
31
23
STM_CMP1
15
7
0
Compare Register1
STMIR1
Interrupt
Control
Clock
Control
55
47
39
31
23
15
7
0
56-Bit System Timer
STMIR0
Enable /
Disable
00H
STM_CAP
fSTM
00H
STM_TIM6
STM_TIM5
Address
Decoder
STM_TIM4
STM_TIM3
PORST
STM_TIM2
STM_TIM1
STM_TIM0
MCB06185
Figure 3-12 General Block Diagram of the STM Module Registers
Data Sheet
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V1.0, 2008-04
TC1762
Preliminary
3.16
Functional Description
Watchdog Timer
The WDT provides a highly reliable and secure way to detect and recover from software
or hardware failure. The WDT helps to abort an accidental malfunction of the TC1762 in
a user-specified time period. When enabled, the WDT will cause the TC1762 system to
be reset if the WDT is not serviced within a user-programmable time period. The CPU
must service the WDT within this time interval to prevent the WDT from causing a
TC1762 system reset. Hence, routine service of the WDT confirms that the system is
functioning as expected.
In addition to this standard “Watchdog” function, the WDT incorporates the End-ofInitialization (Endinit) feature and monitors its modifications. A system-wide line is
connected to the WDT_CON0.ENDINIT bit, serving as an additional write-protection for
critical registers (besides Supervisor Mode protection). Registers protected via this line
can only be modified when Supervisor Mode is active and bit ENDINIT = 0.
A further enhancement in the TC1762’s WDT is its reset prewarning operation. Instead
of resetting the device upon the detection of an error immediately (the way that standard
Watchdogs do), the WDT first issues a Non-Maskable Interrupt (NMI) to the CPU before
resetting the device at a specified time period later. This step gives the CPU a chance to
save the system state to the memory for later investigation of the cause of the
malfunction; an important aid in debugging.
Features
•
•
•
•
•
•
•
•
•
•
16-bit Watchdog counter
Selectable input frequency: fSYS/256 or fSYS/16384
16-bit user-definable reload value for normal Watchdog operation, fixed reload value
for Time-Out and Prewarning Modes
Incorporation of the ENDINIT bit and monitoring of its modifications
Sophisticated Password Access mechanism with fixed and user-definable password
fields
Proper access always requires two write accesses. The time between the two
accesses is monitored by the WDT and is limited.
Access Error Detection: Invalid password (during first access) or invalid guard bits
(during second access) trigger the Watchdog reset generation
Overflow Error Detection: An overflow of the counter triggers the Watchdog reset
generation.
Watchdog function can be disabled; access protection and ENDINIT monitor function
remain enabled.
Double Reset Detection: If a Watchdog induced reset occurs twice, a severe system
malfunction is assumed and the TC1762 is held in reset until a power-on or hardware
reset occurs. This prevents the device from being periodically reset if, for instance,
connection to the external memory has been lost such that system initialization could
not even be performed.
Data Sheet
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TC1762
Preliminary
•
Functional Description
Important debugging support is provided through the reset prewarning operation by
first issuing an NMI to the CPU before finally resetting the device after a certain
period of time.
3.17
System Control Unit
The System Control Unit (SCU) of the TC1762 handles several system control tasks.
The system control tasks of the SCU are:
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Clock system selection and control
Reset and boot operation control
Power management control
Configuration input sampling
External Request Unit
System clock output control
On-chip SRAM parity control
Pad driver temperature compensation control
Emergency stop input control for GPTA outputs
GPTA input IN1 control
Pad test mode control for dedicated pins
ODCS level 2 trace control
NMI control
Miscellaneous SCU control
Data Sheet
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V1.0, 2008-04
TC1762
Preliminary
3.18
Functional Description
Boot Options
The TC1762 booting schemes provide a number of different boot options for the start of
code execution. Table 3-2 shows the boot options available in the TC1762.
Table 3-2
BRKIN
TC1762 Boot Selections
HWCFG
[3:0]
TESTMODE Type of Boot
BootROM
Exit Jump
Address
Normal Boot Options
1
0000B
1
Enter bootstrap loader mode 1:
Serial ASC0 boot via ASC0 pins
D400 0000H
0001B
Enter bootstrap loader mode 2:
Serial CAN boot via P3.12 and
P3.13 pins
0010B
Start from internal PFLASH
0011B
Alternate boot mode (ABM): Start Defined in
from internal PFLASH after CRC ABM header
check is correctly executed; enter or D400 0000H
a serial bootstrap loader mode1) if
CRC check fails
1111B
Enter bootstrap loader mode 3:
Serial ASC0 boot via P3.12 and
P3.13 pins
D400 0000H
others
Reserved; execute stop loop
–
A000 0000H
Debug Boot Options
0
0000B
1
Tri-state chip
–
others
irrel.
Reserved; execute stop loop
–
1) The type of the alternate bootstrap loader mode is selected by the value of the SCU_SCLIR.SWOPT[2:0] bit
field, which contains the levels of the P0.[2:0] latched in with the rising edge of the HDRST.
Data Sheet
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V1.0, 2008-04
TC1762
Preliminary
3.19
Functional Description
Power Management System
The TC1762 power management system allows software to configure the various
processing units so that they automatically adjust to draw the minimum necessary power
for the application. There are three power management modes:
•
•
•
Run Mode
Idle Mode
Sleep Mode
The operation of each system component in each of these states can be configured by
software. The power-management modes provide flexible reduction of power
consumption through a combination of techniques, including stopping the CPU clock,
stopping the clocks of other system components individually, and individually clockspeed reduction of some peripheral components.
Besides these explicit software-controlled power-saving modes, special attention has
been paid to automatic power-saving in those operating units which are not required at
a certain point of time, or idle in the TC1762. In that case, they are shut off automatically
until their operation is required again.
Table 3-3 describes the features of the power management modes.
Table 3-3
Power Management Mode Summary
Mode
Description
Run
The system is fully operational. All clocks and peripherals are enabled,
as determined by software.
Idle
The CPU clock is disabled, waiting for a condition to return it to Run
Mode. Idle Mode can be entered by software when the processor has no
active tasks to perform. All peripherals remain powered and clocked.
Processor memory is accessible to peripherals. A reset, Watchdog
Timer event, a falling edge on the NMI pin, or any enabled interrupt event
will return the system to Run Mode.
Sleep
The system clock signal is distributed only to those peripherals
programmed to operate in Sleep Mode. The other peripheral module will
be shut down by the suspend signal. Interrupts from operating
peripherals, the Watchdog Timer, a falling edge on the NMI pin, or a
reset event will return the system to Run Mode. Entering this state
requires an orderly shut-down controlled by the Power Management
State Machine.
In typical operation, Idle Mode and Sleep Mode may be entered and exited frequently
during the run time of an application. For example, system software will typically cause
the CPU to enter Idle Mode each time it has to wait for an interrupt before continuing its
tasks. In Sleep Mode and Idle Mode, wake-up is performed automatically when any
Data Sheet
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TC1762
Preliminary
Functional Description
enabled interrupt signal is detected, or when the count value (WDT_SR.WDTTIM)
changes from 7FFFH to 8000H.
3.20
On-Chip Debug Support
Figure 3-13 shows a block diagram of the TC1762 OCDS system.
OCDS
L1
BCU
SPB
Peripheral
Unit n
JDI
Debug
I/F
TRST
BRKIN
MCBS
Break
Switch
BRKOUT
DMA
System Peripheral Bus
TCK
JTAG
Controller
OSCU
B reak an d S uspe nd Si gna ls
TDI
Cerberus
Watchdog
Timer
TDO
TMS
Ena ble , C ontrol a nd R eset
OCDS
OCDS
TriCore
L2
L1
DMA L2
16
OCDS2[15:0]
Multiplexer
SPB
Peripheral
Unit 1
MCB06195
Figure 3-13 OCDS System Block Diagram
The TC1762 basically supports three levels of debug operation:
•
•
•
OCDS Level 1 debug support
OCDS Level 2 debug support
OCDS Level 3 debug support
Data Sheet
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TC1762
Preliminary
Functional Description
OCDS Level 1 Debug Support
The OCDS Level 1 debug support is mainly assigned for real-time software debugging
purposes which have a demand for low-cost standard debugger hardware.
The OCDS Level 1 is based on a JTAG interface that is used by the external debug
hardware to communicate with the system. The on-chip Cerberus module controls the
interactions between the JTAG interface and the on-chip modules. The external debug
hardware may become master of the internal buses, and read or write the on-chip
register/memory resources. The Cerberus also makes it possible to define breakpoint
and trigger conditions as well as to control user program execution (run/stop, break,
single-step).
OCDS Level 2 Debug Support
The OCDS Level 2 debug support makes it possible to implement program tracing
capabilities for enhanced debuggers by extending the OCDS Level 1 debug functionality
with an additional 16-bit wide trace output port with trace clock. With the trace extension,
the following four trace capabilities are provided (only one of the three trace capabilities
can be selected at a time):
•
•
•
Trace of the CPU program flow
Trace of the DMA Controller transaction requests
Trace of the DMA Controller Move Engine status information
OCDS Level 3 Debug Support
The OCDS Level 3 debug support is based on a special TC1766 emulation device, the
TC1766ED, which provides additional features required for high-end emulation
purposes. The TC1766ED is a device which includes the TC1766 product chip and
additional emulation extension hardware in a package with the same footprint as the
TC1766.
Data Sheet
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TC1762
Preliminary
3.21
Functional Description
Clock Generation and PLL
The TC1762 clock system performs the following functions:
•
•
•
•
•
•
Acquires and buffers incoming clock signals to create a master clock frequency
Distributes in-phase synchronized clock signals throughout the TC1762’s entire clock
tree
Divides a system master clock frequency into lower frequencies required by the
different modules for operation.
Dynamically reduces power consumption during operation of functional units
Statically reduces power consumption through programmable power-saving modes
Reduces electromagnetic interference (EMI) by switching off unused modules
The clock system must be operational before the TC1762 can function, so it contains
special logic to handle power-up and reset operations. Its services are fundamental to
the operation of the entire system, so it contains special fail-safe logic.
Features
•
•
•
•
PLL operation for multiplying clock source by different factors
Direct drive capability for direct clocking
Comfortable state machine for secure switching between basic PLL, direct or
prescaler operation
Sleep and Power-Down Mode support
The TC1762 Clock Generation Unit (CGU) as shown in Figure 3-14 allows a very
flexible clock generation. It basically consists of an main oscillator circuit and a PhaseLocked Loop (PLL). The PLL can converts a low-frequency external clock signal from the
oscillator circuit to a high-speed internal clock for maximum performance.
The system clock fSYS is generated from an oscillator clock fOSC in either one of the four
hardware/software selectable ways:
•
•
•
•
Direct Drive Mode (PLL Bypass):
In Direct Drive Mode, the TC1762 clock system is directly driven by an external clock
signal. input, i.e. fCPU = fOSC and fSYS = fOSC. This allows operation of the TC1762 with
a reasonably small fundamental mode crystal.
VCO Bypass Mode (Prescaler Mode):
In VCO Bypass Mode, fCPU and fSYS are derived from fOSC by the two divider stages,
P-Divider and K-Divider. The system clock fSYS is equal to fCPU.
PLL Mode:
In PLL Mode, the PLL is running. The VCO clock fVCO is derived from fOSC, divided by
the P factor, multiplied by the PLL (N-Divider). The clock signals fCPU and fSYS are
derived from fVCO by the K-Divider. The system clock fSYS is equal to fCPU.
PLL Base Mode:
In PLL Base Mode, the PLL is running at its VCO base frequency and fCPU and fSYS
Data Sheet
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V1.0, 2008-04
TC1762
Preliminary
Functional Description
are derived from fVCO only by the K-Divider. In this mode, the system clock fSYS is
equal to fCPU.
XTAL1
Clock Generation Unit (CGU)
Oscillator
Circuit
fOSC
1:1
Divider
1
XTAL2
Osc. Run
Detect.
P
Divider
≥1
Phase
Detect.
fVCO
VCO
0
M
U
X
K:1
Divider
M
U
X
fSYS
fCPU
N
Divider
PLL
Lock
Detector
BYPASS
OGC MOSC OSCR
PDIV OSC
[2:0] DISC
PLL_
LOCK
NDIV VCO_
VCO_
KDIV SYS PLL_
[6:0] SEL[1:0] BYPASS [3:0] FSL BYPASS
Register
OSC_CON
OSC_
BYPASS
Register PLL_CLC
System Control Unit (SCU)
MCA06083
Figure 3-14 Clock Generation Unit
Recommended Oscillator Circuits
The oscillator circuit, a Pierce oscillator, is designed to work with both, an external crystal
oscillator or an external stable clock source. It basically consists of an inverting amplifier
and a feedback element with XTAL1 as input, and XTAL2 as output.
When using a crystal, a proper external oscillator circuitry must be connected to both
pins, XTAL1 and XTAL2. The crystal frequency can be within the range of 4 MHz
to 25 MHz. Additionally, it is necessary to have two load capacitances CX1 and CX2, and
depending on the crystal type, a series resistor RX2, to limit the current. A test resistor RQ
may be temporarily inserted to measure the oscillation allowance (negative resistance)
of the oscillator circuitry. RQ values are typically specified by the crystal vendor. The CX1
and CX2 values shown in Figure 3-15 can be used as starting points for the negative
resistance evaluation and for non-productive systems. The exact values and related
operating range are dependent on the crystal frequency and have to be determined and
optimized together with the crystal vendor using the negative resistance method.
Data Sheet
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Preliminary
Functional Description
Oscillation measurement with the final target system is strongly recommended to verify
the input amplitude at XTAL1 and to determine the actual oscillation allowance (margin
negative resistance) for the oscillator-crystal system.
When using an external clock signal, the signal must be connected to XTAL1. XTAL2 is
left open (unconnected). The external clock frequency can be in the range of 0 - 40 MHz
if the PLL is bypassed, and 4 - 40 MHz if the PLL is used.
The oscillator can also be used in combination with a ceramic resonator. The final
circuitry must also be verified by the resonator vendor.
Figure 3-15 shows the recommended external oscillator circuitries for both operating
modes, external crystal mode and external input clock mode. A block capacitor is
recommended to be placed between VDDOSC/VDDOSC3 and VSSOSC.
V DDOSC
VDDOSC3
f OSC
XTAL1
4 - 25
MHz
RQ
VDDOSC
External Clock
Signal 4 - 40
MHz
TC1762
Oscillator
XTAL1
fOSC
TC1762
Oscillator
R X2
XTAL2
CX1
V DDOSC3
XTAL2
CX2
Fundamental
Mode Crystal
VSSOSC
V SSOSC
Crystal Frequency CX1, CX2 1)
R X2 1)
4 MHz
8 MHz
0
0
0
0
12 MHz
16 - 25 MHz
33
18
12
10
pF
pF
pF
pF
1) Note that these are evaluation start values!
MCS06084
Figure 3-15 Oscillator Circuitries
Note: For crystal operation, it is strongly recommended to measure the negative
resistance in the final target system (layout) to determine the optimum parameters
for the oscillator operation. Please refer to the minimum and maximum values of
the negative resistance specified by the crystal supplier.
Data Sheet
62
V1.0, 2008-04
TC1762
Preliminary
3.22
Functional Description
Power Supply
The TC1762 has several power supply lines for different voltage classes:
•
•
1.5 V: Core logic, oscillator and A/D converter supply
3.3 V: I/O ports, Flash memories, oscillator, and A/D converter supply with reference
voltages
Figure 3-16 shows the power supply concept of the TC1762 with the power supply pins
and its connections to the functional units.
VDDM
VAREF
VDDAF
V DDMF
(3.3V)
(3.3V)
(1.5V)
(3.3V)
VFAREF
(3.3V)
V SSM
V AGND
VSSAF
VSSMF
V FAGND
2
2
2
2
2
TC1762
FADC
ADC
V SSA
V DDA
(1.5 V) 1
1
PLL
Core
Flash
Memories
Ports
9
7
8
V SS
V DD
V DDP
V DDFL3
(1.5 V)
(3.3 V)
3.3 V
1
OSC
3
V DDOSC3 (3.3 V)
V DDOSC (1.5 V)
V SSOSC
TC1762 PwrSupply
Figure 3-16 Power Supply Concept of TC1762
Data Sheet
63
V1.0, 2008-04
TC1762
Preliminary
3.23
Functional Description
Identification Register Values
Table 3-4 shows the address map and reset values of the TC1762 Identification
Registers.
Table 3-4
TC1762 Identification Registers
Short Name
Address
Reset Value
Stepping
SCU_ ID
F000 0008H
002C C002H
-
MANID
F000 0070H
0000 1820H
-
CHIPID
F000 0074H
0000 8B02H
-
RTID
F000 0078H
0000 0001H
AA-Step
0000 0011H
AB-Step
0000 0007H
AC-Step
SBCU_ID
F000 0108H
0000 6A0AH
-
STM_ID
F000 0208H
0000 C006H
-
CBS_ JDPID
F000 0408H
0000 6307H
-
MSC0_ ID
F000 0808H
0028 C001H
-
ASC0_ ID
F000 0A08H
0000 4402H
-
ASC1_ ID
F000 0B08H
0000 4402H
-
GPTA0_ ID
F000 1808H
0029 C004H
-
DMA_ID
F000 3C08H
001A C012H
-
CAN_ID
F000 4008H
002B C012H
-
SSC0_ ID
F010 0108H
0000 4510H
-
FADC_ ID
F010 0308H
0027 C012H
-
ADC0_ID
F010 0408H
0030 C001H
-
MLI0_ ID
F010 C008H
0025 C006H
-
MCHK_ ID
F010 C208H
001B C001H
-
CPS_ID
F7E0 FF08H
0015 C006H
-
CPU_ID
F7E1 FE18H
000A C005H
-
PMU_ID
F800 0508H
002E C012H
-
FLASH_ID
F800 2008H
0041 C002H
-
DMI_ID
F87F FC08H
0008 C004H
-
PMI_ID
F87F FD08H
000B C004H
-
Data Sheet
64
V1.0, 2008-04
TC1762
Preliminary
Table 3-4
Functional Description
TC1762 Identification Registers
Short Name
Address
Reset Value
Stepping
LBCU_ID
F87F FE08H
000F C005H
-
LFI_ID
F87F FF08H
000C C005H
-
Data Sheet
65
V1.0, 2008-04
TC1762
Preliminary
4
Electrical Parameters
Electrical Parameters
Chapter 4 provides the characteristics of the electrical parameters which are
implementation-specific for the TC1762.
4.1
General Parameters
The general parameters are described here to aid the users in interpreting the
parameters mainly in Section 4.2 and Section 4.3. The absolute maximum ratings and
its operating conditions are provided for the appropriate setting in the TC1762.
4.1.1
Parameter Interpretation
The parameters listed in this section partly represent the characteristics of the TC1762
and partly its requirements on the system. To aid interpreting the parameters easily
when evaluating them for a design, they are marked with an two-letter abbreviation in
column “Symbol”:
•
•
CC
Such parameters indicate Controller Characteristics which are a distinctive feature of
the TC1762 and must be regarded for a system design.
SR
Such parameters indicate System Requirements which must provided by the
microcontroller system in which the TC1762 designed in.
Data Sheet
66
V1.0, 2008-04
TC1762
Preliminary
4.1.2
Electrical Parameters
Pad Driver and Pad Classes Summary
This section gives an overview on the different pad driver classes and its basic
characteristics. More details (mainly DC parameters) are defined in Section 4.2.1.
Table 4-1
Pad Driver and Pad Classes Overview
Leakage1) Termination
Class Power Type
Supply
Sub Class
Speed Load
Grade
A
A1
(e.g. GPIO)
6 MHz
100 pF 500 nA
A2
(e.g. serial
I/Os)
40
MHz
50 pF
6 µA
Series
termination
recommended
A3
66 or
(e.g. BRKIN, 80
MHz2)
BRKOUT)
50 pF
6 µA
Series
termination
recommended
(for f > 25 MHz)
A4
(e.g. Trace
Clock)
66 or
80
MHz2)
25 pF
6 µA
Series
termination
recommended
–
50
MHz
–
Parallel
termination3),
100Ω ± 10%
3.3V
LVTTL
I/O,
LVTTL
outputs
C
3.3V
LVDS
D
–
Analog inputs, reference voltage inputs
No
1) Values are for TJmax = 150 °C.
2) This value corresponds to the operating frequency of the device, which depending on the derivative, can be
66 or 80 MHz.
3) In applications where the LVDS pins are not used (disabled), these pins must be either left unconnected, or
properly terminated with the differential parallel termination of 100Ω ± 10%.
Data Sheet
67
V1.0, 2008-04
TC1762
Preliminary
4.1.3
Electrical Parameters
Absolute Maximum Ratings
Table 4-2 shows the absolute maximum ratings of the TC1762 parameters.
Table 4-2
Absolute Maximum Rating Parameters
Parameter
Symbol
Limit Values
Min.
TA
Storage temperature
TST
Junction temperature
TJ
Voltage at 1.5 V power supply VDD
pins with respect to VSS1)
Voltage at 3.3 V power supply VDDP
pins with respect to VSS2)
Voltage on any Class A input VIN
Ambient temperature
Unit Notes
Max.
SR -40
125
°C
Under bias
SR -65
150
°C
–
SR -40
150
°C
Under bias
SR –
2.25
V
–
SR –
3.75
V
–
SR -0.5
VDDP + 0.5
V
Whatever is
lower
V
or max. 3.7
Whatever is
lower
Whatever is
lower
pin and dedicated input pins
with respect to VSS
or
max. 3.7
Voltage on any Class D
analog input pin with respect
to VAGND
VAIN,
VAREFx
SR -0.5
VDDM + 0.5
Voltage on any Class D
analog input pin with respect
to VSSAF
VAINF,
VFAREF
SR -0.5
VDDMF + 0.5 V
or max. 3.7
CPU & LMB Bus
Frequency3)4)
fCPU
SR –
66 or 80
MHz –
FPI Bus Frequency3)4)
fSYS
SR –
66 or 80
MHz
5)
1) Applicable for VDD, VDDOSC, VDDPLL, and VDDAF.
2) Applicable for VDDP, VDDFL3, VDDM, and VDDMF.
3) The PLL jitter characteristics add to this value according to the application settings. See the PLL jitter
parameters.
4) This value depend on the derivative and the operating frequency it is designated for. For a device operating
at 66 MHz, the absolute maximum frequency is also 66 MHz. Similarly, for a device operating at 80 MHz, the
absolute maximum frequency is 80 MHz.
5) The ratio between fCPU and fSYS is fixed at 1:1.
Note: Stresses above those listed under “Absolute Maximum Ratings” may cause
permanent damage to the device. This is a stress rating only and functional
operation of the device at these or any other conditions above those indicated in
the operational sections of this specification is not implied. Exposure to absolute
Data Sheet
68
V1.0, 2008-04
TC1762
Preliminary
Electrical Parameters
maximum rating conditions for extended periods may affect device reliability.
During absolute maximum rating overload conditions (VIN > related VDD or
VIN < VSS) the voltage on the related VDD pins with respect to ground (VSS) must
not exceed the values defined by the absolute maximum ratings.
4.1.4
Operating Conditions
The following operating conditions must not be exceeded in order to ensure correct
operation of the TC1762. All parameters specified in the following table refer to these
operating conditions, unless otherwise noted.
Table 4-3
Operating Condition Parameters
Parameter
Digital supply voltage1)
Digital ground voltage
Ambient temperature under
bias
Analog supply voltages
Symbol
Limit
Values
Min.
Max.
Unit Notes
Conditions
VDD
VDDOSC
VDDP
VDDOSC3
SR
1.42
1.582) V
–
SR
3.13
3.473) V
For Class A
pins
(3.3V ± 5%)
VDDFL3
VSS
TA
SR
3.13
3.473) V
–
SR
0
V
–
SR
-40
+125
°C
–
–
–
–
See separate
specification
Page 4-75,
Page 4-82
SR
–4)
805)
MHz –
SR
-5
+5
mA
6)
SR
–
20
mA
See note7)
SR
–
100
mA
See note 7)
–
fCPU
Short circuit current
ISC
Absolute sum of short circuit Σ|ISC|
CPU clock
currents of a pin group (see
Table 4-4)
Absolute sum of short circuit
currents of the device
Data Sheet
Σ|ISC|
69
V1.0, 2008-04
TC1762
Preliminary
Table 4-3
Electrical Parameters
Operating Condition Parameters
Parameter
Symbol
Limit
Values
Min.
Max.
Unit Notes
Conditions
Inactive device pin current
(VDD = VDDP = 0)
IID
SR
-1
1
External load capacitance
CL
SR
–
See
pF
DC
chara
cterist
ics
mA
Voltage on all
power supply
pins VDDx = 0
Depending on
pin class
1) Digital supply voltages applied to the TC1762 must be static regulated voltages which allow a typical voltage
swing of ±5%.
2) Voltage overshoot up to 1.7 V is permissible at Power-Up and PORST low, provided the pulse duration is less
than 100 µs and the cumulated summary of the pulses does not exceed 1 h.
3) Voltage overshoot to 4 V is permissible at Power-Up and PORST low, provided the pulse duration is less than
100 µs and the cumulated summary of the pulses does not exceed 1 h.
4) The TC1762 uses a static design, so the minimum operation frequency is 0 MHz. Due to test time restriction
no lower frequency boundary is tested, however.
5) The PLL jitter characteristics add to this value according to the application settings. See the PLL jitter
parameters.
6) Applicable for digital outputs.
7) See additional document “TC1796 Pin Reliability in Overload“ for overload current definitions.
Data Sheet
70
V1.0, 2008-04
TC1762
Preliminary
Table 4-4
Electrical Parameters
Pin Groups for Overload/Short-Circuit Current Sum Parameter
Group
Pins
1
TRCLK, P5.[7:0], P0.[7:6], P0.[15:14]
2
P0.[13:12], P0.[5:4], P2.[13:8], SOP0A, SON0, FCLP0A, FCLN0
3
P0.[11:8], P0.[3:0], P3.[13:11]
4
P3[10:0], P3.[15:14]
5
HDRST, PORST, NMI, TESTMODE, BRKIN, BRKOUT, BYPASS, TCK,
TRST, TDO, TMS, TDI, P1.[7:4]
6
P1.[3:0], P1.[11:8], P4.[3:0]
7
P2.[7:0], P1.[14:12]
8
P5.[15:8]
Data Sheet
71
V1.0, 2008-04
TC1762
Preliminary
4.2
Electrical Parameters
DC Parameters
The electrical characteristics of the DC Parameters are detailed in this section.
4.2.1
Input/Output Pins
Table 4-5 provides the characteristics of the input/output pins of the TC1762.
Table 4-5
Input/Output DC-Characteristics (Operating Conditions apply)
Parameter
Symbol
Limit Values
Min.
Unit Test Conditions
Max.
General Parameters
Pull-up current1)
|IPUH|
CC 10
100
µA
VIN < VIHAmin;
class A1/A2/Input pads.
20
200
µA
VIN < VIHAmin;
class A3/A4 pads.
Pull-down
current1)
|IPDL|
CC 10
150
µA
VIN > VILAmax;
class A1/A2/Input pads.
20
200
µA
VIN > VILAmax;
class A3/A4 pads.
Pin capacitance1)
(Digital I/O)
CIO
CC –
10
pF
f = 1 MHz
TA = 25 °C
Input only Pads (VDDP = 3.13 to 3.47 V = 3.3V ±5%)
Input low voltage
class A1/A2 pins
VILA
SR
-0.3
0.34 ×
V
–
0.64 ×
VDDP
VDDP+
V
Whatever is lower
Input high voltage VIHA
class A1/A2 pins
SR
Ratio VIL/VIH
CC 0.53
–
–
–
VILA3
SR
–
0.8
V
–
Input high voltage VIHA3
class A3 pins
SR
2.0
–
V
–
–
V
2)5)
±3000
nA
((VDDP/2)-1) < VIN
< ((VDDP/2)+1)
otherwise3)
Input low voltage
class A3 pins
Input hysteresis
VDDP
HYSA CC 0.1 ×
0.3 or
max. 3.6
VDDP
Input leakage
current
IOZI
CC –
±6000
Data Sheet
72
V1.0, 2008-04
TC1762
Preliminary
Table 4-5
Electrical Parameters
Input/Output DC-Characteristics (cont’d)(Operating Conditions apply)
Parameter
Symbol
Limit Values
Min.
Unit Test Conditions
Max.
Class A Pads (VDDP = 3.13 to 3.47 V = 3.3V ±5%)
Output low
voltage4)
VOLA
Output high
voltage3)
VOHA
CC –
0.4
V
mode, (Not applicable to
Class A1 pins)
IOL = 1.8 mA for medium
driver mode, A2 pads
IOL = 1.4 mA for medium
driver mode, A1 pads
IOL = 370 µA for weak
driver mode
CC 2.4
–
V
IOH = -2 mA for strong
driver mode, (Not
applicable to Class A1
pins)
IOH = -1.8 mA for medium
driver mode, A1/A2 pads
IOH = -370 µA for weak
driver mode
VDDP -
–
V
0.4
Input low voltage
class A1/2 pins
IOL = 2 mA for strong driver
VILA
SR
IOH = -1.4 mA for strong
driver mode, (Not
applicable to Class A1
pins)
IOH = -1 mA for medium
driver mode, A1/A2 pads
IOH = -280 µA for weak
driver mode
-0.3
0.34 ×
V
–
0.64 ×
VDDP
VDDP +
V
Whatever is lower
Input high voltage VIHA
class A1/2 pins
SR
Ratio VIL/VIH
CC 0.53
–
–
–
HYSA CC 0.1 ×
–
V
2)5)
Input hysteresis
VDDP
0.3 or
3.6
VDDP
Data Sheet
73
V1.0, 2008-04
TC1762
Preliminary
Table 4-5
Electrical Parameters
Input/Output DC-Characteristics (cont’d)(Operating Conditions apply)
Parameter
Symbol
Limit Values
Min.
Input leakage
current Class
A2/3/4 pins
IOZA24 CC –
Input leakage
current
Class A1 pins
IOZA1
Unit Test Conditions
Max.
±3000
nA
((VDDP/2)-1) < VIN
<((VDDP/2)+1)
otherwise3)
nA
0 V <VIN < VDDP
mV
Parallel termination
100 Ω ± 1%
±6000
CC –
±500
Class C Pads (VDDP = 3.13 to 3.47 V = 3.3V ±5%)
Output low voltage VOL
Output high
voltage
VOH
Output differential VOD
voltage
Output offset
voltage
VOS
Output impedance R0
CC 815
CC
1545
mV
CC 150
600
mV
CC 1075
1325
mV
CC 40
140
–
Class D Pads
see ADC Characteristics
–
–
–
–
1) Not subject to production test, verified by design / characterization.
2) The pads that have spike filter function in the input path: PORST, HDRST, NMI do not have hysteresis.
3) Only one of these parameters is tested, the other is verified by design characterization
4) Max. resistance between pin and next power supply pin 25 Ω for strong driver mode
(verified by design characterization).
5) Function verified by design, value is not subject to production test - verified by design/characterization.
Hysteresis is implemented to avoid metastable states and switching due to internal ground bounce. It cannot
be guaranteed that it suppresses switching due to external system noise.
Data Sheet
74
V1.0, 2008-04
TC1762
Preliminary
4.2.2
Electrical Parameters
Analog to Digital Converter (ADC0)
Table 4-6 provides the characteristics of the ADC module in the TC1762.
Table 4-6
ADC Characteristics (Operating Conditions apply)
Parameter
Symbol
Limit Values
Min.
Typ.
Max.
Test Conditions /
Remarks
3.3
3.471) V
–
2)
Analog supply
voltage
VDDM
VDD
SR 3.13
SR 1.42
1.5
1.58
Analog ground
voltage
VSSM
SR -0.1
–
0.1
Analog reference VAREFx
voltage 17)
Unit
V
Power supply for
ADC digital part,
internal supply
V
–
SR VAGNDx+ VDDM VDDM+ V
1V
0.051)
–
3)4)
Analog reference VAGNDx
ground 17)
SR VSSMx 0.05V
Analog reference VAREFxvoltage range5)17) VAGNDx
SR VDDM/2
0
VAREF V
–
-1V
VDDM
+ 0.05
Analog input
voltage range
VAIN
SR VAGNDx
–
VAREFx V
–
VDDM
supply current
IDDM
SR
2.5
4
mA
rms
6)
Power-up
calibration
time
tPUC
CC –
–
3840
fADC
–
Internal ADC
clocks
fBC
fANA
tS
Sample time
CLK
CC 2
–
40
MHz fBC = fANA × 4
CC 0.5
–
10
MHz fANA = fBC / 4
CC 4 × (CHCONn.STC
+ 2) × tBC
8 × tBC
Data Sheet
75
–
–
µs
–
µs
V1.0, 2008-04
TC1762
Preliminary
Table 4-6
Electrical Parameters
ADC Characteristics (cont’d) (Operating Conditions apply)
Parameter
Symbol
Limit Values
Unit
Test Conditions /
Remarks
CC tS + 40 × tBC + 2 × tDIV
µs
For 8-bit
conversion
tS + 48 × tBC + 2 × tDIV
µs
For 10-bit
conversion
tS + 56 × tBC + 2 × tDIV
µs
For 12-bit
conversion
Min.
Conversion time
Total unadjusted
error 4)
DNL error11)5)
INL error11)5)
Gain error11)5)
Offset error11)5)
tC
TUE7)
Data Sheet
Max.
CC –
–
±1
LSB
For 8-bit conv.
–
–
±2
LSB
For 10-bit conv.
–
–
±4
LSB
For 12-bit conv.8)9)
–
–
±8
LSB
For 12-bit
conv.10)9)
±1.5
±3.0
LSB
For 12-bit conv.12)
TUEDNL
CC –
TUEINL
CC –
TUEGAIN
CC –
TUEOFF
CC –
Input leakage
IOZ114)
current at analog
inputs AN0, AN1
and AN31.
see Figure 4-313)
Typ.
9)
±1.5
±3.0
LSB
For 12-bit conv.12)
9)
±0.5
±3.5
LSB
For 12-bit conv.12)
9)
±1.0
±4.0
LSB
For 12-bit conv.12)
9)
300
nA
(0% VDDM) < VIN <
(2% VDDM)
–200
400
nA
(2% VDDM) < VIN <
(95% VDDM)
–200
1000
nA
(95% VDDM) < VIN
< (98% VDDM)
–200
3000
nA
(98% VDDM) < VIN
< (100% VDDM)
CC –1000
76
–
V1.0, 2008-04
TC1762
Preliminary
Table 4-6
Electrical Parameters
ADC Characteristics (cont’d) (Operating Conditions apply)
Parameter
Symbol
Limit Values
Min.
Input leakage
current at analog
inputs AN2 to
AN30, see
Figure 4-3
IOZ1
14)
Unit
Test Conditions /
Remarks
Typ.
Max.
–
200
nA
(0% VDDM) < VIN <
(2% VDDM)
–200
300
nA
(2% VDDM) < VIN <
(95% VDDM)
–200
1000
nA
(95% VDDM) < VIN
< (98% VDDM)
–200
3000
nA
(98% VDDM) < VIN
< (100% VDDM)
CC –1000
Input leakage
current at VAREF
IOZ2
CC –
–
±1
µA
0 V < VAREF <
VDDM, no
conversion
running
Input current at
IAREF
CC –
35
75
µA
rms
0 V < VAREF <
VAREF
17)
VDDM15)
Total capacitance CAREFTOT
of the voltage
reference
inputs16)17)
CC –
–
25
pF
9)
Switched
CAREFSW
capacitance at
the positive
reference voltage
input 17)
CC –
15
20
pF
9)18)
Resistance of the RAREF
reference voltage
input path16)
CC –
1
1.5
kΩ
500 Ohm
increased for
AN[1:0] used as
reference input 9)
Total capacitance CAINTOT
of the analog
inputs16)
CC –
–
25
pF
6)9)
CAINSW
CC –
–
7
pF
9)19)
Switched
capacitance at
the analog
voltage inputs
Data Sheet
77
V1.0, 2008-04
TC1762
Preliminary
Table 4-6
Electrical Parameters
ADC Characteristics (cont’d) (Operating Conditions apply)
Parameter
Symbol
Limit Values
Min.
Unit
Test Conditions /
Remarks
Typ.
Max.
CC –
1
1.5
kΩ
9)
ON resistance for RAIN7T
the ADC test
(pull-down for
AIN7)
CC 200
300
1000
Ω
Test feature
available only for
AIN7
Current through
IAIN7T
resistance for the
ADC test (pulldown for AIN7)
CC –
ON resistance of
the transmission
gates in the
analog voltage
path
RAIN
9)
15
rms
30
peak
mA
Test feature
available only for
AIN7
9)
1) Voltage overshoot to 4 V are permissible, provided the pulse duration is less than 100 µs and the cumulated
summary of the pulses does not exceed 1 h.
2) Voltage overshoot to 1.7 V are permissible, provided the pulse duration is less than 100 µs and the cumulated
summary of the pulses does not exceed 1 h.
3) A running conversion may become inexact in case of violating the normal operating conditions (voltage
overshoot).
4) If the reference voltage VAREF increases or the VDDM decreases, so that
VDDM + 0.07 V), then the accuracy of the ADC decreases by 4LSB12.
VAREF = ( VDDM + 0.05 V
to
5) If a reduced reference voltage in a range of VDDM/2 to VDDM is used, then the ADC converter errors increase.
If the reference voltage is reduced with the factor k (k<1), then TUE, DNL, INL Gain and Offset errors increase
with the factor 1/k.
If a reduced reference voltage in a range of 1 V to VDDM/2 is used, then there are additional decrease in the
ADC speed and accuracy.
6) Current peaks of up to 6 mA with a duration of max. 2 ns may occur
7) TUE is tested at VAREF = 3.3 V, VAGND = 0 V and VDDM = 3.3 V
8) ADC module capability.
9) Not subject to production test, verified by design / characterization.
10) Value under typical application conditions due to integration (switching noise, etc.).
11) The sum of DNL/INL/Gain/Offset errors does not exceed the related TUE total unadjusted error.
12) For 10-bit conversions the DNL/INL/Gain/Offset error values must be multiplied with factor 0.25.
For 8-bit conversions the DNL/INL/Gain/Offset error values must be multiplied with 0.0625.
13) The leakage current definition is a continuous function, as shown in Figure 4-3. The numerical values defined
determine the characteristic points of the given continuous linear approximation - they do not define step
function.
14) Only one of these parameters is tested, the other is verified by design characterization.
Data Sheet
78
V1.0, 2008-04
TC1762
Preliminary
Electrical Parameters
15) IAREF_MAX is valid for the minimum specified conversion time. The current flowing during an ADC conversion
with a duration of up to tC = 25µs can be calculated with the formula IAREF_MAX = QCONV/tC. Every conversion
needs a total charge of QCONV = 150pC from VAREF.
All ADC conversions with a duration longer than tC = 25µs consume an IAREF_MAX = 6µA.
16) For the definition of the parameters see also Figure 4-2.
17) Applies to AIN0 and AIN1, when used as auxiliary reference inputs.
18) This represents an equivalent switched capacitance. This capacitance is not switched to the reference voltage
at once. Instead of this smaller capacitances are successively switched to the reference voltage.
19) The sampling capacity of the conversion C-Network is pre-charged to VAREF/2 before the sampling moment.
Because of the parasitic elements the voltage measured at AINx is lower then VAREF/2.
A/D Converter Module
fCLC
Fractional
Divider
fDIV
Programmable
Clock Divider
(1:1) to (1:256)
CON.CTC
Arbiter
(1:20)
fTIMER
fBC
1:4
fANA
Programmable
Counter
Sample
Time tS
CHCONn.STC
Control Unit
(Timer)
Control/Status Logic
Interrupt Logic
External Trigger Logic
External Multiplexer Logic
Request Generation Logic
MCA04657_mod
Figure 4-1
Data Sheet
ADC0 Clock Circuit
79
V1.0, 2008-04
TC1762
Preliminary
Electrical Parameters
REXT
VAIN =
Analog Input Circuitry
RAIN, On
ANx
CEXT
CAINSW
CAINTOT - CAINSW
VAGNDx
RAIN7T
Reference Voltage Input Circuitry
RAREF, On
VAREFx
VAREF
CAREFTOT - CAREFSW
CAREFSW
VAGNDx
Analog_InpRefDiag
Figure 4-2
Data Sheet
ADC0 Input Circuits
80
V1.0, 2008-04
TC1762
Preliminary
Electrical Parameters
Ioz1
3uA
AN0, AN1 and AN31
1uA
400nA
300nA
-200nA
VIN[V DDM%]
95% 98% 100%
2%
-1uA
Ioz1
3uA
AN2 to AN30
1uA
300nA
200nA
-200nA
V IN[V DDM%]
2%
95% 98%100%
-1uA
Figure 4-3
Data Sheet
ADC0 Analog Inputs Leakage
81
V1.0, 2008-04
TC1762
Preliminary
4.2.3
Electrical Parameters
Fast Analog to Digital Converter (FADC)
Table 4-7 provides the characteristics of the FADC module in the TC1762.
Table 4-7
FADC Characteristics (Operating Conditions apply)
Parameter
Symbol
Limit Values
Min.
DNL error
INL error
Gradient error1)12)
Offset error12)
Reference error of
internal VFAREF/2
EDNL
EINL
EGRAD
EOFF3)
EREF
Input leakage current IOZ16)
at analog inputs
AN32 to AN35.
5)
see Figure 4-5
Analog supply
voltages
Analog ground
voltage
VDDMF
VDDAF
VSSAF
Unit
Remarks
Conditions
Max.
CC –
±1
LSB
12)
CC –
±4
LSB
12)
CC –
±3
%
2)
–
±5
%
Without calibration
gain 1, 2, 4
–
±6
%
Without calibration
gain 8
CC –
±204)
mV
2)
–
4)
±60
mV
Without calibration
CC –
±60
mV
–
CC –1000
300
nA
(0% VDDM) < VIN <
(2% VDDM)
–200
400
nA
(2% VDDM) < VIN <
(95% VDDM)
–200
1000
nA
(95% VDDM) < VIN <
(98% VDDM)
–200
3000
nA
(98% VDDM) < VIN <
(100% VDDM)
SR 3.13
3.477)
V
–
SR 1.42
1.588)
V
–
SR -0.1
0.1
V
–
With calibration,
gain 1, 2
With calibration
Analog reference
voltage
VFAREF SR 3.13
3.477)9)
V
Nominal 3.3 V
Analog reference
ground
VFAGND SR VSSAF -
VSSAF
V
–
V
–
Analog input voltage VAINF
range
Data Sheet
0.05V
+0.05V
SR VFAGND
82
VDDMF
V1.0, 2008-04
TC1762
Preliminary
Table 4-7
Electrical Parameters
FADC Characteristics (cont’d)(Operating Conditions apply)
Parameter
Symbol
Limit Values
Min.
IDDMF
IDDAF
Input current at each IFAREF
VFAREF
Input leakage current IFOZ2
at VFAREF11)
Input leakage current IFOZ3
at VFAGND
Conversion time
tC
Analog supply
currents
Unit
Remarks
Conditions
Max.
SR –
9
mA
–
SR –
17
mA
10)
CC –
150
µA
rms
Independent of
conversion
CC –
±500
nA
0 V < VIN < VDDMF
CC
±8
µA
CC –
21
CLK of For 10-bit conv.
fADC
fADC
RFAIN
CC –
80
MHz
–
CC 100
200
kΩ
12)
Channel Amplifier
Cutoff Frequency
fCOFF
CC 2
MHz
–
Settling Time of a
Channel Amplifier
after changing ENN
or ENP
tSET
CC
µsec
–
Converter Clock
Input resistance of
the analog voltage
path (Rn, Rp)
5
1) Calibration of the gain is possible for the gain of 1 and 2, and not possible for the gain of 4 and 8.
2) Calibration should be performed at each power-up. In case of continuous operation, calibration should be
performed minimum once per week.
3) The offset error voltage drifts over the whole temperature range typically ±2 LSB.
4) Applies when the gain of the channel equals one. For the other gain settings, the offset error increases; it must
be multiplied with the applied gain.
5) The leakage current definition is a continuous function, as shown in Figure 4-5. The numerical values defined
determine the characteristic points of the given continuous linear approximation - they do not define step
function.
6) Only one of these parameters is tested, the other is verified by design characterization.
7) Voltage overshoot to 4 V are permissible, provided the pulse duration is less than 100 µs and the cumulated
summary of the pulses does not exceed 1 h.
8) Voltage overshoot to 1.7 V are permissible, provided the pulse duration is less than 100 µs and the cumulated
sum of the pulses does not exceed 1 h.
9) A running conversion may become inexact in case of violating the normal operating conditions (voltage
overshoots).
10) Current peaks of up to 40 mA with a duration of max. 2 ns may occur
Data Sheet
83
V1.0, 2008-04
TC1762
Preliminary
Electrical Parameters
11) This value applies in power-down mode.
12) Not subject to production test, verified by design / characterization.
The calibration procedure should run after each power-up, when all power supply
voltages and the reference voltage have stabilized. The offset calibration must run first,
followed by the gain calibration.
FADC Analog Input Stage
RN
FAINxN
=
VFAGND
-
VFAREF /2
+
+
RP
FAINxP
-
FADC Reference Voltage
Input Circuitry
VFAREF
IFAREF
VFAREF
VFAGND
FADC_InpRefDiag
Figure 4-4
Data Sheet
FADC Input Circuits
84
V1.0, 2008-04
TC1762
Preliminary
Electrical Parameters
Ioz1
3uA
AN32 to AN35
1uA
400nA
300nA
-200nA
V IN[VDDM%]
95% 98%100%
2%
-1uA
Figure 4-5
Data Sheet
Analog Inputs AN32-AN35 Leakage
85
V1.0, 2008-04
TC1762
Preliminary
4.2.4
Electrical Parameters
Oscillator Pins
Table 4-8 provides the characteristics of the oscillator pins in the TC1762.
Table 4-8
Oscillator Pins Characteristics (Operating Conditions apply)
Parameter
Symbol
Limit values
Min.
Frequency Range
Input low voltage at
XTAL11)
Input high voltage at
XTAL11)
fOSC
VILX
VIHX
Input current at XTAL1 IIX1
Unit Test Conditions
Max.
CC 4
25
MHz –
SR -0.2
0.3 ×
V
–
SR 0.7 ×
VDDOSC3
VDDOSC3
V
–
µA
0 V < VIN < VDDOSC3
VDDOSC3
+ 0.2
±25
CC –
1) If the XTAL1 pin is driven by a crystal, reaching a minimum amplitude (peak-to-peak) of 0.3 × VDDOSC3 is
necessary.
Note: It is strongly recommended to measure the oscillation allowance (negative
resistance) in the final target system (layout) to determine the optimal parameters
for the oscillator operation. Please refer to the limits specified by the crystal
supplier.
Data Sheet
86
V1.0, 2008-04
TC1762
Preliminary
4.2.5
Electrical Parameters
Temperature Sensor
Table 4-9 provides the characteristics of the temperature sensor in the TC1762.
Table 4-9
Parameter
Temperature Sensor Characteristics (Operating Conditions apply)
Symbol
Limit Values
Min.
Temperature
TSR
Sensor Range
tTSST SR
Temperature
of the die at
the sensor
location
TTS
Sensor
Inaccuracy
TTSA CC
A/D Converter fANA
clock for DTS
signal
Data Sheet
Max.
SR -40
Start-up time
after resets
inactive
Unit Remarks
150
°C
10
µs
CC TTS = (ADC_Code - 487) × 0.396 - 40
–
°C
10-bit ADC
result
TTS = (ADC_Code - 1948) × 0.099 - 40 °C
12Bit ADC
result
SR –
87
±10
°C
10
MHz Conversion
with ADC0
V1.0, 2008-04
TC1762
Preliminary
4.2.6
Electrical Parameters
Power Supply Current
Table 4-10 provides the characteristics of the power supply current in the TC1762.
Table 4-10
Power Supply Current (Operating Conditions apply)
Parameter
Symbol
Limit Values
Min. Typ. Max.
PORST low current at IDD_PORST
CC
–
–
VDD
961)
Unit Test
Conditions /
Remarks
mA
The PLL
running at the
base frequency
mA
The PLL
running at the
base frequency
mA
fCPU = 80MHz
fCPU/fSYS = 1:1
mA
fCPU = 66MHz
fCPU/fSYS = 1:1
1382)
PORST low current at IDDP_PORST CC
–
–
VDDP
121)
13
2)
2901)
Active mode core
supply current3)4)
IDD
Active mode core
supply current3)4)
IDD
Active mode analog
supply current
IDDAx;
IDDMx
IDDOSC
CC
–
–
–
mA
See
ADC0/FADC
CC
–
–
5
mA
–
IDDOSC3
CC
–
–
3.65)
mA
–
CC
–
–
45
mA
–
–
25
mA
LVDS pads
active
–
At worst case,
TA = 125 °C
Oscillator and PLL
core power supply
Oscillator and PLL
pads power supply
CC
–
–
3302)
CC
–
–
2501)
3002)
FLASH power supply IDDFL3
current
LVDS port supply
(via VDDP)6)
ILVDS
CC
–
Maximum Allowed
Power Dissipation7)
PDmax
SR
PD × RTJA < 25°C
1) Maximum value measured at TA = 125 °C.
2) Maximum value measured at TJ = 150 °C.
3) Infineon Power Loop: CPU and PCP running, all peripherals active. The power consumption of each custom
application will most probably be lower than this value, but must be evaluated separately.
4) The IDD decreases typically to 240mA if the fCPU is decreased to 40 MHz, at constant TJ = 150 °C, for the
Infineon Max. Power Loop.
5) Estimated value; double-bonded at package level with VDDP.
6) In case the LVDS pads are disabled, the power consumption per pair is negligible (less than 1µA).
7) For the calculation of the junction to ambient thermal resistance RTJA, see Chapter 5.1.
Data Sheet
88
V1.0, 2008-04
TC1762
Preliminary
4.3
Electrical Parameters
AC Parameters
All AC parameters are defined with the temperature compensation disabled, which
means that pads are constantly kept at the maximum strength.
4.3.1
Testing Waveforms
The testing waveforms for rise/fall time, output delay and output high impedance are
shown in Figure 4-6, Figure 4-7 and Figure 4-8.
VDDP
90%
90%
10%
10%
VSS
tF
tR
rise_fall
Figure 4-6
Rise/Fall Time Parameters
VDDP
VDDE / 2
Test Points
VDDE / 2
VSS
Mct04881_LL.vsd
Figure 4-7
Testing Waveform, Output Delay
VLoad + 0.1 V
VLoad - 0.1 V
Timing
Reference
Points
VOH - 0.1 V
VOL - 0.1 V
MCT04880_LL
Figure 4-8
Data Sheet
Testing Waveform, Output High Impedance
89
V1.0, 2008-04
TC1762
Preliminary
4.3.2
Electrical Parameters
Output Rise/Fall Times
Table 4-11 provides the characteristics of the output rise/fall times in the TC1762.
Table 4-11
Output Rise/Fall Times (Operating Conditions apply)
Parameter
Symbol
Limit Values Unit Test Conditions
Min.
Max.
Class A1 Pads
Rise/fall times1)
Class A1 pads
tRA1, tFA1
50
140
18000
150
550
65000
ns
Regular (medium) driver, 50 pF
Regular (medium) driver, 150 pF
Regular (medium) driver, 20 nF
Weak driver, 20 pF
Weak driver, 150 pF
Weak driver, 20 000 pF
tFA2, tFA2
3.3
6
5.5
16
50
140
18000
150
550
65000
ns
Strong driver, sharp edge, 50 pF
Strong driver, sharp edge, 100pF
Strong driver, med. edge, 50 pF
Strong driver, soft edge, 50 pF
Medium driver, 50 pF
Medium driver, 150 pF
Medium driver, 20 000 pF
Weak driver, 20 pF
Weak driver, 150 pF
Weak driver, 20 000 pF
tFA3, tFA3
2.5
ns
50 pF
tFA4, tFA4
2.0
ns
25 pF
trC, tfC
2
ns
Class A2 Pads
Rise/fall times 1)
Class A2 pads
Class A3 Pads
Rise/fall times 1)
Class A3 pads
Class A4 Pads
Rise/fall times 1)
Class A4 pads
Class C Pads
Rise/fall times
Class C pads
1) Not all parameters are subject to production test, but verified by design/characterization and test correlation.
Data Sheet
90
V1.0, 2008-04
TC1762
Preliminary
4.3.3
Electrical Parameters
Power Sequencing
There is a restriction for the power sequencing of the 3.3 V domain as shown in
Figure 4-9. It must always be higher than 1.5 V domain - 0.5 V. The gray area shows the
valid range for V3.3V relative to an exemplary V1.5V ramp. VDDP, VDDOSC3, VDDM, VDDMF,
VDDFL3 belong to the 3.3 V domain. The VDDM and VDDMF subdomains are connected with
antiparallel ESD protection diodes. There are no other such connections between the
subdomains. VDD , VDDOSC and VDDAF belong to the 1.5 V domain.
Power Supply Voltage
3.3V
V3 .3
V1 .5
re a
id a
re a
fo r
id a
V
3. 3
V al
.3
for V 3
V al
1.5V
V 3 .3 > V1 .5 - 0.5V
Time
VD D P
(3.3V)
PORST
Time
PowerSeq
Figure 4-9
VDDP / VDD Power Up Sequence
All ground pins VSS must be externally connected to one single star point in the system.
The difference voltage between the ground pins must not exceed 200 mV.
The PORST signal must be activated at latest before any power supply voltage falls
below the levels shown on the figure below. In this case, only the memory row of a Flash
memory that was the target of the write at the moment of the power loss will contain
unreliable content. Additionally, the PORST signal should be activated as soon as
possible. The sooner the PORST signal is activated, the less time the system operates
outside of the normal operating power supply range.
Data Sheet
91
V1.0, 2008-04
TC1762
Preliminary
Electrical Parameters
Power Supply Voltage
VDDP
3.3V
VDDP
3.13V
VDDPmin
-5%
2.9V
VPORST3.3
-12%
t
PORST
t
V DD
1.5V
VDD
1.42V
1.32V
V DDmin
V PORST1.5min
-5%
-12%
t
PORST
t
PowerDown3.3_1.5_reset_only_LL.vsd
Figure 4-10 Power Down / Power Loss Sequence
Data Sheet
92
V1.0, 2008-04
TC1762
Preliminary
4.3.4
Electrical Parameters
Power, Pad and Reset Timing
Table 4-12 provides the characteristics of the power, pad and reset timing in the
TC1762.
Table 4-12
Power, Pad and Reset Timing Parameters
Parameter
Symbol
Limit Values
Min.
Unit
Max.
Min. VDDP voltage to ensure defined
pad states1)
VDDPPA
CC 0.6
–
V
Oscillator start-up time2)
tOSCS
tPOA
CC –
10
ms
SR 10
–
ms
HDRST pulse width
tHD
CC 1024 clock
cycles3)
–
fSYS
PORST rise time
tPOR
tPOS
tPOH
tHDS
tHDH
SR –
50
ms
SR 0
–
ns
SR 100
–
ns
SR 0
–
ns
SR 100 +
(2 × 1/fSYS)
–
ns
Ports inactive after PORST reset
active6)7)
tPIP
CC –
150
ns
Ports inactive after HDRST reset
active8)
tPI
CC –
150 +
5 × 1/fSYS
ns
Minimum VDDP PORST activation
threshold.9)
VPORST3.3 SR –
2.9
V
Minimum VDD PORST activation
threshold. 9)
VPORST1.5 SR –
1.32
V
Power-on Reset Boot Time10)
tBP
tB
CC 2.15
3.50
ms
CC 500
800
µs
tB
CC 560
860
µs
Minimum PORST active time after
power supplies are stable at operating
levels
Setup time to PORST rising edge4)
Hold time from PORST rising edge4)
Setup time to HDRST rising edge5)
Hold time from HDRST rising edge5)
Hardware/Software Reset Boot Time
at fCPU=80MHz11)
Hardware/Software Reset Boot Time
at fCPU=66MHz11)
1) This parameter is valid under assumption that PORST signal is constantly at low-level during the powerup/power-down of the VDDP.
Data Sheet
93
V1.0, 2008-04
TC1762
Preliminary
Electrical Parameters
2) This parameter is verified by device characterization. The external oscillator circuitry must be optimized by the
customer and checked for negative resistance as recommended and specified by crystal suppliers.
3) Any HDRST activation is internally prolonged to 1024 FPI bus clock (fSYS) cycles.
4) Applicable for input pins TESTMODE, TRST, BRKIN, and TXD1A with noise suppression filter of PORST
switched-on (BYPASS = 0).
5) The setup/hold values are applicable for Port 0 and Port 4 input pins with noise suppression filter of HDRST
switched-on (BYPASS = 0), independently whether HDRST is used as input or output.
6) Not subject to production test, verified by design / characterization.
7) This parameter includes the delay of the analog spike filter in the PORST pad.
8) Not subject to production test, verified by design / characterization.
9) In case of power loss during internal flash write, prevents Flash write to random address.
10) Booting from Flash, the duration of the boot-time is defined between the rising edge of the PORST and the
moment when the first user instruction has entered the CPU and its processing starts.
11) Booting from Flash, the duration of the boot time is defined between the following events:
1. Hardware reset: the falling edge of a short HDRST pulse and the moment when the first user instruction has
entered the CPU and its processing starts, if the HDRST pulse is shorter than 1024 × TSYS.
If the HDRST pulse is longer than 1024 × TSYS, only the time beyond the 1024 × TSYS should be added to the
boot time (HDRST falling edge to first user instruction).
2. Software reset: the moment of starting the software reset and the moment when the first user instruction
has entered the CPU and its processing starts
VDDPPA
VDDPPA
VDDP
VDD
VDDPR
toscs
OSC
tPOA
tPOA
PORST
thd
thd
HDRST
Padstate
undefined
2)
1)
2)
Pads
t pi
1) as programmed
1)
2)
Padstate
undefined
2) Tri-state, pull device active
reset_beh
Figure 4-11 Power, Pad and Reset Timing
Data Sheet
94
V1.0, 2008-04
TC1762
Preliminary
4.3.5
Electrical Parameters
Phase Locked Loop (PLL)
Section 4.3.5 provides the characteristics of the PLL parameters and its operation in the
TC1762.
Note: All PLL characteristics defined on this and the next page are verified by design
characterization.
Table 4-13
PLL Parameters (Operating Conditions apply)
Parameter
Symbol
Limit Values
Min.
Accumulated jitter
VCO frequency range
PLL base frequency1)
DP
fVCO
fPLLBASE
tL
PLL lock-in time
Unit
Max.
See Figure 4-12
–
400
500
MHz
500
600
MHz
600
700
MHz
140
320
MHz
150
400
MHz
200
480
MHz
–
200
µs
1) The CPU base frequency which is selected after reset is calculated by dividing the limit values by 16 (this is
the K factor after reset).
Phase Locked Loop Operation
When PLL operation is enabled and configured, the PLL clock fVCO (and with it the CPU
clock fCPU) is constantly adjusted to the selected frequency. The relation between fVCO
and fSYS is defined by: fVCO = K × fCPU. The PLL causes a jitter of fCPU and affects the
clock outputs TRCLK and SYSCLK (P4.3) which are derived from the PLL clock fVCO.
There are two formulas that define the (absolute) approximate maximum value of jitter
DP in ns dependent on the K-factor, the CPU clock frequency fCPU in MHz, and the
number P of consecutive fCPU clock periods.
P × K < 900
5×P
Dp [ ns ] = ±  ----------------------------+ 0, 9
 fcpu [ MHz ]

(4.1)
P × K ≥ 900
4500
Dp [ ns ] = ±  --------------------------------------- + 0, 9
 fcpu [ MHz ] × K

(4.2)
K : K-Divider Value
P : Number of fCPU periods
DP : Jitter in ns
fCPU : CPU frequency in MHz
Data Sheet
95
V1.0, 2008-04
TC1762
Preliminary
Electrical Parameters
Note: The frequency of system clock fSYS can be selected to be either fCPU or fCPU/2.
With rising number P of clock cycles the maximum jitter increases linearly up to a value
of P that is defined by the K-factor of the PLL. Beyond this value of P the maximum
accumulated jitter remains at a constant value. Further, a lower CPU clock frequency
fCPU results in a higher absolute maximum jitter value.
Figure 4-12 illustrates the jitter curve for for several K/ fCPU combinations.
Jitter [ns]
TC1762 PLL Jitter (Preliminary)
±13.0
±12.0
fCP U = 80 MHz (K = 5)
fCP U = 40 MHz (K = 10)
±11.0
±10.0
fCP U = 66 MHz ( K = 7)
±9.0
fCP U = 40 MHz
(K = 17)
fCP U = 80 MHz (K = 8)
±8.0
±7.0
fCP U = 66 MHz (K = 10)
±6.0
±5.0
±4.0
±3.0
±2.0
±1.0
±0.0
1
25
50
75
100
125
150
175
oo
P [Periods]
Figure 4-12 Approximated Maximum Accumulated PLL Jitter for Typical CPU
Clock Frequencies fCPU (overview)
Data Sheet
96
V1.0, 2008-04
TC1762
Preliminary
Electrical Parameters
Jitter [ns]
TC1762 PLL Jitter (preliminary )
±1.40
fCP U = 40 MHz
±1.30
f CP U = 66 MHz
±1.20
±1.10
fCP U = 80 MHz
±1.00
±0.90
1
2
3
4
5
P [Periods]
Figure 4-13 Approximated Maximum Accumulated PLL Jitter for Typical CPU
Clock Frequencies fCPU (detail)
Note: The maximum peak-to-peak noise on the main oscillator and PLL power supply
(measured between VDDOSC and VSSOSC) is limited to a peak-to-peak voltage of
VPP = 10 mV. This condition can be achieved by appropriate blocking to the supply
pins and using PCB supply and ground planes.
Data Sheet
97
V1.0, 2008-04
TC1762
Preliminary
4.3.6
Electrical Parameters
Debug Trace Timing
VSS = 0 V; VDDP = 3.13 to 3.47 V (Class A); TA = -40 °C to +125 °C;
CL (TRCLK) = 25 pF; CL (TR[15:0]) = 50 pF
Table 4-14
Debug Trace Timing Parameter1)
Parameter
Symbol
Limit Values
Min.
t9
TR[15:0] new state from TRCLK
Unit
Max.
CC -1
4
ns
1) Not subject to production test, verified by design/characterization.
TRCLK
t9
TR[15:0]
Old State
New State
Trace_Tmg
Figure 4-14 Debug Trace Timing
Data Sheet
98
V1.0, 2008-04
TC1762
Preliminary
4.3.7
Electrical Parameters
Timing for JTAG Signals
(Operating Conditions apply, CL = 50 pF)
Table 4-15
TCK Clock Timing Parameter
Parameter
Symbol
Limit Values
Min.
TCK clock period1)
tTCK
t1
t2
t3
t4
TCK high time
TCK low time
TCK clock rise time
TCK clock fall time
Unit
Max.
SR 25
–
ns
SR 10
–
ns
SR 10
–
ns
SR –
4
ns
SR –
4
ns
1) fTCK should be lower or equal to fSYS
0.9 VDD
0.5 VDD
0.1 VDD
TCK
t1
t2
t4
t3
tTCK
Figure 4-15 TCK Clock Timing
Data Sheet
99
V1.0, 2008-04
TC1762
Preliminary
Table 4-16
Electrical Parameters
JTAG Timing Parameter1)
Parameter
Symbol
Limit
Values
Unit
Test
Conditions /
Remarks
Min. Max.
TMS setup to TCK
t1
SR 6.0
–
ns
–
TMS hold to TCK
t2
SR 6.0
–
ns
–
TDI setup to TCK
t1
SR 6.0
–
ns
–
TDI hold to TCK
t2
SR 6.0
–
ns
–
TDO valid output from TCK2)
t3
CC –
14.5
ns
CL = 50 pF3)4)
3.0
–
CL = 20 pF
TDO high impedance to valid output
from TCK2)
t4
CC –
15.5
ns
CL = 50 pF3)4)
TDO valid output to high impedance
from TCK2)
t5
CC –
14.5
ns
CL = 50 pF4)
1) Not subject to production test, verified by design / characterization.
2) The falling edge on TCK is used to capture the TDO timing.
3) By reducing the load from 50 pF to 20 pF, a reduction of approximately 1.0 ns in timing is expected.
4) By reducing the power supply range from +/-5 % to +5/-2 %, a reduction of approximately 0.5 ns in timing is
expected.
Data Sheet
100
V1.0, 2008-04
TC1762
Preliminary
Electrical Parameters
TCK
t1
t2
t1
t2
TMS
TDI
t4
t3
t5
TDO
Figure 4-16 JTAG Timing
Note: The JTAG module is fully compliant with IEEE1149.1-2000 with JTAG clock at
20 MHz. The JTAG clock at 40 MHz is possible with the modified timing diagram
shown in Figure 4-16.
Data Sheet
101
V1.0, 2008-04
TC1762
Preliminary
4.3.8
Electrical Parameters
Peripheral Timings
Section 4.3.8 provides the characteristics of the peripheral timings in the TC1762.
Note: Peripheral timing parameters are not subject to production test. They are verified
by design/characterization.
4.3.8.1
Micro Link Interface (MLI) Timing
Table 4-17 provides the characteristics of the MLI timing in the TC1762.
Table 4-17
MLI Timing (Operating Conditions apply, CL = 50 pF)
Parameter
Symbol
TCLK clock period1)2)
Limit Values
Min.
Max.
Unit
CC
23)
–
1/fSYS
SR
1
–
1/fSYS
MLI outputs delay from TCLK
t30
t31
t35
CC
0
8
ns
MLI inputs setup to RCLK
t36
SR
4
–
ns
MLI inputs hold to RCLK
t37
SR
4
–
ns
RREADY output delay from RCLK
t38
CC
0
8
ns
RCLK clock period
1) TCLK signal rise/fall times are the same as the A2 Pads rise/fall times.
2) TCLK high and low times can be minimum 1 × TMLI
3) TMLImin = TSYS = 1/fSYS. When fSYS = 80MHz, t30 = 25ns
Data Sheet
102
V1.0, 2008-04
TC1762
Preliminary
Electrical Parameters
t30
0.9 VDDP
0.1 VDDP
TCLKx
t35
t35
TDATAx
TVALIDx
TREADYx
t30
RCLKx
t36
t37
RDATAx
RVALIDx
t38
t38
RREADYx
MLI_Tmg_1.vsd
Figure 4-17 MLI Interface Timing
Note: The generation of RREADYx is in the input clock domain of the receiver. The
reception of TREADYx is asynchronous to TCLKx.
Data Sheet
103
V1.0, 2008-04
TC1762
Preliminary
4.3.8.2
Electrical Parameters
Micro Second Channel (MSC) Interface Timing
Table 4-18 provides the characteristics of the MSC timing in the TC1762.
Table 4-18
MSC Interface Timing (Operating Conditions apply, CL = 50 pF)
Parameter
Symbol
Limit Values
Min.
FCLP clock period1)2)
SOP/ENx outputs delay from FCLP
SDI bit time
SDI rise time
SDI fall time
Unit
Max.
t40
t45
CC 2 × TMSC3)
–
ns
CC -10
10
ns
t46
t48
t49
SR 8 × TMSC
–
ns
SR
100
ns
SR
100
ns
1) FCLP signal rise/fall times are the same as the A2 Pads rise/fall times.
2) FCLP signal high and low can be minimum 1 × TMSC.
3) TMSCmin = TSYS = 1/fSYS. When fSYS = 80MHz, t40 = 25ns
t40
0.9 VDDP
0.1 VDDP
FCLP
t45
t 45
SOP
EN
t48
t 49
0.9 VDDP
0.1 VDDP
SDI
t46
t46
MSC_Tmg_1.vsd
Figure 4-18 MSC Interface Timing
Note: The data at SOP should be sampled with the falling edge of FCLP in the target
device.
Data Sheet
104
V1.0, 2008-04
TC1762
Preliminary
4.3.8.3
Electrical Parameters
Synchronous Serial Channel (SSC) Master Mode Timing
Table 4-19 provides the characteristics of the SSC timing in the TC1762.
Table 4-19
SSC Master Mode Timing (Operating Conditions apply, CL = 50 pF)
Parameter
Symbol
Limit Values
Min.
Unit
Max.
CC 2 × TSSC3)
–
ns
MTSR/SLSOx delay from SCLK
t50
t51
CC 0
8
ns
MRST setup to SCLK
t52
SR 10
–
ns
MRST hold from SCLK
t53
SR 5
–
ns
SCLK clock period1)2)
1) SCLK signal rise/fall times are the same as the A2 Pads rise/fall times.
2) SCLK signal high and low times can be minimum 1 × TSSC.
3) TSSCmin = TSYS = 1/fSYS. When fSYS = 80 MHz, t50 = 25ns
t50
SCLK1)2)
t51
t51
MTSR1)
t52
t53
Data
valid
MRST1)
t51
SLSOx2)
1) This timing is based on the following setup: CON.PH = CON.PO = 0.
2) The transition at SLSOx is based on the following setup: SSOTC.TRAIL = 0
and the first SCLK high pulse is in the first one of a transmission.
SSC_Tmg_1.vsd
Figure 4-19 SSC Master Mode Timing
Data Sheet
105
V1.0, 2008-04
TC1762
Preliminary
5
Packaging
Packaging
Chapter 5 provides the information of the TC1762 package and reliability section.
5.1
Package Parameters
Table 5-1 provides the characteristics of the package parameters.
Table 5-1
Package Parameters (PG-LQFP-176-2)
Parameter
Symbol
Limit Values
Min.
Max.
Unit Notes
Thermal resistance junction
case top1)
RTJCT CC
–
5.4
K/W –
Thermal resistance junction
leads1)
RTJL
–
21.5
K/W –
CC
1) The thermal resistances between the case top and the ambient (RTCAT), the leads and the ambient (RTLA) are
to be combined with the thermal resistances between the junction and the case top (RTJCT ), the junction and
the leads (RTJL) given above, in order to calculate the total thermal resistance between the junction and the
ambient (RTJA). The thermal resistances between the case top and the ambient (RTCAT ), the leads and the
ambient (RTLA) depend on the external system (PCB, case) characteristics, and are under user responsibility.
The junction temperature can be calculated using the following equation: TJ=TA+RTJA × PD, where the RTJA is
the total thermal resistance between the junction and the ambient. This total junction ambient resistance RTJA
can be obtained from the upper four partial thermal resistances.
Data Sheet
106
V1.0, 2008-04
TC1762
Preliminary
5.2
Packaging
Package Outline
Figure 5-1 shows the package outlines of the TC1762.
PG-LQFP-176-2
Plastic Low Profile Quad Flat Package
Figure 5-1
Package Outlines PG-LQFP-176-2
You can find all of our packages, sorts of packing and others in our
Infineon Internet Page “Products”: http://www.infineon.com/products.
Dimensions in mm
SMD = Surface Mounted Device
Data Sheet
107
V1.0, 2008-04
TC1762
Preliminary
5.3
Packaging
Flash Memory Parameters
The data retention time of the TC1762’s Flash memory (i.e. the time after which stored
data can still be retrieved) depends on the number of times the Flash memory has been
erased and programmed.
Table 5-2
Flash Parameters
Parameter
Symbol
Limit Values
Min.
Max.
Unit
Notes
Program Flash
Retention Time,
Physical Sector1) 2)
tRET
20
–
years
Max. 1000
erase/program cycles
Program Flash
Retention Time,
Logical Sector1)2)
tRETL
20
–
years
Max. 50
erase/program cycles
Data Flash Endurance
(32 Kbyte)
NE
15 000
–
–
Max. data retention
time 5 years
Data Flash Endurance,
EEPROM Emulation
(8 × 4 Kbyte)
NE8
120 000
–
–
Max. data retention
time 5 years
Programming Time per
Page3)
tPR
–
5
ms
–
Program Flash Erase
Time per 256-Kbyte
sector
tERP
–
5
s
fCPU = 80 MHz
Data Flash Erase Time
per 16-Kbyte sector
tERD
–
0.625
s
fCPU = 80 MHz
Wake-up time
tWU
4300 × 1/fCPU + 40µs
1) Storage and inactive time included.
2) At average weighted junction temperature TJ = 100 °C, or
the retention time at average weighted temperature of TJ = 110 °C is minimum 10 years, or
the retention time at average weighted temperature of TJ = 150 °C is minimum 0.7 years.
3) In case the Program Verify feature detects weak bits, these bits will be programmed once more. The
reprogramming takes additional 5ms.
Data Sheet
108
V1.0, 2008-04
TC1762
Preliminary
5.4
Packaging
Quality Declaration
Table 5-3 shows the characteristics of the quality parameters in the TC1762.
Table 5-3
Quality Parameters
Parameter
Symbol
Limit Values
Unit
Notes
Min.
Max.
–
24000
hours
At average
weighted junction
temperature
TJ = 127°C
–
66000
hours
At average
weighted junction
temperature
TJ = 100°C
–
20
years
At average
weighted junction
temperature
TJ = 85°C
–
2000
V
Conforming to
EIA/JESD22A114-B
–
500
V
–
ESD susceptibility
VCDM
according to Charged
Device Model (CDM) pins
–
500
V
Conforming to
JESD22-C101-C
Moisture Sensitivity Level (MSL)
–
3
V
Conforming to
J-STD-020C for
240°C
Operation Lifetime1)2)
tOP
ESD susceptibility
VHBM
according to Human Body
Model (HBM)
ESD susceptibility of the
LVDS pins
VHBM1
1) This lifetime refers only to the time when the device is powered-on.
2) An example of a detailed temperature profile is as below:
2000 hours at TJ = 150oC
16000 hours at TJ = 125oC
6000 hours at TJ = 110oC
This example is equivalent to the operation lifetime and average temperatures given in Table 5-3.
Note: Information about soldering can be found on the “package” information page
under: http://www.infineon.com/products.
Data Sheet
109
V1.0, 2008-04
w w w . i n f i n e o n . c o m
Published by Infineon Technologies AG