56F803 Data Sheet Preliminary Technical Data 56F800 16-bit Digital Signal Controllers DSP56F803 Rev. 15 01/2007 freescale.com 56F803 General Description • Up to 40 MIPS at 80MHz core frequency • 6-channel PWM module • DSP and MCU functionality in a unified, C-efficient architecture • Two 4-channel 12-bit ADCs • Quadrature Decoder • Hardware DO and REP loops • CAN 2.0 B module • MCU-friendly instruction set supports both DSP and controller functions: MAC, bit manipulation unit, 14 addressing modes • Serial Communication Interface (SCI) • Serial Peripheral Interface (SPI) • 31.5K × 16-bit words (64KB) Program Flash • Up to two General Purpose Quad Timers • 512 × 16-bit words (1KB) Program RAM • JTAG/OnCETM port for debugging • 4K × 16-bit words (8KB) Data Flash • 16 shared GPIO lines • 2K × 16-bit words (4KB) Data RAM • 100–pin LQFP package • 2K × 16-bit words (4KB) Boot Flash • Up to 64K × 16-bit words each of external Program and Data memory 6 3 3 PWM Outputs Current Sense Inputs PWMA EXTBOOT RESET Fault Inputs IRQB IRQA VCAPC VDD 6 2 6 JTAG/ OnCE Port 4 4 4 A/D1 A/D2 Digital Reg VSSA Analog Reg Low Voltage Supervisor ADC Quadrature Decoder 0 / Quad Timer A Quad Timer B Interrupt Controller Quad Timer D 2 Program Controller and Hardware Looping Unit • Data Memory 4096 x 16 Flash 2048 x 16 SRAM CAN 2.0A/B • • CGDB XAB1 XAB2 SPI or GPIO 16-Bit 56800 Core • • INTERRUPT CONTROLS 16 COP/ Watchdog Application-Specific Memory & Peripherals CLKO XTAL Clock Gen EXTAL • • IPBB CONTROLS 16 COP RESET MODULE CONTROLS ADDRESS BUS [8:0] Bit Manipulation Unit PLL • XDB2 2 SCI or GPIO Data ALU 16 x 16 + 36 → 36-Bit MAC Three 16-bit Input Registers Two 36-bit Accumulators Address Generation Unit PAB PDB Boot Flash 2048 x 16 Flash Quad Timer C 4 VDDA VREF Program Memory 32252 x 16 Flash 512 x 16 SRAM 2 VSS 6* IPBus Bridge (IPBB) DATA BUS [15:0] External Bus Interface Unit External Address Bus Switch External Data Bus Switch Bus Control A[00:05] 6 10 A[06:15] or GPIO-E2:E3 & GPIO-A0:A7 D[00:15] 16 PS Select DS Select WR Enable RD Enable 56F803 Block Diagram *includes TCS pin which is reserved for factory use and is tied to VSS 56F803 Technical Data, Rev. 15 Freescale Semiconductor 3 Part 1 Overview 1.1 56F803 Features 1.1.1 • • • • • • • • • • • • • • 1.1.2 • • Processing Core Efficient 16-bit 56800 family controller engine with dual Harvard architecture As many as 40 Million Instructions Per Second (MIPS) at 80MHz core frequency Single-cycle 16 × 16-bit parallel Multiplier-Accumulator (MAC) Two 36-bit accumulators, including extension bits 16-bit bidirectional barrel shifter Parallel instruction set with unique processor addressing modes Hardware DO and REP loops Three internal address buses and one external address bus Four internal data buses and one external data bus Instruction set supports both DSP and controller functions Controller style addressing modes and instructions for compact code Efficient C compiler and local variable support Software subroutine and interrupt stack with depth limited only by memory JTAG/OnCE debug programming interface Memory Harvard architecture permits as many as three simultaneous accesses to Program and Data memory On-chip memory including a low-cost, high-volume Flash solution — 31.5K × 16-bit words of Program Flash — 512K × 16-bit words of Program RAM — 4K × 16-bit words of Data Flash — 2K × 16-bit words of Data RAM — 2K × 16-bit words of Boot Flash • Off-chip memory expansion capabilities programmable for 0, 4, 8, or 12 wait states — As much as 64K × 16 bits of Data memory — As much as 64K × 16 bits of Program memory 1.1.3 • • • Peripheral Circuits for 56F803 Pulse Width Modulator module (PWM) with six PWM outputs, three Current Sense inputs, and three Fault inputs, fault-tolerant design with dead time insertion, supports both center- and edge- aligned modes, supports Freescale’s patented dead time distortion correction Two 12-bit Analog-to-Digital Converters (ADCs), which support two simultaneous conversions; ADC and PWM modules can be synchronized Quadrature Decoder with four inputs (shares pins with Quad Timer) 56F803 Technical Data, Rev. 15 4 Freescale Semiconductor 56F803 Description • • • • • • • • • • 1.1.4 • • • • Four General Purpose Quad Timers: Timer A (sharing pins with Quad Dec0), Timers B &C without external pins and Timer D with two pins CAN 2.0 B module with 2-pin ports for transmit and receive Serial Communication Interface (SCI) with two pins (or two additional GPIO lines) Serial Peripheral Interface (SPI) with configurable 4-pin port (or four additional GPIO lines) Computer Operating Properly (COP) Watchdog timer Two dedicated external interrupt pins Sixteen multiplexed General Purpose I/O (GPIO) pins External reset input pin for hardware reset JTAG/On-Chip Emulation (OnCE™) for unobtrusive, processor speed-independent debugging Software-programmable, Phase Locked Loop-based frequency synthesizer for the controller core clock Energy Information Fabricated in high-density CMOS with 5V-tolerant, TTL-compatible digital inputs Uses a single 3.3V power supply On-chip regulators for digital and analog circuitry to lower cost and reduce noise Wait and Stop modes available 1.2 56F803 Description The 56F803 is a member of the 56800 core-based family of processors. It combines, on a single chip, the processing power of a DSP and the functionality of a microcontroller with a flexible set of peripherals to create an extremely cost-effective solution. Because of its low cost, configuration flexibility, and compact program code, the 56F803 is well-suited for many applications. The 56F803 includes many peripherals that are especially useful for applications such as motion control, smart appliances, steppers, encoders, tachometers, limit switches, power supply and control, automotive control, engine management, noise suppression, remote utility metering, and industrial control for power, lighting, and automation. The 56800 core is based on a Harvard-style architecture consisting of three execution units operating in parallel, allowing as many as six operations per instruction cycle. The MCU-style programming model and optimized instruction set allow straightforward generation of efficient, compact device and control code. The instruction set is also highly efficient for C compilers to enable rapid development of optimized control applications. The 56F803 supports program execution from either internal or external memories. Two data operands can be accessed from the on-chip Data RAM per instruction cycle. The 56F803 also provides two external dedicated interrupt lines, and up to 16 General Purpose Input/Output (GPIO) lines, depending on peripheral configuration. The 56F803 controller includes 31.5K words (16-bit) of Program Flash and 4K words of Data Flash (each programmable through the JTAG port) with 512 words of Program RAM and 2K words of Data RAM. It also supports program execution from external memory. A total of 2K words of Boot Flash is incorporated for easy customer-inclusion of field-programmable 56F803 Technical Data, Rev. 15 Freescale Semiconductor 5 software routines that can be used to program the main Program and Data Flash memory areas. Both Program and Data Flash memories can be independently bulk–erased or erased in page sizes of 256 words. The Boot Flash memory can also be either bulk- or page-erased. A key application-specific feature of the 56F803 is the inclusion of a Pulse Width Modulator (PWM) module. This module incorporates three complementary, individually programmable PWM signal outputs (the module is also capable of supporting three independent PWM functions, for a total of six PWM outputs) to enhance motor control functionality. Complementary operation permits programmable dead time insertion, distortion correction via current sensing by software, and separate top and bottom output polarity control. The up-counter value is programmable to support a continuously variable PWM frequency. Edge- and center-aligned synchronous pulse width control (0% to 100% modulation) is supported. The device is capable of controlling most motor types: ACIM (AC Induction Motors), both BDC and BLDC (Brush and Brushless DC motors), SRM and VRM (Switched and Variable Reluctance Motors), and stepper motors. The PWM incorporates fault protection and cycle-by-cycle current limiting with sufficient output drive capability to directly drive standard opto-isolators. A “smoke-inhibit”, write-once protection feature for key parameters and patented PWM waveform distortion correction circuit are also provided. The PWM is double-buffered and includes interrupt controls to permit integral reload rates to be programmable from 1 to 16. The PWM module provides a reference output to synchronize the ADC. The 56F803 incorporates a separate Quadrature Decoder capable of capturing all four transitions on the two-phase inputs, permitting generation of a number proportional to actual position. Speed computation capabilities accommodate both fast and slow moving shafts. The integrated watchdog timer in the Quadrature Decoder can be programmed with a time-out value to alarm when no shaft motion is detected. Each input is filtered to ensure only true transitions are recorded. This controller also provides a full set of standard programmable peripherals that include a Serial Communications Interface (SCI), one Serial Peripheral Interface (SPI), and four Quad Timers. Any of these interfaces can be used as General Purpose Input/Outputs (GPIO) if that function is not required. A Controller Area Network interface (CAN Version 2.0 A/B-compliant) and an internal interrupt controller are also included on the 56F803. 1.3 State of the Art Development Environment • • Processor ExpertTM (PE) provides a Rapid Application Design (RAD) tool that combines easy-to-use component-based software application creation with an expert knowledge system. The Code Warrior Integrated Development Environment is a sophisticated tool for code navigation, compiling, and debugging. A complete set of evaluation modules (EVMs) and development system cards will support concurrent engineering. Together, PE, Code Warrior and EVMs create a complete, scalable tools solution for easy, fast, and efficient development. 56F803 Technical Data, Rev. 15 6 Freescale Semiconductor Product Documentation 1.4 Product Documentation The four documents listed in Table 1-1 are required for a complete description and proper design with the 56F803. Documentation is available from local Freescale distributors, Freescale Semiconductor sales offices, Freescale Literature Distribution Centers, or online at: www.freescale.com Table 1-1 56F803 Chip Documentation Topic Description Order Number 56800E Family Manual Detailed description of the 56800 family architecture, and 16-bit core processor and the instruction set 56800EFM DSP56F801/803/805/807 User’s Manual Detailed description of memory, peripherals, and interfaces of the 56F801, 56F803, 56F803, and 56F807 DSP56F801-7UM 56F803 Technical Data Sheet Electrical and timing specifications, pin descriptions, and package descriptions (this document) DSP56F803 56F803 Errata Details any chip issues that might be present DSP56F803E 1.5 Data Sheet Conventions This data sheet uses the following conventions: OVERBAR This is used to indicate a signal that is active when pulled low. For example, the RESET pin is active when low. “asserted” A high true (active high) signal is high or a low true (active low) signal is low. “deasserted” A high true (active high) signal is low or a low true (active low) signal is high. Examples: Signal/Symbol Logic State Signal State Voltage1 PIN True Asserted VIL/VOL PIN False Deasserted VIH/VOH PIN True Asserted VIH/VOH PIN False Deasserted VIL/VOL 1. Values for VIL, VOL, VIH, and VOH are defined by individual product specifications. 56F803 Technical Data, Rev. 15 Freescale Semiconductor 7 Part 2 Signal/Connection Descriptions 2.1 Introduction The input and output signals of the 56F803 are organized into functional groups, as shown in Table 2-1 and as illustrated in Figure 2-1. In Table 2-2 through Table 2-17, each table row describes the signal or signals present on a pin. Table 2-1 Functional Group Pin Allocations Number of Pins Detailed Description Power (VDD or VDDA) 7 Table 2-2 Ground (VSS or VSSA) 7 Table 2-3 Supply Capacitors 2 Table 2-4 PLL and Clock 3 Table 2-5 Address Bus1 16 Table 2-6 Data Bus 16 Table 2-7 Bus Control 4 Table 2-8 Interrupt and Program Control 4 Table 2-9 Pulse Width Modulator (PWM) Port 12 Table 2-10 Serial Peripheral Interface (SPI) Port1 4 Table 2-11 Quadrature Decoder Port2 4 Table 2-12 Serial Communications Interface (SCI) Port1 2 Table 2-13 CAN Port 2 Table 2-14 Analog to Digital Converter (ADC) Port 9 Table 2-15 Quad Timer Module Port 2 Table 2-16 JTAG/On-Chip Emulation (OnCE) 6 Table 2-17 Functional Group 1. Alternately, GPIO pins 2. Alternately, Quad Timer pins 56F803 Technical Data, Rev. 15 8 Freescale Semiconductor Introduction Power Port VDD 6 Ground Port VSS 6* Power Port VDDA 1 Ground Port VSSA 1 Other Supply Ports VCAPC PLL and Clock EXTAL XTAL CLKO A0-A5 External Address Bus or GPIO External Data Bus A6-7 (GPIOE2-E3) A8-15 (GPIOA0-A7) D0–D15 PS DS External Bus Control RD WR PHASEA0 (TA0) Quadrature Decoder or Quad Timer A PHASEB0 (TA1) INDEX0 (TA2) HOME0 (TA3) 6 3 2 3 TCK JTAG/OnCE™ Port TDI TDO TRST DE ISA0-2 FAULTA0-2 PWMA Port 1 1 56F803 1 1 6 2 8 16 1 1 1 1 1 SCLK (GPIOE4) MOSI (GPIOE5) MISO (GPIOE6) SPI Port or GPIO SS (GPIOE7) TXD0 (GPIOE0) RXD0 (GPIOE1) SCI0 Port or GPIO 1 1 1 1 8 1 1 ANA0-7 VREF ADCA Port 1 1 1 1 1 TMS PWMA0-5 2 MSCAN_RX MSCAN_TX TD1-2 CAN Quad Timer D 1 1 1 1 1 1 1 1 IRQA IRQB RESET EXTBOOT Interrupt/ Program Control 1 1 *includes TCS pin which is reserved for factory use and is tied to VSS Figure 2-1 56F803 Signals Identified by Functional Group1 1. Alternate pin functionality is shown in parenthesis. 56F803 Technical Data, Rev. 15 Freescale Semiconductor 9 2.2 Power and Ground Signals Table 2-2 Power Inputs No. of Pins Signal Name Signal Description 6 VDD Power—These pins provide power to the internal structures of the chip, and should all be attached to VDD. 1 VDDA Analog Power—This pin is a dedicated power pin for the analog portion of the chip and should be connected to a low noise 3.3V supply. Table 2-3 Grounds No. of Pins Signal Name Signal Description 5 VSS GND—These pins provide grounding for the internal structures of the chip, and should all be attached to VSS. 1 VSSA Analog Ground—This pin supplies an analog ground. 1 TCS TCS—This Schmitt pin is reserved for factory use and must be tied to VSS for normal use. In block diagrams, this pin is considered an additional VSS. Table 2-4 Supply Capacitors No. of Pins Signal Name Signal Type State During Reset 2 VCAPC Supply Supply Signal Description VCAPC—Connect each pin to a 2.2 μF or greater bypass capacitor in order to bypass the core logic voltage regulator (required for proper chip operation). For more information, please refer to Section 5.2. 56F803 Technical Data, Rev. 15 10 Freescale Semiconductor Clock and Phase Locked Loop Signals 2.3 Clock and Phase Locked Loop Signals Table 2-5 PLL and Clock No. of Pins Signal Name Signal Type State During Reset 1 EXTAL Input Input 1 XTAL Input/ Output Chip-driven Signal Description External Crystal Oscillator Input—This input should be connected to an 8MHz external crystal or ceramic resonator. For more information, please refer to Section 3.5. Crystal Oscillator Output—This output should be connected to an 8MHz external crystal or ceramic resonator. For more information, please refer to Section 3.5. This pin can also be connected to an external clock source. For more information, please refer to Section 3.5.3. 1 CLKO Output Chip-driven Clock Output—This pin outputs a buffered clock signal. By programming the CLKOSEL[4:0] bits in the CLKO Select Register (CLKOSR), the user can select between outputting a version of the signal applied to XTAL and a version of the device’s master clock at the output of the PLL. The clock frequency on this pin can also be disabled by programming the CLKOSEL[4:0] bits in CLKOSR. 2.4 Address, Data, and Bus Control Signals Table 2-6 Address Bus Signals No. of Pins Signal Name Signal Type State During Reset 6 A0–A5 Output Tri-stated Address Bus—A0–A5 specify the address for external Program or Data memory accesses. 2 A6–A7 Output Tri-stated Address Bus—A6–A7 specify the address for external Program or Data memory accesses. GPIOE2– GPIOE3 Input/O utput Input Port E GPIO—These two pins are General Purpose I/O (GPIO) pins that can be individually programmed as input or output pins. Signal Description After reset, the default state is Address Bus. 8 A8–A15 Output Tri-stated GPIOA0– GPIOA7 Input/O utput Input Address Bus—A8–A15 specify the address for external Program or Data memory accesses. Port A GPIO—These eight pins are General Purpose I/O (GPIO) pins that can be individually programmed as input or output pins. After reset, the default state is Address Bus. 56F803 Technical Data, Rev. 15 Freescale Semiconductor 11 Table 2-7 Data Bus Signals No. of Pins Signal Name Signal Type State During Reset 16 D0–D15 Input/O utput Tri-stated Signal Description Data Bus— D0–D15 specify the data for external Program or Data memory accesses. D0–D15 are tri-stated when the external bus is inactive. Internal pull-ups may be active. Table 2-8 Bus Control Signals No. of Pins Signal Name Signal Type State During Reset 1 PS Output Tri-stated Program Memory Select—PS is asserted low for external Program memory access. 1 DS Output Tri-stated Data Memory Select—DS is asserted low for external Data memory access. 1 WR Output Tri-stated Write Enable—WR is asserted during external memory write cycles. When WR is asserted low, pins D0–D15 become outputs and the device puts data on the bus. When WR is deasserted high, the external data is latched inside the external device. When WR is asserted, it qualifies the A0–A15, PS, and DS pins. WR can be connected directly to the WE pin of a Static RAM. 1 RD Output Tri-stated Read Enable—RD is asserted during external memory read cycles. When RD is asserted low, pins D0–D15 become inputs and an external device is enabled onto the device data bus. When RD is deasserted high, the external data is latched inside the controller. When RD is asserted, it qualifies the A0–A15, PS, and DS pins. RD can be connected directly to the OE pin of a Static RAM or ROM. Signal Description 2.5 Interrupt and Program Control Signals Table 2-9 Interrupt and Program Control Signals No. of Pins Signal Name Signal Type State During Reset 1 IRQA Input (Schmitt) Input External Interrupt Request A—The IRQA input is a synchronized external interrupt request indicating an external device is requesting service. It can be programmed to be level-sensitive or negative-edge- triggered. 1 IRQB Input (Schmitt) Input External Interrupt Request B—The IRQB input is an external interrupt request indicating an external device is requesting service. It can be programmed to be level-sensitive or negative-edge-triggered. Signal Description 56F803 Technical Data, Rev. 15 12 Freescale Semiconductor Pulse Width Modulator (PWM) Signals Table 2-9 Interrupt and Program Control Signals (Continued) No. of Pins Signal Name Signal Type State During Reset 1 RESET Input (Schmitt) Input Signal Description Reset—This input is a direct hardware reset on the processor. When RESET is asserted low, the controller is initialized and placed in the Reset state. A Schmitt trigger input is used for noise immunity. When the RESET pin is deasserted, the initial chip operating mode is latched from the EXTBOOT pin. The internal reset signal will be deasserted synchronous with the internal clocks, after a fixed number of internal clocks. To ensure a complete hardware reset, RESET and TRST should be asserted together. The only exception occurs in a debugging environment when a hardware device reset is required and it is necessary not to reset the OnCE/JTAG module. In this case, assert RESET, but do not assert TRST. 1 EXTBOOT Input (Schmitt) Input External Boot—This input is tied to VDD to force device to boot from off-chip memory. Otherwise, it is tied to VSS. 2.6 Pulse Width Modulator (PWM) Signals Table 2-10 Pulse Width Modulator (PWMA) Signals No. of Pins Signal Name Signal Type State During Reset 6 PWMA0–5 Output Tri-stated 3 ISA0–2 Input (Schmitt) Input ISA0–2— These three input current status pins are used for top/bottom pulse width correction in complementary channel operation for PWMA. 3 FAULTA0–2 Input (Schmitt) Input FAULTA0–2— These three fault input pins are used for disabling selected PWMA outputs in cases where fault conditions originate off-chip. Signal Description PWMA0–5— These are six PWMA output pins. 56F803 Technical Data, Rev. 15 Freescale Semiconductor 13 2.7 Serial Peripheral Interface (SPI) Signals Table 2-11 Serial Peripheral Interface (SPI) Signals No. of Pins Signal Name Signal Type State During Reset 1 MISO Input/Out put Input SPI Master In/Slave Out (MISO)—This serial data pin is an input to a master device and an output from a slave device. The MISO line of a slave device is placed in the high impedance state if the slave device is not selected. GPIOE6 Input/Out put Input Port E GPIO—This General Purpose I/O (GPIO) pin can be individually programmed as an input or output pin. Signal Description After reset, the default state is MISO. 1 MOSI Input/Out put Input GPIOE5 Input/Out put Input SPI Master Out/Slave In (MOSI)—This serial data pin is an output from a master device and an input to a slave device. The master device places data on the MOSI line a half-cycle before the clock edge that the slave device uses to latch the data. Port E GPIO—This General Purpose I/O (GPIO) pin can be individually programmed as an input or output pin. After reset, the default state is MOSI. 1 SCLK Input/Out put Input SPI Serial Clock—In master mode, this pin serves as an output, clocking slaved listeners. In slave mode, this pin serves as the data clock input. GPIOE4 Input/Out put Input Port E GPIO—This General Purpose I/O (GPIO) pin can be individually programmed as an input or output pin. After reset, the default state is SCLK. 1 SS Input Input GPIOE7 Input/Out put Input SPI Slave Select—In master mode, this pin is used to arbitrate multiple masters. In slave mode, this pin is used to select the slave. Port E GPIO—This General Purpose I/O (GPIO) pin can be individually programmed as an input or output pin. After reset, the default state is SS. 56F803 Technical Data, Rev. 15 14 Freescale Semiconductor Quadrature Decoder Signals 2.8 Quadrature Decoder Signals Table 2-12 Quadrature Decoder (Quad Dec0) Signals No. of Pins Signal Name Signal Type State During Reset 1 PHASEA0 Input Input Phase A—Quadrature Decoder #0 PHASEA input TA0 Input/Output Input TA0—Timer A Channel 0 PHASEB0 Input Input Phase B—Quadrature Decoder #0 PHASEB input TA1 Input/Output Input TA1—Timer A Channel 1 INDEX0 Input Input Index—Quadrature Decoder #0 INDEX input TA2 Input/Output Input TA2—Timer A Channel 2 HOME0 Input Input Home—Quadrature Decoder #0 HOME input TA3 Input/Output Input TA3—Timer A Channel 3 1 1 1 Signal Description 2.9 Serial Communications Interface (SCI) Signals Table 2-13 Serial Communications Interface (SCI0) Signals No. of Pins Signal Name Signal Type State During Reset 1 TXD0 Output Input Transmit Data (TXD0)—SCI0 transmit data output GPIOE0 Input/Output Input Port E GPIO—This General Purpose I/O (GPIO) pin can be individually programmed as an input or output pin. Signal Description After reset, the default state is SCI output. 1 RXD0 Input Input Receive Data (RXD0)— SCI0 receive data input GPIOE1 Input/Output Input Port E GPIO—This General Purpose I/O (GPIO) pin can be individually programmed as an input or output pin. After reset, the default state is SCI input. 56F803 Technical Data, Rev. 15 Freescale Semiconductor 15 2.10 CAN Signals Table 2-14 CAN Module Signals No. of Pins Signal Name Signal Type State During Reset 1 MSCAN_ RX Input (Schmitt) Input 1 MSCAN_ TX Output Output Signal Description MSCAN Receive Data—This is the MSCAN input. This pin has an internal pull-up resistor. MSCAN Transmit Data—MSCAN output. CAN output is open-drain output and a pull-up resistor is needed. 2.11 Analog-to-Digital Converter (ADC) Signals Table 2-15 Analog to Digital Converter Signals No. of Pins Signal Name Signal Type State During Reset 4 ANA0–3 Input Input ANA0–3—Analog inputs to ADC channel 1 4 ANA4–7 Input Input ANA4–7—Analog inputs to ADC channel 2 1 VREF Input Input VREF—Analog reference voltage for ADC. Must be set to VDDA-0.3V for optimal performance. Signal Description 2.12 Quad Timer Module Signals Table 2-16 Quad Timer Module Signals No. of Pins Signal Name Signal Type State During Reset 2 TD1–2 Input/Output Input Signal Description TD1–2— Timer D Channel 1–2 56F803 Technical Data, Rev. 15 16 Freescale Semiconductor JTAG/OnCE 2.13 JTAG/OnCE Table 2-17 JTAG/On-Chip Emulation (OnCE) Signals No. of Pins Signal Name Signal Type State During Reset 1 TCK Input Input, pulled low Test Clock Input—This input pin provides a gated clock to synchronize the (Schmitt) internally test logic and shift serial data to the JTAG/OnCE port. The pin is connected internally to a pull-down resistor. 1 TMS Input (Schmitt) Input, pulled high internally Signal Description Test Mode Select Input—This input pin is used to sequence the JTAG TAP controller’s state machine. It is sampled on the rising edge of TCK and has an on-chip pull-up resistor. Note: Always tie the TMS pin to VDD through a 2.2K resistor. 1 TDI Input (Schmitt) Input, pulled high internally Test Data Input—This input pin provides a serial input data stream to the JTAG/OnCE port. It is sampled on the rising edge of TCK and has an on-chip pull-up resistor. 1 TDO Output Tri-stated Test Data Output—This tri-statable output pin provides a serial output data stream from the JTAG/OnCE port. It is driven in the Shift-IR and Shift-DR controller states, and changes on the falling edge of TCK. 1 TRST Input (Schmitt) Input, pulled high internally Test Reset—As an input, a low signal on this pin provides a reset signal to the JTAG TAP controller. To ensure complete hardware reset, TRST should be asserted at power-up and whenever RESET is asserted. The only exception occurs in a debugging environment when a hardware device reset is required and it is necessary not to reset the OnCE/JTAG module. In this case, assert RESET, but do not assert TRST. Note: For normal operation, connect TRST directly to VSS. If the design is to be used in a debugging environment, TRST may be tied to VSS through a 1K resistor. 1 DE Output Output Debug Event—DE provides a low pulse on recognized debug events. Part 3 Specifications 3.1 General Characteristics The 56F803 is fabricated in high-density CMOS with 5-V tolerant TTL-compatible digital inputs. The term “5-V tolerant” refers to the capability of an I/O pin, built on a 3.3V-compatible process technology, to withstand a voltage up to 5.5V without damaging the device. Many systems have a mixture of devices designed for 3.3V and 5V power supplies. In such systems, a bus may carry both 3.3V and 5V-compatible I/O voltage levels (a standard 3.3V I/O is designed to receive a maximum voltage of 3.3V ± 10% during normal operation without causing damage). This 5V-tolerant capability therefore offers the power savings of 3.3V I/O levels while being able to receive 5V levels without being damaged. 56F803 Technical Data, Rev. 15 Freescale Semiconductor 17 Absolute maximum ratings given in Table 3-1 are stress ratings only, and functional operation at the maximum is not guaranteed. Stress beyond these ratings may affect device reliability or cause permanent damage to the device. The 56F803 DC/AC electrical specifications are preliminary and are from design simulations. These specifications may not be fully tested or guaranteed at this early stage of the product life cycle. Finalized specifications will be published after complete characterization and device qualifications have been completed. CAUTION This device contains protective circuitry to guard against damage due to high static voltage or electrical fields. However, normal precautions are advised to avoid application of any voltages higher than maximum rated voltages to this high-impedance circuit. Reliability of operation is enhanced if unused inputs are tied to an appropriate voltage level. Table 3-1 Absolute Maximum Ratings Characteristic Symbol Min Max Unit Supply voltage VDD VSS – 0.3 VSS + 4.0 V All other input voltages, excluding Analog inputs VIN VSS – 0.3 VSS + 5.5V V Voltage difference VDD to VDDA ΔVDD - 0.3 0.3 V Voltage difference VSS to VSSA ΔVSS - 0.3 0.3 V Analog inputs ANA0-7 and VREF VIN VSSA– 0.3 VDDA+ 0.3 V Analog inputs EXTAL and XTAL VIN VSSA– 0.3 VSSA+ 3.0 V I — 10 mA Current drain per pin excluding VDD, VSS, PWM outputs, TCS, VPP, VDDA, VSSA Table 3-2 Recommended Operating Conditions Characteristic Symbol Min Typ Max Unit Supply voltage, digital VDD 3.0 3.3 3.6 V Supply Voltage, analog VDDA 3.0 3.3 3.6 V Voltage difference VDD to VDDA ΔVDD -0.1 - 0.1 V 56F803 Technical Data, Rev. 15 18 Freescale Semiconductor General Characteristics Table 3-2 Recommended Operating Conditions Characteristic Symbol Min Typ Max Unit Voltage difference VSS to VSSA ΔVSS -0.1 - 0.1 V ADC reference voltage VREF 2.7 – VDDA V TA –40 – 85 °C Ambient operating temperature Table 3-3 Thermal Characteristics6 Value Characteristic Comments Symbol Unit Notes 100-pin LQFP Junction to ambient Natural convection Junction to ambient (@1m/sec) RθJA 41.7 °C/W 2 RθJMA 37.2 °C/W 2 Junction to ambient Natural convection Four layer board (2s2p) RθJMA (2s2p) 34.2 °C/W 1,2 Junction to ambient (@1m/sec) Four layer board (2s2p) RθJMA 32 °C/W 1,2 Junction to case RθJC 10.2 °C/W 3 Junction to center of case ΨJT 0.8 °C/W 4, 5 I/O pin power dissipation P I/O User Determined W Power dissipation PD P D = (IDD x VDD + P I/O) W PDMAX (TJ - TA) /RθJA W Junction to center of case 7 Notes: 1. Theta-JA determined on 2s2p test boards is frequently lower than would be observed in an application. Determined on 2s2p thermal test board. 2. Junction to ambient thermal resistance, Theta-JA (RθJA) was simulated to be equivalent to the JEDEC specification JESD51-2 in a horizontal configuration in natural convection. Theta-JA was also simulated on a thermal test board with two internal planes (2s2p where “s” is the number of signal layers and “p” is the number of planes) per JESD51-6 and JESD51-7. The correct name for Theta-JA for forced convection or with the non-single layer boards is Theta-JMA. 3. Junction to case thermal resistance, Theta-JC (RθJC ), was simulated to be equivalent to the measured values using the cold plate technique with the cold plate temperature used as the “case” temperature. The basic cold plate measurement technique is described by MIL-STD 883D, Method 1012.1. This is the correct thermal metric to use to calculate thermal performance when the package is being used with a heat sink. 56F803 Technical Data, Rev. 15 Freescale Semiconductor 19 4. Thermal Characterization Parameter, Psi-JT (ΨJT ), is the “resistance” from junction to reference point thermocouple on top center of case as defined in JESD51-2. ΨJT is a useful value to use to estimate junction temperature in steady state customer environments. 5. Junction temperature is a function of on-chip power dissipation, package thermal resistance, mounting site (board) temperature, ambient temperature, air flow, power dissipation of other components on the board, and board thermal resistance. 6. See Section 5.1 from more details on thermal design considerations. 7. TJ = Junction Temperature TA = Ambient Temperature 3.2 DC Electrical Characteristic Table 3-4 DC Electrical Characteristics Operating Conditions: VSS = VSSA = 0 V, VDD = VDDA = 3.0–3.6 V, TA = –40° to +85°C, CL ≤ 50pF, fop = 80MHz Characteristic Symbol Min Typ Max Unit Input high voltage (XTAL/EXTAL) VIHC 2.25 — 2.75 V Input low voltage (XTAL/EXTAL) VILC 0 — 0.5 V Input high voltage (Schmitt trigger inputs)1 VIHS 2.2 — 5.5 V Input low voltage (Schmitt trigger inputs)1 VILS -0.3 — 0.8 V Input high voltage (all other digital inputs) VIH 2.0 — 5.5 V Input low voltage (all other digital inputs) VIL -0.3 — 0.8 V Input current high (pullup/pulldown resistors disabled, VIN=VDD) IIH -1 — 1 μA Input current low (pullup/pulldown resistors disabled, VIN=VSS) IIL -1 — 1 μA Input current high (with pullup resistor, VIN=VDD) IIHPU -1 — 1 μA Input current low (with pullup resistor, VIN=VSS) IILPU -210 — -50 μA Input current high (with pulldown resistor, VIN=VDD) IIHPD 20 — 180 μA Input current low (with pulldown resistor, VIN=VSS) IILPD -1 — 1 μA Nominal pullup or pulldown resistor value RPU, RPD 30 KΩ Output tri-state current low IOZL -10 — 10 μA Output tri-state current high IOZH -10 — 10 μA 56F803 Technical Data, Rev. 15 20 Freescale Semiconductor DC Electrical Characteristic Table 3-4 DC Electrical Characteristics (Continued) Operating Conditions: VSS = VSSA = 0 V, VDD = VDDA = 3.0–3.6 V, TA = –40° to +85°C, CL ≤ 50pF, fop = 80MHz Characteristic Symbol Min Typ Max Unit Input current high (analog inputs, VIN=VDDA)2 IIHA -15 — 15 μA Input current low (analog inputs, VIN=VSSA)2 IILA -15 — 15 μA Output High Voltage (at IOH) VOH VDD – 0.7 — — V Output Low Voltage (at IOL) VOL — — 0.4 V Output source current IOH 4 — — mA Output sink current IOL 4 — — mA PWM pin output source current3 IOHP 10 — — mA PWM pin output sink current4 IOLP 16 — — mA Input capacitance CIN — 8 — pF Output capacitance COUT — 12 — pF VDD supply current IDDT5 Run 6 — 126 152 mA Wait7 — 105 129 mA Stop — 60 84 mA Low Voltage Interrupt, external power supply8 VEIO 2.4 2.7 3.0 V Low Voltage Interrupt, internal power supply9 VEIC 2.0 2.2 2.4 V Power on Reset10 VPOR — 1.7 2.0 V 1. 1. Schmitt Trigger inputs are: EXTBOOT, IRQA, IRQB, RESET, ISA0-2, FAULTA0-3, TCS, TCK, TRST, TMS, TDI, and MSCAN_RX 2. Analog inputs are: ANA[0:7], XTAL and EXTAL. Specification assumes ADC is not sampling. 3. PWM pin output source current measured with 50% duty cycle. 4. PWM pin output sink current measured with 50% duty cycle. 5. IDDT = IDD + IDDA (Total supply current for VDD + VDDA) 6. Run (operating) IDD measured using 8MHz clock source. All inputs 0.2V from rail; outputs unloaded. All ports configured as inputs; measured with all modules enabled. 7. Wait IDD measured using external square wave clock source (fosc = 8MHz) into XTAL; all inputs 0.2V from rail; no DC loads; less than 50pF on all outputs. CL = 20pF on EXTAL; all ports configured as inputs; EXTAL capacitance linearly affects wait IDD; measured with PLL enabled. 56F803 Technical Data, Rev. 15 Freescale Semiconductor 21 8. This low-voltage interrupt monitors the VDDA external power supply. VDDA is generally connected to the same potential as VDD via separate traces. If VDDA drops below VEIO, an interrupt is generated. Functionality of the device is guaranteed under transient conditions when VDDA>VEIO (between the minimum specified VDD and the point when the VEIO interrupt is generated). 9. This low voltage interrupt monitors the internally regulated core power supply. If the output from the internal voltage is regulator drops below VEIC, an interrupt is generated. Since the core logic supply is internally regulated, this interrupt will not be generated unless the external power supply drops below the minimum specified value (3.0V). 10. Power–on reset occurs whenever the internally regulated 2.5V digital supply drops below 1.5V typical. While power is ramping up, this signal remains active as long as the internal 2.5V is below 1.5V typical, no matter how long the ramp-up rate is. The internally regulated voltage is typically 100mV less than VDD during ramp-up, until 2.5V is reached, at which time it self-regulates. 180 IDD Digital IDD Analog IDD Total 150 IDD (mA) 120 90 60 30 0 20 40 60 80 Freq. (MHz) Figure 3-1 Maximum Run IDD vs. Frequency (see Note 6. in Table 3-14) 3.3 AC Electrical Characteristics Timing waveforms in Section 3.3 are tested using the VIL and VIH levels specified in the DC Characteristics table. In Figure 3-2 the levels of VIH and VIL for an input signal are shown. 56F803 Technical Data, Rev. 15 22 Freescale Semiconductor Flash Memory Characteristics Low VIH Input Signal High 90% 50% 10% Midpoint1 VIL Fall Time Rise Time Note: The midpoint is VIL + (VIH – VIL)/2. Figure 3-2 Input Signal Measurement References Figure 3-3 shows the definitions of the following signal states: • • • Active state, when a bus or signal is driven, and enters a low impedance state Tri-stated, when a bus or signal is placed in a high impedance state Data Valid state, when a signal level has reached VOL or VOH • Data Invalid state, when a signal level is in transition between VOL and VOH Data2 Valid Data1 Valid Data1 Data3 Valid Data2 Data3 Data Tri-stated Data Invalid State Data Active Data Active Figure 3-3 Signal States 3.4 Flash Memory Characteristics Table 3-5 Flash Memory Truth Table XE1 YE2 SE3 OE4 PROG5 ERASE6 MAS17 NVSTR8 Standby L L L L L L L L Read H H H H L L L L Word Program H H L L H L L H Page Erase H L L L L H L H Mass Erase H L L L L H H H Mode 1. X address enable, all rows are disabled when XE = 0 2. Y address enable, YMUX is disabled when YE = 0 3. Sense amplifier enable 4. Output enable, tri-state Flash data out bus when OE = 0 56F803 Technical Data, Rev. 15 Freescale Semiconductor 23 5. Defines program cycle 6. Defines erase cycle 7. Defines mass erase cycle, erase whole block 8. Defines non-volatile store cycle Table 3-6 IFREN Truth Table Mode IFREN = 1 IFREN = 0 Read information block Read main memory block Program information block Program main memory block Page erase Erase information block Erase main memory block Mass erase Erase both block Erase main memory block Read Word program Table 3-7 Flash Timing Parameters Operating Conditions: VSS = VSSA = 0 V, VDD = VDDA = 3.0–3.6V, TA = –40° to +85°C, CL ≤ 50pF Characteristic Symbol Min Typ Max Unit Figure Program time Tprog* 20 – – us Figure 3-4 Erase time Terase* 20 – – ms Figure 3-5 Mass erase time Tme* 100 – – ms Figure 3-6 Endurance1 ECYC 10,000 20,000 – cycles Data Retention1 DRET 10 30 – years The following parameters should only be used in the Manual Word Programming Mode PROG/ERASE to NVSTR set up time Tnv* – 5 – us Figure 3-4, Figure 3-5, Figure 3-6 NVSTR hold time Tnvh* – 5 – us Figure 3-4, Figure 3-5 NVSTR hold time (mass erase) Tnvh1* – 100 – us Figure 3-6 NVSTR to program set up time Tpgs* – 10 – us Figure 3-4 Recovery time Trcv* – 1 – us Figure 3-4, Figure 3-5, Figure 3-6 56F803 Technical Data, Rev. 15 24 Freescale Semiconductor Flash Memory Characteristics Table 3-7 Flash Timing Parameters (Continued) Operating Conditions: VSS = VSSA = 0 V, VDD = VDDA = 3.0–3.6V, TA = –40° to +85°C, CL ≤ 50pF Characteristic Symbol Min Typ Max Unit Figure Cumulative program HV period2 Thv – 3 – ms Figure 3-4 Program hold time3 Tpgh – – – Figure 3-4 Address/data set up time3 Tads – – – Figure 3-4 Address/data hold time3 Tadh – – – Figure 3-4 1. One cycle is equal to an erase program and read. 2. Thv is the cumulative high voltage programming time to the same row before next erase. The same address cannot be programmed twice before next erase. 3. Parameters are guaranteed by design in smart programming mode and must be one cycle or greater. *The Flash interface unit provides registers for the control of these parameters. IFREN XADR XE Tadh YADR YE DIN Tads PROG Tnvs Tprog Tpgh NVSTR Tpgs Tnvh Trcv Thv Figure 3-4 Flash Program Cycle 56F803 Technical Data, Rev. 15 Freescale Semiconductor 25 IFREN XADR XE YE=SE=OE=MAS1=0 ERASE Tnvs NVSTR Tnvh Trcv Terase Figure 3-5 Flash Erase Cycle IFREN XADR XE MAS1 YE=SE=OE=0 ERASE Tnvs NVSTR Tnvh1 Tme Trcv Figure 3-6 Flash Mass Erase Cycle 56F803 Technical Data, Rev. 15 26 Freescale Semiconductor External Clock Operation 3.5 External Clock Operation The 56F803 system clock can be derived from an external crystal or an external system clock signal. To generate a reference frequency using the internal oscillator, a reference crystal must be connected between the EXTAL and XTAL pins. 3.5.1 Crystal Oscillator The internal oscillator is also designed to interface with a parallel-resonant crystal resonator in the frequency range specified for the external crystal in Table 3-9. In Figure 3-7 a recommended crystal oscillator circuit is shown. Follow the crystal supplier’s recommendations when selecting a crystal, because crystal parameters determine the component values required to provide maximum stability and reliable start-up. The crystal and associated components should be mounted as close as possible to the EXTAL and XTAL pins to minimize output distortion and start-up stabilization time. The internal 56F80x oscillator circuitry is designed to have no external load capacitors present. As shown in Figure 3-8 no external load capacitors should be used. The 56F80x components internally are modeled as a parallel resonant oscillator circuit to provide a capacitive load on each of the oscillator pins (XTAL and EXTAL) of 10pF to 13pF over temperature and process variations. Using a typical value of internal capacitance on these pins of 12pF and a value of 3pF as a typical circuit board trace capacitance the parallel load capacitance presented to the crystal is 9pF as determined by the following equation: CL1 * CL2 CL = CL1 + CL2 12 * 12 + Cs = + 3 = 6 + 3 = 9pF 12 + 12 This is the value load capacitance that should be used when selecting a crystal and determining the actual frequency of operation of the crystal oscillator circuit. EXTAL XTAL Rz Recommended External Crystal Parameters: Rz = 1 to 3 MΩ fc = 8MHz (optimized for 8MHz) fc Figure 3-7 Connecting to a Crystal Oscillator 56F803 Technical Data, Rev. 15 Freescale Semiconductor 27 3.5.2 Ceramic Resonator It is also possible to drive the internal oscillator with a ceramic resonator, assuming the overall system design can tolerate the reduced signal integrity. In Figure 3-8, a typical ceramic resonator circuit is shown. Refer to supplier’s recommendations when selecting a ceramic resonator and associated components. The resonator and components should be mounted as close as possible to the EXTAL and XTAL pins. The internal 56F80x oscillator circuitry is designed to have no external load capacitors present. As shown in Figure 3-7 no external load capacitors should be used. EXTAL XTAL Rz Recommended Ceramic Resonator Parameters: Rz = 1 to 3 MΩ fc = 8MHz (optimized for 8MHz) fc Figure 3-8 Connecting a Ceramic Resonator Note: Freescale recommends only two terminal ceramic resonators vs. three terminal resonators (which contain an internal bypass capacitor to ground). 3.5.3 External Clock Source The recommended method of connecting an external clock is given in Figure 3-9. The external clock source is connected to XTAL and the EXTAL pin is grounded. 56F803 XTAL EXTAL External Clock VSS Figure 3-9 Connecting an External Clock Signal 56F803 Technical Data, Rev. 15 28 Freescale Semiconductor External Clock Operation Table 3-8 External Clock Operation Timing Requirements3 Operating Conditions: VSS = VSSA = 0 V, VDD = VDDA = 3.0–3.6 V, TA = –40° to +85°C Characteristic Symbol Min Typ Max Unit Frequency of operation (external clock driver)1 fosc 0 — 80 MHz Clock Pulse Width2, 3 tPW 6.25 — — ns 1. See Figure 3-9 for details on using the recommended connection of an external clock driver. 2. The high or low pulse width must be no smaller than 6.25ns or the chip will not function. 3. Parameters listed are guaranteed by design. VIH External Clock 90% 50% 10% tPW tPW 90% 50% 10% VIL Note: The midpoint is VIL + (VIH – VIL)/2. Figure 3-10 External Clock Timing 56F803 Technical Data, Rev. 15 Freescale Semiconductor 29 3.5.4 Phase Locked Loop Timing Table 3-9 PLL Timing Operating Conditions: VSS = VSSA = 0 V, VDD = VDDA = 3.0–3.6 V, TA = –40° to +85°C Characteristic Symbol Min Typ Max Unit fosc 4 8 10 MHz fout/2 40 — 110 MHz PLL stabilization time 3 0o to +85oC tplls — 1 10 ms PLL stabilization time3 -40o to 0oC tplls — 100 200 ms External reference crystal frequency for the PLL1 PLL output frequency 2 1. An externally supplied reference clock should be as free as possible from any phase jitter for the PLL to work correctly. The PLL is optimized for 8MHz input crystal. 2. ZCLK may not exceed 80MHz. For additional information on ZCLK and fout/2, please refer to the OCCS chapter in the User Manual. ZCLK = fop 3. This is the minimum time required after the PLL set-up is changed to ensure reliable operation. 3.6 External Bus Asynchronous Timing Table 3-10 External Bus Asynchronous Timing1, 2 Operating Conditions: VSS = VSSA = 0 V, VDD = VDDA = 3.0–3.6 V, TA = –40° to +85°C, CL ≤ 50pF, fop = 80MHz Characteristic Symbol Min Max Unit Address Valid to WR Asserted tAWR 6.5 — ns WR Width Asserted Wait states = 0 Wait states > 0 tWR 7.5 (T*WS) + 7.5 — — ns ns WR Asserted to D0–D15 Out Valid tWRD — 4.2 ns Data Out Hold Time from WR Deasserted tDOH 4.8 — ns Data Out Set Up Time to WR Deasserted Wait states = 0 Wait states > 0 tDOS 2.2 (T*WS) + 6.4 — — ns ns RD Deasserted to Address Not Valid tRDA 0 — ns Address Valid to RD Deasserted Wait states = 0 Wait states > 0 tARDD — 18.7 (T*WS) + 18.7 ns ns 56F803 Technical Data, Rev. 15 30 Freescale Semiconductor External Bus Asynchronous Timing Table 3-10 External Bus Asynchronous Timing1, 2 (Continued) Operating Conditions: VSS = VSSA = 0 V, VDD = VDDA = 3.0–3.6 V, TA = –40° to +85°C, CL ≤ 50pF, fop = 80MHz Characteristic Symbol Min Max Unit Input Data Hold to RD Deasserted tDRD 0 — ns RD Assertion Width Wait states = 0 Wait states > 0 tRD 19 (T*WS) + 19 — — ns ns Address Valid to Input Data Valid Wait states = 0 Wait states > 0 tAD — — 1 (T*WS) + 1 ns ns -4.4 — ns — — 2.4 (T*WS) + 2.4 ns ns Address Valid to RD Asserted tARDA RD Asserted to Input Data Valid Wait states = 0 Wait states > 0 tRDD WR Deasserted to RD Asserted tWRRD 6.8 — ns RD Deasserted to RD Asserted tRDRD 0 — ns WR Deasserted to WR Asserted tWRWR 14.1 — ns RD Deasserted to WR Asserted tRDWR 12.8 — ns 56F803 Technical Data, Rev. 15 Freescale Semiconductor 31 1. Timing is both wait state and frequency dependent. In the formulas listed, WS = the number of wait states and T = Clock Period. For 80MHz operation, T = 12.5ns. 2. Parameters listed are guaranteed by design. To calculate the required access time for an external memory for any frequency < 80Mhz, use this formula: Top = Clock period @ desired operating frequency WS = Number of wait states Memory Access Time = (Top*WS) + (Top- 11.5) A0–A15, PS, DS (See Note) tARDD tRDA tARDA RD tRDRD tRD tAWR tWRWR tWRRD tWR tRDWR WR tRDD tAD tWRD tDRD tDOS tDOH Data In Data Out D0–D15 Note: During read-modify-write instructions and internal instructions, the address lines do not change state. Figure 3-11 External Bus Asynchronous Timing 3.7 Reset, Stop, Wait, Mode Select, and Interrupt Timing Table 3-11 Reset, Stop, Wait, Mode Select, and Interrupt Timing 1, 5 Operating Conditions: VSS = VSSA = 0 V, VDD = VDDA = 3.0–3.6V, TA = –40° to +85°C, CL ≤ 50pF Characteristic Symbol Min Max Unit See Figure RESET Assertion to Address, Data and Control Signals High Impedance tRAZ — 21 ns Figure 3-12 Minimum RESET Assertion Duration2 OMR Bit 6 = 0 OMR Bit 6 = 1 tRA 275,000T 128T — — ns ns RESET De-assertion to First External Address Output tRDA 33T 34T ns Figure 3-12 Figure 3-12 56F803 Technical Data, Rev. 15 32 Freescale Semiconductor Reset, Stop, Wait, Mode Select, and Interrupt Timing Table 3-11 Reset, Stop, Wait, Mode Select, and Interrupt Timing (Continued)1, 5 Operating Conditions: VSS = VSSA = 0 V, VDD = VDDA = 3.0–3.6V, TA = –40° to +85°C, CL ≤ 50pF Characteristic Symbol Min Max Unit See Figure Edge-sensitive Interrupt Request Width tIRW 1.5T — ns Figure 3-13 IRQA, IRQB Assertion to External Data Memory Access Out Valid, caused by first instruction execution in the interrupt service routine tIDM 15T — ns Figure 3-14 IRQA, IRQB Assertion to General Purpose Output Valid, caused by first instruction execution in the interrupt service routine tIG 16T — ns Figure 3-14 IRQA Low to First Valid Interrupt Vector Address Out recovery from Wait State3 tIRI 13T — ns Figure 3-15 IRQA Width Assertion to Recover from Stop State4 tIW 2T — ns Figure 3-16 Delay from IRQA Assertion to Fetch of first instruction (exiting Stop) OMR Bit 6 = 0 OMR Bit 6 = 1 tIF Duration for Level Sensitive IRQA Assertion to Cause the Fetch of First IRQA Interrupt Instruction (exiting Stop) OMR Bit 6 = 0 OMR Bit 6 = 1 tIRQ Delay from Level Sensitive IRQA Assertion to First Interrupt Vector Address Out Valid (exiting Stop) OMR Bit 6 = 0 OMR Bit 6 = 1 Figure 3-16 — — 275,000T 12T ns ns Figure 3-17 — — 275,000T 12T ns ns Figure 3-17 tII — — 275,000T 12T ns ns 1. In the formulas, T = clock cycle. For an operating frequency of 80MHz, T = 12.5ns. 2. Circuit stabilization delay is required during reset when using an external clock or crystal oscillator in two cases: • After power-on reset • When recovering from Stop state 3. The minimum is specified for the duration of an edge-sensitive IRQA interrupt required to recover from the Stop state. This is not the minimum required so that the IRQA interrupt is accepted. 4. The interrupt instruction fetch is visible on the pins only in Mode 3. 5. Parameters listed are guaranteed by design. 56F803 Technical Data, Rev. 15 Freescale Semiconductor 33 RESET tRA tRAZ tRDA A0–A15, D0–D15 First Fetch PS, DS, RD, WR First Fetch Figure 3-12 Asynchronous Reset Timing IRQA, IRQB tIRW Figure 3-13 External Interrupt Timing (Negative-Edge-Sensitive) 56F803 Technical Data, Rev. 15 34 Freescale Semiconductor Reset, Stop, Wait, Mode Select, and Interrupt Timing A0–A15, PS, DS, RD, WR First Interrupt Instruction Execution tIDM IRQA, IRQB a) First Interrupt Instruction Execution General Purpose I/O Pin tIG IRQA, IRQB b) General Purpose I/O Figure 3-14 External Level-Sensitive Interrupt Timing IRQA, IRQB tIRI A0–A15, PS, DS, RD, WR First Interrupt Vector Instruction Fetch Figure 3-15 Interrupt from Wait State Timing tIW IRQA tIF A0–A15, PS, DS, RD, WR First Instruction Fetch Not IRQA Interrupt Vector Figure 3-16 Recovery from Stop State Using Asynchronous Interrupt Timing 56F803 Technical Data, Rev. 15 Freescale Semiconductor 35 tIRQ IRQA tII A0–A15 PS, DS, RD, WR First IRQA Interrupt Instruction Fetch Figure 3-17 Recovery from Stop State Using IRQA Interrupt Service 3.8 Serial Peripheral Interface (SPI) Timing Table 3-12 SPI Timing1 Operating Conditions: VSS = VSSA = 0 V, VDD = VDDA = 3.0–3.6V, TA = –40° to +85°C, CL ≤ 50pF, fOP = 80MHz Characteristic Symbol Cycle time Master Slave Min Max Unit 50 25 — — ns ns — 25 — — ns ns — 100 — — ns ns 17.6 12.5 — — 24.1 25 — — ns ns 20 0 — — ns ns 0 2 — — ns ns 4.8 15 ns 3.7 15.2 ns tC Enable lead time Master Slave tELD Enable lag time Master Slave tELG Clock (SCLK) high time Master Slave tCH Clock (SCLK) low time Master Slave tCL Data set-up time required for inputs Master Slave tDS Data hold time required for inputs Master Slave tDH Access time (time to data active from high-impedance state) Slave tA Disable time (hold time to high-impedance state) Slave tD See Figure Figures 3-18, , 3-20, 3-21 Figure 3-21 Figure 3-21 ns ns Figures 3-18, , 3-20, 3-21 Figures 3-18, , 3-20, 3-21 Figures 3-18, , 3-20, 3-21 Figures 3-18, , 3-20, 3-21 Figure 3-21 Figure 3-21 56F803 Technical Data, Rev. 15 36 Freescale Semiconductor Serial Peripheral Interface (SPI) Timing Table 3-12 SPI Timing1 Operating Conditions: VSS = VSSA = 0 V, VDD = VDDA = 3.0–3.6V, TA = –40° to +85°C, CL ≤ 50pF, fOP = 80MHz Characteristic Symbol Data Valid for outputs Master Slave (after enable edge) tDV Data invalid Master Slave tDI Rise time Master Slave tR Fall time Master Slave tF Min Max Unit — — 4.5 20.4 ns ns 0 0 — — ns ns — — 11.5 10.0 ns ns — — 9.7 9.0 ns ns See Figure Figures 3-18, , 3-20, 3-21 Figures 3-18, , 3-20, 3-21 Figures 3-18, , 3-20, 3-21 Figures 3-18, , 3-20, 3-21 1. Parameters listed are guaranteed by design. SS SS is held High on master (Input) tC tR tF tCL SCLK (CPOL = 0) (Output) tCH tF tR tCL SCLK (CPOL = 1) (Output) tDH tCH tDS MISO (Input) MSB in Bits 14–1 tDI MOSI (Output) Master MSB out LSB in tDV Bits 14–1 tF tDI(ref) Master LSB out tR Figure 3-18 SPI Master Timing (CPHA = 0) 56F803 Technical Data, Rev. 15 Freescale Semiconductor 37 SS (Input) SS is held High on master tC tF tR tCL SCLK (CPOL = 0) (Output) tCH tF tCL SCLK (CPOL = 1) (Output) tCH tDS tDH tR MISO (Input) MSB in tDI tDV(ref) MOSI (Output) Bits 14–1 Master MSB out LSB in tDV Bits 14– 1 tF Master LSB out tR Figure 3-19 SPI Master Timing (CPHA = 1) 56F803 Technical Data, Rev. 15 38 Freescale Semiconductor Serial Peripheral Interface (SPI) Timing SS (Input) tC tF tCL SCLK (CPOL = 0) (Input) tELG tR tCH tELD tCL SCLK (CPOL = 1) (Input) tCH tA MISO (Output) Slave MSB out Bits 14–1 tDS tDV tDH MOSI (Input) MSB in tF tR Bits 14–1 tD Slave LSB out tDI tDI LSB in Figure 3-20 SPI Slave Timing (CPHA = 0) 56F803 Technical Data, Rev. 15 Freescale Semiconductor 39 SS (Input) tC tF tR tCL SCLK (CPOL = 0) (Input) tCH tELD SCLK (CPOL = 1) (Input) tDV tELG tCL tCH tR tD tF tA MISO (Output) Slave MSB out Bits 14–1 Slave LSB out tDV tDS tDI tDH MOSI (Input) MSB in Bits 14–1 LSB in Figure 3-21 SPI Slave Timing (CPHA = 1) 3.9 Quad Timer Timing Table 3-13 Timer Timing1, 2 Operating Conditions: VSS = VSSA = 0 V, VDD = VDDA = 3.0–3.6V, TA = –40° to +85°C, CL ≤ 50pF, fOP = 80MHz Characteristic Symbol Min Max Unit PIN 4T+6 — ns Timer input high/low period PINHL 2T+3 — ns Timer output period POUT 2T — ns Timer input period 56F803 Technical Data, Rev. 15 40 Freescale Semiconductor Quadrature Decoder Timing Table 3-13 Timer Timing1, 2 Operating Conditions: VSS = VSSA = 0 V, VDD = VDDA = 3.0–3.6V, TA = –40° to +85°C, CL ≤ 50pF, fOP = 80MHz Timer output high/low period 1. POUTHL 1T — ns In the formulas listed, T = clock cycle. For 80MHz operation, T = 12.5ns. 2. Parameters listed are guaranteed by design. Timer Inputs PIN PINHL PINHL Timer Outputs POUT POUTHL POUTHL Figure 3-22 Timer Timing 3.10 Quadrature Decoder Timing Table 3-14 Quadrature Decoder Timing1,2 Operating Conditions: VSS = VSSA = 0 V, VDD = VDDA = 3.0–3.6V, TA = –40° to +85°C, CL ≤ 50pF, fOP = 80MHz Characteristic Symbol Min Max Unit Quadrature input period PIN 8T+12 — ns Quadrature input high/low period PHL 4T+6 — ns Quadrature phase period PPH 2T+3 — ns 1. In the formulas listed, T = clock cycle. For 80MHz operation, T = 12. ns. VSS = 0 V, VDD = 3.0 – 3.6V, TA = –40° to +85°C, CL ≤ 50pF. 2. Parameters listed are guaranteed by design. 56F803 Technical Data, Rev. 15 Freescale Semiconductor 41 PPH PPH PPH PPH Phase A (Input) PIN PHL PHL Phase B (Input) PIN PHL PHL Figure 3-23 Quadrature Decoder Timing 3.11 Serial Communication Interface (SCI) Timing Table 3-15 SCI Timing4 Operating Conditions: VSS = VSSA = 0 V, VDD = VDDA = 3.0–3.6 V, TA = –40° to +85°C, CL ≤ 50pF, fOP = 80MHz Characteristic Symbol Min Max Unit BR — (fMAX*2.5)/(80) Mbps RXD2 Pulse Width RXDPW 0.965/BR 1.04/BR ns TXD3 Pulse Width TXDPW 0.965/BR 1.04/BR ns Baud Rate1 1. fMAX is the frequency of operation of the system clock in MHz. 2. The RXD pin in SCI0 is named RXD0 and the RXD pin in SCI1 is named RXD1. 3. The TXD pin in SCI0 is named TXD0 and the TXD pin in SCI1 is named TXD1. 4. Parameters listed are guaranteed by design. RXD SCI receive data pin (Input) RXDPW Figure 3-24 RXD Pulse Width 56F803 Technical Data, Rev. 15 42 Freescale Semiconductor Analog-to-Digital Converter (ADC) Characteristics TXD SCI receive data pin (Input) TXDPW Figure 3-25 TXD Pulse Width 3.12 Analog-to-Digital Converter (ADC) Characteristics Table 3-16 ADC Characteristics Characteristic Symbol Min Typ Max Unit VADCIN 01 — VREF2 V Resolution RES 12 — 12 Bits Integral Non-Linearity3 INL — +/- 2.5 +/- 4 LSB4 Differential Non-Linearity DNL — +/- 0.9 +/- 1 LSB4 ADC input voltages Monotonicity GUARANTEED ADC internal clock5 fADIC 0.5 — 5 MHz Conversion range RAD VSSA — VDDA V Power-up time tADPU — 16 — tAIC cycles6 Conversion time tADC — 6 — tAIC cycles6 Sample time tADS — 1 — tAIC cycles6 Input capacitance CADI — 5 — pF6 Gain Error (transfer gain)5 EGAIN 0.95 1.00 1.10 — VOFFSET -80 -15 +20 mV THD 60 64 — dB Signal-to-Noise plus Distortion5 SINAD 55 60 — dB Effective Number of Bits5 ENOB 9 10 — bit Spurious Free Dynamic Range5 SFDR 65 70 — dB BW — 100 — KHz Offset Voltage5 Total Harmonic Distortion5 Bandwidth 56F803 Technical Data, Rev. 15 Freescale Semiconductor 43 Table 3-16 ADC Characteristics Characteristic Symbol Min Typ Max Unit ADC Quiescent Current (both ADCs) IADC — 50 — mA VREF Quiescent Current (both ADCs) IVREF — 12 16.5 mA 1. For optimum ADC performance, keep the minimum VADCIN value > 25mV. Inputs less than 25mV may convert to a digital output code of 0. 2. VREF must be equal to or less than VDDA and must be greater than 2.7V. For optimal ADC performance, set VREF to VDDA-0.3V. 3. Measured in 10-90% range. 4. LSB = Least Significant Bit. 5. Guaranteed by characterization. 6. tAIC = 1/fADIC 3 ADC analog input 1 2 4 1. Parasitic capacitance due to package, pin to pin, and pin to package base coupling. (1.8pf) 2. Parasitic capacitance due to the chip bond pad, ESD protection devices and signal routing. (2.04pf) 3. Equivalent resistance for the ESD isolation resistor and the channel select mux. (500 ohms) 4. Sampling capacitor at the sample and hold circuit. (1pf) Figure 3-26 Equivalent Analog Input Circuit 3.13 Controller Area Network (CAN) Timing Table 3-17 CAN Timing2 Operating Conditions: VSS = VSSA = 0 V, VDD = VDDA = 3.0–3.6 V, TA = –40× to +85×C, CL £ 50pF, MSCAN Clock = 30MHz Characteristic Baud Rate Bus Wakeup detection 1 Symbol Min Max Unit BRCAN — 1 Mbps T WAKEUP 5 — μs 56F803 Technical Data, Rev. 15 44 Freescale Semiconductor Controller Area Network (CAN) Timing 1. If Wakeup glitch filter is enabled during the design initialization and also CAN is put into SLEEP mode then, any bus event (on MSCAN_RX pin) whose duration is less than 5 micro seconds is filtered away. However, a valid CAN bus wakeup detection takes place for a wakeup pulse equal to or greater than 5 microseconds. The value of 5 microseconds originates from the fact that the CAN wakeup message consists of 5 dominant bits at the highest possible baud rate of 1Mbps. 2. Parameters listed are guaranteed by design. MSCAN_RX CAN receive data pin (Input) T WAKEUP Figure 3-27 Bus Wakeup Detection 56F803 Technical Data, Rev. 15 Freescale Semiconductor 45 3.14 JTAG Timing Table 3-18 JTAG Timing1, 3 Operating Conditions: VSS = VSSA = 0 V, VDD = VDDA = 3.0–3.6 V, TA = –40° to +85°C, CL ≤ 50pF, fOP = 80MHz Characteristic Symbol Min Max Unit TCK frequency of operation2 fOP DC 10 MHz TCK cycle time tCY 100 — ns TCK clock pulse width tPW 50 — ns TMS, TDI data set-up time tDS 0.4 — ns TMS, TDI data hold time tDH 1.2 — ns TCK low to TDO data valid tDV — 26.6 ns TCK low to TDO tri-state tTS — 23.5 ns tTRST 50 — ns tDE 4T — ns TRST assertion time DE assertion time 1. Timing is both wait state and frequency dependent. For the values listed, T = clock cycle. For 80MHz operation, T = 12.5ns. 2. TCK frequency of operation must be less than 1/8 the processor rate. 3. Parameters listed are guaranteed by design. tCY tPW tPW VM VM VIH TCK (Input) VM = VIL + (VIH – VIL)/2 VIL Figure 3-28 Test Clock Input Timing Diagram 56F803 Technical Data, Rev. 15 46 Freescale Semiconductor JTAG Timing TCK (Input) tDS TDI TMS (Input) tDH Input Data Valid tDV TDO (Output) Output Data Valid tTS TDO (Output) tDV TDO (Output) Output Data Valid Figure 3-29 Test Access Port Timing Diagram TRST (Input) tTRST Figure 3-30 TRST Timing Diagram DE tDE Figure 3-31 OnCE—Debug Event 56F803 Technical Data, Rev. 15 Freescale Semiconductor 47 Part 4 Packaging 4.1 Package and Pin-Out Information 56F803 D9 D8 D7 D6 D5 D4 D3 VSS VDD D2 D1 D0 VCAPC SCLK MOSI MISO SS TD2 TD1 CLKO DE RESET EXTBOOT RXD0 TXD0 This section contains package and pin-out information for the 100-pin LQFP configuration of the 56F803. PIN 76 PIN 1 ORIENTATION MARK PIN 51 PIN 26 PWMA5 PWMA4 PWMA3 PWMA2 PWMA1 PWMA0 HOME0 INDEX0 VSS VDD PHASEB0 PHASEA0 VSS VDD VDD VDDA VSSA EXTAL XTAL AN7 AN6 AN5 AN4 AN3 AN2 A14 A15 VSS WR RD IRQA IRQB TCS TCK TMS TDI TDO TRST VCAPC ISA0 ISA1 ISA2 FAULTA0 MSCAN_TX FAULTA1 MSCAN_RX FAULTA2 VREF AN0 AN1 D10 D11 D12 D13 D14 D15 A0 VDD VSS A1 A2 A3 A4 A5 A6 A7 A8 A9 A10 A11 A12 A13 VDD PS DS Figure 4-1 Top View, 56F803 100-pin LQFP Package 56F803 Technical Data, Rev. 15 48 Freescale Semiconductor Package and Pin-Out Information 56F803 Table 4-1 56F803 Pin Identification By Pin Number Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name 1 D10 26 A14 51 AN2 76 TXD0 2 D11 27 A15 52 AN3 77 RXD0 3 D12 28 VSS 53 AN4 78 EXTBOOT 4 D13 29 WR 54 AN5 79 RESET 5 D14 30 RD 55 AN6 80 DE 6 D15 31 IRQA 56 AN7 81 CLKO 7 A0 32 IRQB 57 XTAL 82 TD1 8 VDD 33 TCS 58 EXTAL 83 TD2 9 VSS 34 TCK 59 VSSA 84 SS 10 A1 35 TMS 60 VDDA 85 MISO 11 A2 36 TDI 61 VDD 86 MOSI 12 A3 37 TDO 62 VDD 87 SCLK 13 A4 38 TRST 63 VSS 88 VCAPC 14 A5 39 VCAPC 64 PHASEA0 89 D0 15 A6 40 ISA0 65 PHASEB0 90 D1 16 A7 41 ISA1 66 VDD 91 D2 17 A8 42 ISA2 67 VSS 92 VDD 18 A9 43 FAULTA0 68 INDEX0 93 VSS 19 A10 44 MSCAN_TX 69 HOME0 94 D3 20 A11 45 FAULTA1 70 PWMA0 95 D4 21 A12 46 MSCAN_RX 71 PWMA1 96 D5 22 A13 47 FAULTA2 72 PWMA2 97 D6 23 VDD 48 VREF 73 PWMA3 98 D7 24 PS 49 AN0 74 PWMA4 99 D8 25 DS 50 AN1 75 PWMA5 100 D9 56F803 Technical Data, Rev. 15 Freescale Semiconductor 49 S 0.15 (0.006) S AC T-U Z S S -T- B 0.15 0.15 (0.006) S AC Z -Z- (0.006) S V AC Z S S T-U T-U S S NOTES: 1. DIMENSIONING AND TOLERANCING PER ANSI Y14.5M, 1982. 2. CONTROLLING DIMENSION: MILLIMETER. 3. DATUM PLANE -AB- IS LOCATED AT BOTTOM OF LEAD AND IS COINCIDENT WITH THE LEAD WHERE THE LEAD EXITS THE PLASTIC BODY AT THE BOTTOM OF THE PARTING LINE. 4. DATUMS -T-, -U-, AND -Z- TO BE DETERMINED AT DATUM PLANE -AB-. 5. DIMENSIONS S AND V TO BE DETERMINED AT SEATING PLANE -AC-. 6. DIMENSIONS A AND B DO NOT INCLUDE MOLD PROTRUSION. ALLOWABLE PROTRUSION IS 0.250 (0.010) PER SIDE. DIMENSIONS A AND B DO INCLUDE MOLD MISMATCH AND ARE DETERMINED AT DATUM PLANE -AB-. 7. DIMENSION D DOES NOT INCLUDE DAMBAR PROTRUSION. DAMBAR PROTRUSION SHALL NOT CAUSE THE D DIMENSION TO EXCEED 0.350 (0.014). DAMBAR CAN NOT BE LOCATED ON THE LOWER RADIUS OR THE FOOT. MINIMUM SPACE BETWEEN PROTRUSION AND AN ADJACENT LEAD IS 0.070 (0.003). 8. MINIMUM SOLDER PLATE THICKNESS SHALL BE 0.0076 (0.003). 9. EXACT SHAPE OF EACH CORNER MAY VARY FROM DEPICTION. -UA 9 0.15 (0.006) S AB T-U S AE Z MILLIMETERS DIM MIN MAX A 13.950 14.050 B 13.950 14.050 C 1.400 1.600 D 0.170 0.270 E 1.350 1.450 F 0.170 0.230 G 0.500 BSC H 0.050 0.150 J 0.090 0.200 K 0.500 0.700 M 12° REF N 0.090 0.160 Q 1° 5° R 0.150 0.250 S 15.950 16.050 V 15.950 16.050 W 0.200 REF X 1.000 REF S AD -AB-AC96X G SEATING PLANE (24X PER SIDE) AE 0.100 (0.004) AC M° C R 0.25 (0.010) E GAUGE PLANE D F J N H INCHES MIN MAX 0.549 0.553 0.549 0.553 0.055 0.063 0.007 0.011 0.053 0.057 0.007 0.009 0.020 BSC 0.002 0.006 0.004 0.008 0.020 0.028 12° REF 0.004 0.006 1° 5° 0.006 0.010 0.628 0.632 0.628 0.632 0.008 REF 0.039 REF Q° W K X 0.20 (0.008) M AC T-U S Z S SECTION AE-AE DETAIL AD Figure 4-2 100-pin LQPF Mechanical Information 56F803 Technical Data, Rev. 15 50 Freescale Semiconductor Thermal Design Considerations Please see www.freescale.com for the most current case outline. Part 5 Design Considerations 5.1 Thermal Design Considerations An estimation of the chip junction temperature, TJ, in °C can be obtained from the equation: Equation 1: TJ = T A + ( P D × RθJA ) Where: TA = ambient temperature °C RθJA = package junction-to-ambient thermal resistance °C/W PD = power dissipation in package Historically, thermal resistance has been expressed as the sum of a junction-to-case thermal resistance and a case-to-ambient thermal resistance: Equation 2: RθJA = R θJC + R θCA Where: RθJA = package junction-to-ambient thermal resistance °C/W RθJC = package junction-to-case thermal resistance °C/W RθCA = package case-to-ambient thermal resistance °C/W RθJC is device-related and cannot be influenced by the user. The user controls the thermal environment to change the case-to-ambient thermal resistance, RθCA. For example, the user can change the air flow around the device, add a heat sink, change the mounting arrangement on the Printed Circuit Board (PCB), or otherwise change the thermal dissipation capability of the area surrounding the device on the PCB. This model is most useful for ceramic packages with heat sinks; some 90% of the heat flow is dissipated through the case to the heat sink and out to the ambient environment. For ceramic packages, in situations where the heat flow is split between a path to the case and an alternate path through the PCB, analysis of the device thermal performance may need the additional modeling capability of a system level thermal simulation tool. The thermal performance of plastic packages is more dependent on the temperature of the PCB to which the package is mounted. Again, if the estimations obtained from RθJA do not satisfactorily answer whether the thermal performance is adequate, a system level model may be appropriate. Definitions: A complicating factor is the existence of three common definitions for determining the junction-to-case thermal resistance in plastic packages: • Measure the thermal resistance from the junction to the outside surface of the package (case) closest to the chip mounting area when that surface has a proper heat sink. This is done to minimize temperature variation 56F803 Technical Data, Rev. 15 Freescale Semiconductor 51 How to Reach Us: Home Page: www.freescale.com E-mail: [email protected] USA/Europe or Locations Not Listed: Freescale Semiconductor Technical Information Center, CH370 1300 N. Alma School Road Chandler, Arizona 85224 +1-800-521-6274 or +1-480-768-2130 [email protected] Europe, Middle East, and Africa: Freescale Halbleiter Deutschland GmbH Technical Information Center Schatzbogen 7 81829 Muenchen, Germany +44 1296 380 456 (English) +46 8 52200080 (English) +49 89 92103 559 (German) +33 1 69 35 48 48 (French) [email protected] Japan: Freescale Semiconductor Japan Ltd. Headquarters ARCO Tower 15F 1-8-1, Shimo-Meguro, Meguro-ku, Tokyo 153-0064, Japan 0120 191014 or +81 3 5437 9125 [email protected] Asia/Pacific: Freescale Semiconductor Hong Kong Ltd. Technical Information Center 2 Dai King Street Tai Po Industrial Estate Tai Po, N.T., Hong Kong +800 2666 8080 [email protected] For Literature Requests Only: Freescale Semiconductor Literature Distribution Center P.O. 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Freescale™ and the Freescale logo are trademarks of Freescale Semiconductor, Inc. All other product or service names are the property of their respective owners. This product incorporates SuperFlash® technology licensed from SST. © Freescale Semiconductor, Inc. 2005. All rights reserved. DSP56F803 Rev. 15 01/2007