SAK-TC1766-192F80HL BD Infineon Technologies, SAK-TC1766-192F80HL BD Datasheet

Page 1

TC1766 ...

Page 2

... Infineon Technologies Office. Infineon Technologies Components may only be used in life-support devices or systems with the express written approval of Infineon Technologies failure of such components can reasonably be expected to cause the failure of that life-support device or system affect the safety or effectiveness of that device or system. Life support devices or systems are intended to be implanted in the human body support and/or maintain and sustain and/or protect human life ...

Page 3

TC1766 ...

Page 4

... MLI timing, maximum operating frequency limit is extended, t31 is added. 109 Thermal resistance junction leads is updated. Trademarks TriCore® trademark of Infineon Technologies AG. We Listen to Your Comments Any information within this document that you feel is wrong, unclear or missing at all? Your feedback will help us to continuously improve the quality of this document. ...

Page 5

Preliminary Table of Contents 1 Summary of Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ...

Page 6

Preliminary 4.2 DC Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ...

Page 7

Preliminary 1 Summary of Features The TC1766 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 ...

Page 8

Preliminary – 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 • 32 analog input lines for ADC and FADC • 81 digital general purpose ...

Page 9

... For the available ordering codes for the TC1766, please refer to the “Product Catalog Microcontrollers” that summarizes all available microcontroller variants. This document describes the derivatives of the device. derivatives and summarizes the differences. Table 1-1 TC1766 Derivative Synopsis Derivative SAK-TC1766-192F80HL Data Sheet Summary of Features Table 1-1 Ambient Temperature Range o o ...

Page 10

Preliminary 2 General Device Information Chapter 2 provides the general information for the TC1766. 2.1 Block Diagram Figure 2-1 shows the TC1766 block diagram. PMI 16 KB SPRAM 8 KB ICACHE PMU 16 KB BROM 1504 KB Pflash 32 KB ...

Page 11

Preliminary 2.2 Logic Symbol Figure 2-2 shows the TC1766 logic symbol. PORST HDRST General Control BYPASS TESTMODE FCLP 0A FCLN0 MSC0 Control SOP0A SON0 AN[35:0] ADC Analog Inputs ADC/FADC Analog Power Supply V V AREF0 ...

Page 12

Preliminary 2.3 Pin Configuration Figure 2-3 shows the TC1766 pin configuration. OCDSDBG0/OUT40/IN40/P5.0 1 OCDSDBG1/OUT41/IN41/P5.1 2 OCDSDBG2/OUT42/IN42/P5.2 3 OCDSDBG3/OUT43/IN43/P5.3 4 OCDSDBG4/OUT44/IN44/P5.4 5 OCDSDBG5/OUT45/IN45/P5.5 6 OCDSDBG6/OUT46/IN46/P5.6 7 OCDSDBG7/OUT47/IN47/P5.7 8 TRCLK DDP OCDSDBG8/TDATA1/RDATA0B/P5.8 13 ...

Page 13

Preliminary 2.4 Pad Driver and Input Classes Overview The TC1766 provides different types and classes of input and output lines. For understanding of the abbreviations in gives an overview on the pad type and class types. Data Sheet General Device ...

Page 14

Preliminary 2.5 Pin Definitions and Functions Table 2-1 shows the TC1766 pin definitions and functions. Table 2-1 Pin Definitions and Functions Symbol Pins I/O Pad Driver Class Parallel Ports P0 I/O A1 P0.0 145 P0.1 146 P0.2 147 P0.3 148 ...

Page 15

Preliminary Table 2-1 Pin Definitions and Functions (cont’d) Symbol Pins I/O Pad Driver Class P1 I P1.4 107 A1 P1.5 108 A1 P1.6 109 A1 P1.7 110 A1 ...

Page 16

Preliminary Table 2-1 Pin Definitions and Functions (cont’d) Symbol Pins I/O Pad Driver Class P2 I ...

Page 17

Preliminary Table 2-1 Pin Definitions and Functions (cont’d) Symbol Pins I/O Pad Driver Class P2.8 164 A2 P2.9 160 A2 P2.10 161 A2 P2.11 162 A2 P2.12 163 A2 P2.13 165 A1 Data Sheet Power Functions Supply SLSO04 SLSO14 EN00 ...

Page 18

Preliminary Table 2-1 Pin Definitions and Functions (cont’d) Symbol Pins I/O Pad Driver Class P3 I/O P3.0 136 A2 P3.1 135 A2 P3.2 129 A2 P3.3 130 A2 P3.4 132 A2 P3.5 126 A2 P3.6 127 A2 P3.7 131 A2 ...

Page 19

Preliminary Table 2-1 Pin Definitions and Functions (cont’d) Symbol Pins I/O Pad Driver Class P4 I/O P4.[3: Data Sheet Power Functions Supply V Port 4 / Hardware Configuration ...

Page 20

Preliminary Table 2-1 Pin Definitions and Functions (cont’d) Symbol Pins I/O Pad Driver Class P5 I/O A2 P5.0 1 P5.1 2 P5.2 3 P5.3 4 P5.4 5 P5.5 6 P5.6 7 P5.7 8 Data Sheet Power Functions Supply V Port ...

Page 21

Preliminary Table 2-1 Pin Definitions and Functions (cont’d) Symbol Pins I/O Pad Driver Class P5.8 13 P5.9 14 P5.10 15 P5.11 16 P5.12 17 P5.13 18 Data Sheet Power Functions Supply OCDSDBG8 TDATA1 RDATA0B OCDSDBG9 TVALID1 RVALID0B OCDSDBG10 TREADY1 RREADY0B ...

Page 22

Preliminary Table 2-1 Pin Definitions and Functions (cont’d) Symbol Pins I/O Pad Driver Class P5.14 19 P5.15 20 MSC0 Outputs C FCLP0A 157 O FCLN0 156 O SOP0A 159 O SON0 158 O Data Sheet Power Functions Supply OCDSDBG14 RREADY1 ...

Page 23

Preliminary Table 2-1 Pin Definitions and Functions (cont’d) Symbol Pins I/O Pad Driver Class Analog Inputs AN[35: AN0 67 AN1 66 AN2 65 AN3 64 AN4 63 AN5 62 AN6 61 AN7 36 AN8 60 AN9 59 AN10 ...

Page 24

Preliminary Table 2-1 Pin Definitions and Functions (cont’d) Symbol Pins I/O Pad Driver Class AN31 AN32 31 AN33 30 AN34 29 AN35 28 System I/O TRST 114 I A2 TCK 115 I A2 TDI 111 I A1 ...

Page 25

Preliminary Table 2-1 Pin Definitions and Functions (cont’d) Symbol Pins I/O Pad Driver Class Power Supplies V 54 – – DDM V 53 – – SSM V 24 – – DDMF V 25 – – SSMF V 23 – – ...

Page 26

Preliminary Table 2-1 Pin Definitions and Functions (cont’d) Symbol Pins I/O Pad Driver Class V 11, – – DDP 69, 83, 100, 124, 154, 171, 139 V 12, – – SS 70, 85, 101, 125, 155, 172, 140 ...

Page 27

Preliminary Table 2-2 List of Pull-up/Pull-down Reset Behavior of the Pins Pins All GPIOs, TDI, TMS, TDO HDRST BYPASS TRST, TCK TRCLK BRKIN, BRKOUT, TESTMODE NMI, PORST Data Sheet General Device Information PORST = 0 Pull-up Drive-low Pull-up High-impedance High-impedance ...

Page 28

Preliminary 3 Functional Description Chapter 3 provides an overview of the TC1766 functional description. 3.1 System Architecture and On-Chip Bus Systems The TC1766 has two independent on-chip buses (see also TC1766 block diagram on Page 2-6): • Local Memory Bus ...

Page 29

Preliminary 3.2 On-Chip Memories As shown in the TC1766 block diagram on on-chip memories that are used as program or data memory. • Program memory in PMU – 16 Kbyte Boot ROM (BROM) – 1504 Kbyte Program Flash (PFlash) • ...

Page 30

Preliminary • 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 Features of Data ...

Page 31

Preliminary 3.3 Architectural Address Map Table 3-1 shows the overall architectural address map as defined for the TriCore and as implemented in TC1766. Table 3-1 TC1766 Architectural Address Map Seg- Contents Size ment 0-7 Global 8 x 256 Mbyte 8 ...

Page 32

Preliminary 3.4 Memory Protection System The TC1766 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. ...

Page 33

Preliminary The PCP2 in the TC1766 contains an improved version of the TC1775’s PCP with the following enhancements: • Optimized context switching • Support for nested interrupts • Enhanced instruction set • Enhanced instruction execution speed • Enhanced interrupt queueing ...

Page 34

Preliminary Table 3-2 PCP2 Instruction Set Overview Instruction Group Description DMA primitives Efficient DMA channel implementation Load/Store Transfer data between PRAM or FPI memory and the general purpose registers, as well as move or exchange values between registers Arithmetic Add, ...

Page 35

Preliminary 3.6 DMA Controller and Memory Checker The DMA Controller of the TC1766 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 ...

Page 36

Preliminary Features • 8 independent DMA channels – 8 DMA channels in the DMA Sub-Block – selectable request inputs per DMA channel – 2-level programmable priority of DMA channels within the DMA Sub-Block – Software and hardware ...

Page 37

Preliminary Note: Although the polynomial above is used for generation, the generation algorithm differs from the one that is used by the Ethernet protocol. 3.7 Interrupt System The TC1766 interrupt system provides a flexible and time-efficient means of processing interrupts. ...

Page 38

Preliminary Service Requestors 2 MSC0 4 MLI0 2 MLI1 3 SSC0 3 SSC1 4 ASC0 4 ASC1 6 MultiCAN 4 ADC0 2 FADC 38 GPTA0 2 STM 1 FPU 1 Flash 2 Ext. Int Figure 3-3 Block Diagram of the ...

Page 39

Preliminary 3.8 Asynchronous/Synchronous Serial Interfaces (ASC0, ASC1) Figure 3-4 shows a global view of the functional blocks and interfaces of the two Asynchronous/Synchronous Serial Interfaces, ASC0 and ASC1. f Clock ASC Control Address Decoder EIR TBIR Interrupt TIR Control RIR ...

Page 40

Preliminary 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 ...

Page 41

Preliminary 3.9 High-Speed Synchronous Serial Interfaces (SSC0 and SSC1) Figure 3-5 shows a global view of the functional blocks and interfaces of the two high- speed Synchronous Serial Interfaces, SSC0 and SSC1. f SSC 0 Clock f Control C L ...

Page 42

Preliminary The SSC supports full-duplex and half-duplex serial synchronous communication up to 40.0 MBaud (@ 80 MHz module clock). The serial clock signal can be generated by the SSC itself (Master Mode) or can be received from an external master ...

Page 43

Preliminary 3.10 Micro Second Bus Interfaces (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 ...

Page 44

Preliminary 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 ...

Page 45

Preliminary 3.11 MultiCAN Controller (CAN) Figure 3-7 shows a global view of the MultiCAN module with its functional blocks and interfaces. f CAN Clock f Control CLC Address Message Decoder Object Buffer DMA Objects INT_O [1:0] Interrupt Control INT_O [5:2] ...

Page 46

Preliminary 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 ...

Page 47

Preliminary 3.12 Micro Link Serial Bus Interface (MLI0, MLI1) 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. ...

Page 48

Preliminary Figure 3-9 shows a global view of the functional blocks of the two MLI modules with its interfaces. Data Sheet Functional Description 44 TC1766 V1.0, 2008-04 ...

Page 49

Preliminary f MLI0 Clock Control Address Decoder MLI0 Module SR[3:0] (Kernel) Interrupt Control SR[4:7] To DMA BRKOUT Cerberus f Clock MLI1 Control Address Decoder MLI1 SR[1:0] Interrupt Module Control (Kernel) SR[3:2] N.C. SR[4:7] To DMA BRKOUT Cerberus Figure 3-9 Block ...

Page 50

Preliminary 3.13 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 ...

Page 51

Preliminary 3.13.1 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 ...

Page 52

Preliminary • Duty Cycle Measurement (DCM) – Four independent units – 100% margin and time-out handling f – maximum resolution GPTA f – /2 maximum input signal frequency GPTA • Digital Phase Locked Loop (PLL) – One unit ...

Page 53

Preliminary I/O Sharing Unit • Interconnecting inputs and outputs from internal clocks, FPC, GTC, LTC, ports, and MSC interface Data Sheet Functional Description 49 TC1766 V1.0, 2008-04 ...

Page 54

Preliminary 3.14 Analog-to-Digital Converter (ADC0) Section 3.14 shows the global view of the ADC module with its functional blocks and interfaces and the features which are provided by the module AGND0 f ADC Clock f Control ...

Page 55

Preliminary 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 • ...

Page 56

Preliminary 3.15 Fast Analog-to-Digital Converter Unit (FADC) The on-chip FADC module of the TC1766 basically is a 2-channel A/D converter with 10- bit resolution that operates by the method of the successive approximation. As shown in Figure 3-12, the main ...

Page 57

Preliminary f FADC Clock f Control CLC Address Decoder SR[1:0] Interrupt Control SR[3:2] DMA OUT1 OUT9 OUT18 OUT26 GPTA0 OUT2 OUT10 OUT19 OUT27 External Request Unit (SCU) Figure 3-12 Block Diagram of the FADC Module Features • Extreme fast conversion, ...

Page 58

Preliminary 3.16 System Timer The TC1766’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 ...

Page 59

Preliminary 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. ...

Page 60

Preliminary STMIR1 Interrupt Control STMIR0 Enable / 00 Disable Clock f 00 Control STM STM_TIM5 Address Decoder PORST Figure 3-13 General Block Diagram of the STM Module Registers Data Sheet 31 23 STM_CMP0 Compare Register 0 31 STM_CMP1 55 47 ...

Page 61

Preliminary 3.17 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 TC1766 in a user-specified time period. When enabled, ...

Page 62

Preliminary • 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. 3.18 System Control Unit The System Control Unit (SCU) ...

Page 63

Preliminary 3.19 Boot Options The TC1766 booting schemes provide a number of different boot options for the start of code execution. Table 3-3 Table 3-3 TC1766 Boot Selections BRKIN HWCFG TESTMODE Type of Boot [3:0] Normal Boot Options 1 0000 ...

Page 64

Preliminary 3.20 Power Management System The TC1766 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 ...

Page 65

Preliminary enabled interrupt signal is detected, or when the count value (WDT_SR.WDTTIM) changes from 7FFF to 8000 H 3.21 On-Chip Debug Support Figure 3-14 shows a block diagram of the TC1766 OCDS system. 16 OCDS2[15:0] TDO TDI TMS TCK TRST ...

Page 66

Preliminary 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 ...

Page 67

Preliminary 3.22 Clock Generation and PLL The TC1766 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 TC1766’s entire clock tree • ...

Page 68

Preliminary are derived from f VCO f equal to . CPU XTAL1 f Oscillator OSC Circuit XTAL2 Osc. Run Detect. OGC MOSC OSCR BYPASS Register OSC_CON OSC_ BYPASS Figure 3-15 Clock Generation Unit Recommended Oscillator Circuits The oscillator circuit, a ...

Page 69

Preliminary 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 ...

Page 70

Preliminary 3.23 Power Supply The TC1766 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 ...

Page 71

Preliminary 3.24 Identification Register Values Table 3-5 shows the address map and reset values of the TC1766 Identification Registers. Table 3-5 TC1766 Identification Registers Short Name Address SCU_ ID F000 0008 MANID F000 0070 CHIPID F000 0074 RTID F000 0078 ...

Page 72

Preliminary Table 3-5 TC1766 Identification Registers Short Name Address LBCU_ID F87F FE08 LFI_ID F87F FF08 Data Sheet Reset Value 000F C005 H H 000C C005 TC1766 Functional Description Stepping – – V1.0, 2008-04 ...

Page 73

Preliminary 4 Electrical Parameters Chapter 4 provides the characteristics of the electrical parameters which are implementation-specific for the TC1766. 4.1 General Parameters The general parameters are described here to aid the users in interpreting the parameters mainly in Section 4.2 ...

Page 74

Preliminary 4.1.2 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 Table 4-1 Pad Driver and Pad Classes Overview Class ...

Page 75

Preliminary 4.1.3 Absolute Maximum Ratings Table 4-2 shows the absolute maximum ratings of the TC1766 parameters. Table 4-2 Absolute Maximum Rating Parameters Parameter Ambient temperature Storage temperature Junction temperature Voltage at 1.5 V power supply 1) V pins with respect ...

Page 76

Preliminary 4.1.4 Operating Conditions The following operating conditions must not be exceeded in order to ensure correct operation of the TC1766. All parameters specified in the following table refer to these operating conditions, unless otherwise noted. Table 4-3 Operating Condition ...

Page 77

Preliminary 1) Digital supply voltages applied to the TC1766 must be static regulated voltages which allow a typical voltage swing of ±5%. 2) Voltage overshoot permissible at Power-Up and PORST low, provided the pulse duration ...

Page 78

Preliminary Table 4-4 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, ...

Page 79

Preliminary 4.2 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 TC1766. Table 4-5 Input/Output DC-Characteristics (Operating Conditions apply) Parameter Symbol ...

Page 80

Preliminary Table 4-5 Input/Output DC-Characteristics (cont’d)(Operating Conditions Parameter Symbol = 3. 3.3V ±5%) V Class A Pads ( DDP Output low V OLA 4) voltage V Output high OHA 3) voltage V Input low voltage ILA ...

Page 81

Preliminary Table 4-5 Input/Output DC-Characteristics (cont’d)(Operating Conditions Parameter Symbol I Input leakage OZA24 current Class A2/3/4 pins I Input leakage OZA1 current Class A1 pins = 3. 3.3V ±5%) Class C Pads ( V DDP V ...

Page 82

Preliminary 4.2.2 Analog to Digital Converter (ADC0) Table 4-6 provides the characteristics of the ADC module in the TC1766. Table 4-6 ADC Characteristics (Operating Conditions apply) Parameter Symbol V Analog supply DDM voltage Analog ground SSM voltage ...

Page 83

Preliminary Table 4-6 ADC Characteristics (cont’d) (Operating Conditions apply) Parameter Symbol t Conversion time C 7) Total unadjusted TUE 5) error 11)5) DNL error TUE DNL 11)5) INL error TUE INL 11)5) Gain error TUE GAIN 11)5) Offset error TUE ...

Page 84

Preliminary Table 4-6 ADC Characteristics (cont’d) (Operating Conditions apply) Parameter Symbol 14) I Input leakage OZ1 current at analog inputs AN2 to AN30, see Figure 4-3 Input leakage I OZ2 V current at AREF I Input current at AREF 17) ...

Page 85

Preliminary Table 4-6 ADC Characteristics (cont’d) (Operating Conditions apply) Parameter Symbol R ON resistance of AIN the transmission gates in the analog voltage path R ON resistance for AIN7T the ADC test (pull-down for AIN7) Current through I AIN7T resistance ...

Page 86

Preliminary I 15) is valid for the minimum specified conversion time. The current flowing during an ADC conversion AREF_MAX with a duration 25µs can be calculated with the formula C needs a total charge of ...

Page 87

Preliminary R EXT AIN EXT V AREF Figure 4-2 ADC0 Input Circuits Data Sheet R AIN, On ANx C AINTOT V R AGNDx AIN7T Reference Voltage Input Circuitry R V AREF, On AREFx C - AREFTOT V ...

Page 88

Preliminary Ioz1 3uA 1uA 400nA 300nA -200nA 2% -1uA Ioz1 3uA 1uA 300nA 200nA -200nA 2% -1uA Figure 4-3 ADC0 Analog Inputs Leakage Data Sheet AN0, AN1 and AN31 95% AN2 to AN30 95% 84 TC1766 Electrical Parameters V [V ...

Page 89

Preliminary 4.2.3 Fast Analog to Digital Converter (FADC) Table 4-7 provides the characteristics of the FADC module in the TC1766. Table 4-7 FADC Characteristics (Operating Conditions apply) Parameter Symbol E DNL error DNL INL error E INL 1)12) E Gradient ...

Page 90

Preliminary Table 4-7 FADC Characteristics (cont’d)(Operating Conditions apply) Parameter Symbol I Analog supply DDMF currents I DDAF I Input current at each FAREF V FAREF I Input leakage current FOZ2 11 FAREF I Input leakage current FOZ3 V ...

Page 91

Preliminary 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 ...

Page 92

Preliminary Ioz1 3uA 1uA 400nA 300nA -200nA 2% -1uA Figure 4-5 Analog Inputs AN32-AN35 Leakage Data Sheet AN32 to AN35 95% 98% 88 TC1766 Electrical Parameters DDM 100% V1.0, 2008-04 ...

Page 93

Preliminary 4.2.4 Oscillator Pins Table 4-8 provides the characteristics of the oscillator pins in the TC1766. Table 4-8 Oscillator Pins Characteristics (Operating Conditions apply) Parameter Symbol f Frequency Range OSC Input low voltage XTAL1 Input high voltage ...

Page 94

Preliminary 4.2.5 Temperature Sensor Table 4-9 provides the characteristics of the temperature sensor in the TC1766. Table 4-9 Temperature Sensor Characteristics (Operating Conditions apply) Parameter Symbol T Temperature SR -40 SR Sensor Range t Start-up time SR TSST after resets ...

Page 95

Preliminary 4.2.6 Power Supply Current Table 4-10 provides the characteristics of the power supply current in the TC1766. Table 4-10 Power Supply Current (Operating Conditions apply) Parameter Symbol I PORST low current PORST low current at ...

Page 96

Preliminary 4.3 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 ...

Page 97

Preliminary 4.3.2 Output Rise/Fall Times Table 4-11 provides the characteristics of the output rise/fall times in the TC1766. Table 4-11 Output Rise/Fall Times (Operating Conditions apply) Parameter Symbol Class A1 Pads 1) Rise/fall times t , RA1 Class A1 pads ...

Page 98

Preliminary 4.3.3 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 ...

Page 99

Preliminary V DDP V DDPmin V PORST3 DDmin V PORST1.5min Figure 4-10 Power Down / Power Loss Sequence Data Sheet Power Supply Voltage 3.3V 3.13V PORST 1.5V 1.42V PORST PowerDown3.3_1.5_reset_only_LL.vsd 95 TC1766 Electrical Parameters V DDP -5% ...

Page 100

Preliminary 4.3.4 Power, Pad and Reset Timing Table 4-12 provides the characteristics of the power, pad and reset timing in the TC1766. Table 4-12 Power, Pad and Reset Timing Parameters Parameter V Min. voltage to ensure defined DDP 1) pad ...

Page 101

Preliminary 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 ...

Page 102

Preliminary 4.3.5 Phase Locked Loop (PLL) Section 4.3.5 provides the characteristics of the PLL parameters and its operation in the TC1766. Note: All PLL characteristics defined on this and the next page are verified by design characterization. Table 4-13 PLL ...

Page 103

Preliminary Note: The frequency of system clock P With rising number of clock cycles the maximum jitter increases linearly value P of that is defined by the K-factor of the PLL. Beyond this value of accumulated jitter ...

Page 104

Preliminary Figure 4-13 Approximated Maximum Accumulated PLL Jitter for Typical CPU Clock Frequencies Note: The maximum peak-to-peak noise on the main oscillator and PLL power supply (measured between mV. This condition can be achieved by appropriate ...

Page 105

Preliminary 4.3.6 Debug Trace Timing 3.13 to 3.47 V (Class A); SS DDP C C (TRCLK pF; (TR[15:0 Table 4-14 Debug Trace Timing Parameter Parameter TR[15:0] new ...

Page 106

Preliminary 4.3.7 Timing for JTAG Signals (Operating Conditions apply, C Table 4-15 TCK Clock Timing Parameter Parameter 1) TCK clock period TCK high time TCK low time TCK clock rise time TCK clock fall time f 1) should be lower ...

Page 107

Preliminary Table 4-16 JTAG Timing Parameter Parameter TMS setup to TCK TMS hold to TCK TDI setup to TCK TDI hold to TCK TDO valid output from TCK TDO high impedance to valid output 2) from TCK TDO valid output ...

Page 108

Preliminary TCK TMS TDI 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 ...

Page 109

Preliminary 4.3.8 Peripheral Timings Section 4.3.8 provides the characteristics of the peripheral timings in the TC1766. 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 ...

Page 110

Preliminary TCLKx TDATAx TVALIDx TREADYx RCLKx RDATAx RVALIDx RREADYx MLI Interface Timing Figure 4-17 Note: The generation of RREADYx is in the input clock domain of the receiver. The reception of TREADYx is asynchronous to TCLKx. Data Sheet t 30 ...

Page 111

Preliminary 4.3.8.2 Micro Second Channel (MSC) Interface Timing Table 4-18 provides the characteristics of the MSC timing in the TC1766. Table 4-18 MSC Interface Timing (Operating Conditions apply Parameter 1)2) FCLP clock period SOP/ENx outputs delay ...

Page 112

Preliminary 4.3.8.3 Synchronous Serial Channel (SSC) Master Mode Timing Table 4-19 provides the characteristics of the SSC timing in the TC1766. Table 4-19 SSC Master Mode Timing (Operating Conditions apply Parameter 1)2) SCLK clock period MTSR/SLSOx ...

Page 113

Preliminary 5 Package and Reliability Chapter 5 provides the information of the TC1766 package and reliability section. 5.1 Package Parameters Table 5-1 provides the thermal characteristics of the package. Table 5-1 Thermal Characteristics of the Package Parameter Thermal resistance junction ...

Page 114

Preliminary 5.2 Package Outline Figure 5-1 shows the package outlines of the TC1766. 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 ...

Page 115

Preliminary 5.3 Flash Memory Parameters The data retention time of the TC1766’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 ...

Page 116

Preliminary 5.4 Quality Declaration Table 5-3 shows the characteristics of the quality parameters in the TC1766. Table 5-3 Quality Parameters Parameter 1)2) Operation Lifetime ESD susceptibility according to Human Body Model (HBM) ESD susceptibility of the LVDS pins ESD susceptibility ...

Page 117

... Published by Infineon Technologies AG ...