FREESCALE DSP56855E

56855
Data Sheet
Technical Data
56800E
16-bit Digital Signal Controllers
DSP56855
Rev. 6
01/2007
freescale.com
56855 General Description
• 120 MIPS at 120MHz
• Two (2) Serial Communication Interfaces (SCI)
• 24K x 16-bit Program SRAM
• General Purpose 16-bit Quad Timer with 1 external pin
• 24K x 16-bit Data SRAM
• 1K x 16-bit Boot ROM
• JTAG/Enhanced On-Chip Emulation (OnCE™) for
unobtrusive, real-time debugging
• Access up to 2M words of program memory or 8M
words of data memory
• Computer Operating Properly (COP)/Watchdog Timer
• Time-of-Day (TOD)
• Chip Select Logic for glueless interface to ROM and
SRAM
• 100 LQFP package
• Up to 18 GPIO
• Six (6) independent channels of DMA
• Enhanced Synchronous Serial Interface (ESSI)
6
JTAG/
Enhanced
OnCE
Program Controller
and
Hardware Looping Unit
VDDIO
VDD
10
4
VSSIO
10
VSS VDDA
VSSA
4
16-Bit
DSP56800E Core
Address
Generation Unit
Data ALU
16 x 16 + 36 → 36-Bit MAC
Three 16-bit Input Registers
Four 36-bit Accumulators
Bit
Manipulation
Unit
PAB
PDB
CDBR
CDBW
Boot ROM
1024 x 16 ROM
Data Memory
24,576 x 16 SRAM
XDB2
XAB1
System
Bus
Control
XAB2
PAB
PDB
CDBR
DMA
6 channel
Core CLK
CDBW
DMA Requests
Memory
Program Memory
24,576 x 16 SRAM
A0-20 [20:0]
D0-D15 [15:0]
IPBus CLK
External Data
Bus Switch
Bus Control
CS0-CS3[3:0] or
GPIOA0-GPIOA3[3:0]
CLKO
POR
3
System
COP/TOD CLK Integration
Module
External Address
Bus Switch
RD Enable
WR Enable
IPRDB
Decoding
Peripherals
IPWDB
IPAB
IPBus Bridge (IPBB)
MODEA-C or
(GPIOH0-H2)
RSTO
RESET
External Bus
Interface Unit
2 SCI ESSI0
or
or
GPIOE GPIOC
4
6
Quad
Timer
or
GPIOG
Interrupt
Controller
COP/
Watchdog
Time
of
Day
Clock
Generator
EXTAL
XTAL
OSC PLL
IRQA
IRQB
56855 Block Diagram
56855 Technical Data, Rev. 6
Freescale Semiconductor
3
Part 1 Overview
1.1 56855 Features
1.1.1
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1.1.2
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Core
Efficient 16-bit engine with dual Harvard architecture
120 Million Instructions Per Second (MIPS) at 120MHz core frequency
Single-cycle 16 × 16-bit parallel Multiplier-Accumulator (MAC)
Four (4) 36-bit accumulators including extension bits
16-bit bidirectional shifter
Parallel instruction set with unique DSP addressing modes
Hardware DO and REP loops
Three (3) internal address buses and one (1) external address bus
Four (4) internal data buses and one (1) external data bus
Instruction set supports both DSP and controller functions
Four (4) hardware interrupt levels
Five (5) software interrupt levels
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/Enhanced OnCE debug programming interface
Memory
Harvard architecture permits up to three (3) simultaneous accesses to program and data memory
On-Chip Memory
— 24K × 16-bit Program SRAM
— 24K × 16-bit Data SRAM
— 1K × 16-bit Boot ROM
•
Off-Chip Memory Expansion (EMI)
— Access up to 2M words of program memory or 8M words of data memory
— Chip Select Logic for glue-less interface to ROM and SRAM
1.1.3
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•
•
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Peripheral Circuits for 56855
General Purpose 16-bit Quad Timer with 1 external pin*
Two (2) Serial Communication Interfaces (SCI)*
Enhanced Synchronous Serial Interface (ESSI) module*
Computer Operating Properly (COP)/Watchdog Timer
JTAG/Enhanced On-Chip Emulation (EOnCE) for unobtrusive, real-time debugging
56855 Technical Data, Rev. 6
4
Freescale Semiconductor
56855 Description
•
•
•
Six (6) independent channels of DMA
Time-of-Day (TOD)
Up to 18 GPIO
* Each peripheral I/O can be used alternately as a General Purpose I/O if not needed
1.1.4
•
•
Energy Information
Fabricated in high-density CMOS with 3.3V, TTL-compatible digital inputs
Wait and Stop modes available
1.2 56855 Description
The 56855 is a member of the 56800E core-based family of controllers. It combines, on a single chip, the
processing power of a Digital Signal Processor (DSP) and the functionality of a microcontroller with a
flexible set of peripherals, creating an extremely cost-effective solution. Because of its low cost,
configuration flexibility, and compact program code, the 56855 is well-suited for many applications. The
56855 includes many peripherals that are especially useful for low-end Internet appliance applications
and low-end client applications such as telephony; portable devices; Internet audio; and point-of-sale
systems, such as noise suppression; ID tag readers; sonic/subsonic detectors; security access devices;
remote metering; sonic alarms.
The 56800E 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 microprocessor-style programming
model and optimized instruction set allow straightforward generation of efficient, compact code for both
DSP and MCU applications. The instruction set is also highly efficient for C Compilers, enabling rapid
development of optimized control applications.
The 56855 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 56855 also provides two external
dedicated interrupt lines, and up to 18 General Purpose Input/Output (GPIO) lines, depending on
peripheral configuration.
The 56855 controller includes 24K words of Program RAM, 24K words of Data RAM and 1K of Boot
ROM. It also supports program execution from external memory.
This controller also provides a full set of standard programmable peripherals that include one Enhanced
Synchronous Serial Interface (ESSI), two Serial Communications Interfaces (SCI), and one Quad Timer.
The ESSI, SCIs, four chip selects and Quad Timer external output can be used as General Purpose
Input/Outputs when its primary function is not required.
56855 Technical Data, Rev. 6
Freescale Semiconductor
5
1.3 State of the Art Development Environment
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•
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.
1.4 Product Documentation
The four documents listed in Table 1-1 are required for a complete description of and proper design with
the 56855. Documentation is available from local Freescale distributors, Freescale Semiconductor sales
offices, Freescale Literature Distribution Centers, or online at www.freescale.com.
Table 1-1 56855 Chip Documentation
Topic
Description
Order Number
56800E
Reference Manual
Detailed description of the 56800E architecture, and
16-bit core processor and the instruction set
56800ERM
DSP56855
User’s Manual
Detailed description of memory, peripherals, and
interfaces of the 56855
DSP5685xUM
56855
Technical Data Sheet
Electrical and timing specifications, pin descriptions,
and package descriptions (this document)
56855
DSP56855
Errata
Details any chip issues that might be present
DSP56855E
56855 Technical Data, Rev. 6
6
Freescale Semiconductor
Data Sheet Conventions
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.
56855 Technical Data, Rev. 6
Freescale Semiconductor
7
Part 2 Signal/Connection Descriptions
2.1 Introduction
The input and output signals of the 56855 are organized into functional groups, as shown in Table 2-1 and
as illustrated in Figure 2-1. In Table 3-1 each table row describes the package pin and the signal or signals
present.
Table 2-1 56855 Functional Group Pin Allocations
Functional Group
Number of Pins
Power (VDD, VDDIO, or VDDA)
(4, 10, 1)1
Ground (VSS, VSSIO,or VSSA)
(4, 10, 1)1
PLL and Clock
3
External Bus Signals
39
External Chip Select*
4
Interrupt and Program Control
72
Enhanced Synchronous Serial Interface (ESSI0) Port*
6
Serial Communications Interface (SCI0) Ports*
2
Serial Communications Interface (SCI1) Ports*
2
Quad Timer Module Port*
1
JTAG/Enhanced On-Chip Emulation (EOnCE)
6
*Alternately, GPIO pins
1. VDD = VDD CORE, VSS = VSS CORE, VDDIO= VDD IO, VSSIO = VSS IO, VDDA = VDD ANA, VSSA = VSS ANA
2. MODA, MODB and MODC can be used as GPIO after the bootstrap process has completed.
56855 Technical Data, Rev. 6
8
Freescale Semiconductor
Introduction
VDD
Logic
Power
VSS
1
4
1
4
1
VDDIO
I/O
Power
VSSIO
1
10
10
1
Analog
Power1
VDDA
VSSA
1
1
1
1
1
1
A0 - A20
D0 - D15
External
Bus
RD
WR
Chip
Select
CS0 - CS3 (GPIOA0 - A3)
56855
21
1
TIO0 (GPIOG0)
IRQA
IRQB
MODA, MODB, MODC
(GPIOH0 - H2)
Interrupt/
Program
Control
RESET
RSTO
SCI 0
TXDO (GPIOE1)
RXD1 (GPIOE2)
SCI 2
TXD1 (GPIOE3)
STD0 (GPIOC0)
SRD0 (GPIOC1)
SCK0 (GPIOC2)
SC00 (GPIOC3)
ESSI 0
SC01 (GPIOC4)
SC02 (GPIOC5)
16
1
1
4
1
Timer
Module
RXDO (GPIOE0)
1
1
1
1
1
1
1
1
3
1
1
1
1
1
XTAL
EXTAL
CLKO
PLL/Clock
TCK
TDI
TDO
TMS
JTAG /
Enhanced
OnCE
TRST
DE
Figure 2-1 56855 Signals Identified by Functional Group2
1. Specifically for PLL, OSC, and POR.
2. Alternate pin functions are shown in parentheses.
56855 Technical Data, Rev. 6
Freescale Semiconductor
9
Part 3 Signals and Package Information
All digital inputs have a weak internal pull-up circuit associated with them. These pull-up circuits are
enabled by default. Exceptions:
1. When a pin has GPIO functionality, the pull-up may be disabled under software control.
2. MODE A, MODE B and MODE C pins have no pull-up.
3. TCK has a weak pull-down circuit always active.
4. Bidirectional I/O pullups automatically disable when the output is enabled.
This table is presented consistently with the Signals Identified by Functional Group figure.
1. BOLD entries in the Type column represents the state of the pin just out of reset.
2. Output(Z) means an output in a High-Z condition.
Table 3-1. 56855 Signal and Package Information for the 100-pin LQFP
Pin No.
Signal Name
Type
Description
9
VDD
VDD
35
VDD
Power (VDD)—These pins provide power to the internal structures of the
chip, and should all be attached to VDD.
65
VDD
84
VDD
10
VSS
VSS
36
VSS
Ground (VSS)—These pins provide grounding for the internal structures of
the chip and should all be attached to VSS.
66
VSS
85
VSS
56855 Technical Data, Rev. 6
10
Freescale Semiconductor
Introduction
Table 3-1. 56855 Signal and Package Information for the 100-pin LQFP (Continued)
Pin No.
Signal Name
Type
Description
1
VDDIO
VDDIO
14
VDDIO
Power (VDDIO)—These pins provide power for all I/O and ESD structures of
the chip, and should all be attached to VDDIO (3.3V).
29
VDDIO
43
VDDIO
49
VDDIO
58
VDDIO
72
VDDIO
76
VDDIO
86
VDDIO
96
VDDIO
2
VSSIO
VSSIO
15
VSSIO
Ground (VSSIO)—These pins provide grounding for all I/O and ESD
structures of the chip and should all be attached to VSS.
30
VSSIO
44
VSSIO
50
VSSIO
60
VSSIO
73
VSSIO
78
VSSIO
87
VSSIO
97
VSSIO
2
VSSIO
18
VDDA
VDDA
Analog Power (VDDA)—These pins supply an analog power source.
19
VSSA
VSSA
Analog Ground (VSSA)—This pin supplies an analog ground.
56855 Technical Data, Rev. 6
Freescale Semiconductor
11
Table 3-1. 56855 Signal and Package Information for the 100-pin LQFP (Continued)
Pin No.
Signal Name
Type
Description
5
A0
Output(Z)
6
A1
Address Bus (A0-A20)—These signals specify a word address for external
program or data memory access.
7
A2
8
A3
22
A4
23
A5
24
A6
25
A7
31
A8
32
A9
33
A10
34
A11
45
A12
46
A13
47
A14
48
A15
53
A16
54
A17
55
A18
56
A19
57
A20
56855 Technical Data, Rev. 6
12
Freescale Semiconductor
Introduction
Table 3-1. 56855 Signal and Package Information for the 100-pin LQFP (Continued)
Pin No.
Signal Name
Type
59
D0
Input/Output(Z)
67
D1
68
D2
69
D3
70
D4
71
D5
79
D6
80
D7
81
D8
82
D9
83
D10
94
D11
95
D12
98
D13
99
D14
3
RD
Output
Description
Data Bus (D0-D15)—These pins provide the bidirectional data for external
program or data memory accesses.
Read Enable (RD)— is asserted during external memory read cycles.
This signal is pulled high during reset.
4
WR
Output
Write Enable (WR) — is asserted during external memory write cycles.
This signal is pulled high during reset.
61
62
63
CS0
Output
GPIOA0
Input/Output
CS1
Output
GPIOA1
Input/Output
CS2
Output
GPIOA2
Input/Output
External Chip Select (CS0)—This pin is used as a dedicated GPIO.
Port A GPIO (0) —This pin is a General Purpose I/O (GPIO) pin when not
configured for host port usage.
External Chip Select (CS1)—This pin is used as a dedicated GPIO.
Port A GPIO (1) —This pin is a General Purpose I/O (GPIO) pin when not
configured for host port usage.
External Chip Select (CS2)—This pin is used as a dedicated GPIO.
Port A GPIO (2) —This pin is a General Purpose I/O (GPIO) pin when not
configured for host port usage.
56855 Technical Data, Rev. 6
Freescale Semiconductor
13
Table 3-1. 56855 Signal and Package Information for the 100-pin LQFP (Continued)
Pin No.
Signal Name
Type
64
CS3
Output
GPIOA3
Input/Output
Port A GPIO (3)—This pin is a General Purpose I/O (GPIO) pin when not
configured for host port usage.
TIO0
Input/Output
Timer Input/Output (TIO0)—This pin can be independently configured to
be either timer input source or output flag.
GPIOG0
Input/Output
Port G GPIO (0)—This pin is a General Purpose I/O (GPIO) pin that can
individually be programmed as input or output pin.
16
IRQA
Input
17
IRQB
External Interrupt Request A and B—The IRQA and IRQB inputs are
asynchronized external interrupt requests that indicate that an external
device is requesting service. A Schmitt trigger input is used for noise
immunity. They can be programmed to be level-sensitive or negative-edgetriggered. If level-sensitive triggering is selected, an external pull-up resistor
is required for Wired-OR operation.
11
MODA
Input
Mode Select (MODA)—During the bootstrap process MODA selects one of
the eight bootstrap modes.
GPIOH0
Input/Output
MODB
Input
GPIOH1
Input/Output
MODC
Input
GPIOH2
Input/Output
RESET
Input
77
12
13
28
Description
External Chip Select (CS3)—This pin is used as a dedicated GPIO.
Port H GPIO (0)—This pin is a General Purpose I/O (GPIO) pin after the
bootstrap process has completed.
Mode Select (MODB)—During the bootstrap process MODB selects one of
the eight bootstrap modes.
Port H GPIO (1)—This pin is a General Purpose I/O (GPIO) pin after the
bootstrap process has completed.
Mode Select (MODC)—During the bootstrap process MODC selects one of
the eight bootstrap modes.
Port H GPIO (2)—This pin is a General Purpose I/O (GPIO) pin after the
bootstrap process has completed.
Reset (RESET)—This input is a direct hardware reset on the processor.
When RESET is asserted low, the device 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
MODA, MODB, and MODC pins.
To ensure complete hardware reset, RESET and TRST should be asserted
together. The only exception occurs in a debugging environment when a
hardware reset is required and it is necessary not to reset the
JTAG/Enhanced OnCE module. In this case, assert RESET, but do not
assert TRST.
27
RSTO
Output
Reset Output (RSTO)—This output is asserted on any reset condition
(external reset, low voltage, software or COP).
56855 Technical Data, Rev. 6
14
Freescale Semiconductor
Introduction
Table 3-1. 56855 Signal and Package Information for the 100-pin LQFP (Continued)
Pin No.
Signal Name
Type
51
RXD0
Input
Serial Receive Data 0 (RXD0)—This input receives byte-oriented serial
data and transfers it to the SCI 0 receive shift register.
GPIOE0
Input/Output
Port E GPIO (0)—This pin is a General Purpose I/O (GPIO) pin that can
individually be programmed as input or output pin.
TXD0
Output(Z)
GPIOE1
Input/Output
Port E GPIO (1)—This pin is a General Purpose I/O (GPIO) pin that can
individually be programmed as input or output pin.
RXD1
Input
Serial Receive Data 1 (RXD1)—This input receives byte-oriented serial
data and transfers it to the SCI 1 receive shift register.
GPIOE2
Input/Output
Port E GPIO (2)—This pin is a General Purpose I/O (GPIO) pin that can
individually be programmed as input or output pin.
TXD1
Output(Z)
GPIOE3
Input/Output
STD0
Output
ESSI Transmit Data (STD0)—This output pin transmits serial data from the
ESSI Transmitter Shift Register.
GPIOC0
Input/Output
Port C GPIO (0)—This pin is a General Purpose I/O (GPIO) pin when the
ESSI is not in use.
SRD0
Input
GPIOC1
Input/Output
Port C GPIO (1)—This pin is a General Purpose I/O (GPIO) pin when the
ESSI is not in use.
SCK0
Input/Output
ESSI Serial Clock (SCK0)—This bidirectional pin provides the serial bit
rate clock for the transmit section of the ESSI. The clock signal can be
continuous or gated and can be used by both the transmitter and receiver in
synchronous mode.
GPIOC2
Input/Output
Port C GPIO (2)—This pin is a General Purpose I/O (GPIO) pin when the
ESSI is not in use.
52
74
75
88
89
90
Description
Serial Transmit Data 0 (TXD0)—This signal transmits data from the SCI 0
transmit data register.
Serial Transmit Data 1 (TXD1)—This signal transmits data from the SCI 1
transmit data register.
Port E GPIO (3)—This pin is a General Purpose I/O (GPIO) pin that can
individually be programmed as input or output pin.
ESSI Receive Data (SRD0)—This input pin receives serial data and
transfers the data to the ESSI Receive Shift Register.
56855 Technical Data, Rev. 6
Freescale Semiconductor
15
Table 3-1. 56855 Signal and Package Information for the 100-pin LQFP (Continued)
Pin No.
Signal Name
Type
91
SC00
Input/Output
ESSI Serial Control Pin 0 (SC00)—The function of this pin is determined
by the selection of either synchronous or asynchronous mode. For
asynchronous mode, this pin will be used for the receive clock I/O. For
synchronous mode, this pin is used either for transmitter1 output or for
serial I/O flag 0.
GPIOC3
Input/Output
Port C GPIO (3)—This pin is a General Purpose I/O (GPIO) pin when the
ESSI is not in use.
SC01
Input/Output
ESSI Serial Control Pin 1 (SC01)—The function of this pin is determined
by the selection of either synchronous or asynchronous mode. For
asynchronous mode, this pin is the receiver frame sync I/O. For
synchronous mode, this pin is used either for transmitter2 output or for
serial I/O flag 1.
GPIOC4
Input/Output
Port C GPIO (4)—This pin is a General Purpose I/O (GPIO) pin when the
ESSI is not in use.
SC02
Input/Output
ESSI Serial Control Pin 2 (SC02)—This pin is used for frame sync I/O.
SC02 is the frame sync for both the transmitter and receiver in synchronous
mode and for the transmitter only in asynchronous mode. When configured
as an output, this pin is the internally generated frame sync signal. When
configured as an input, this pin receives an external frame sync signal for
the transmitter (and the receiver in synchronous operation).
GPIOC5
Input or Output
Port C GPIO (5)—This pin is a General Purpose I/O (GPIO) pin when the
ESSI is not in use.
20
XTAL
Input/Output
Crystal Oscillator Output (XTAL)—This output connects the internal
crystal oscillator output to an external crystal. If an external clock source
other than a crystal oscillator is used, XTAL must be used as the input.
21
EXTAL
Input
External Crystal Oscillator Input (EXTAL)—This input should be
connected to an external crystal. If an external clock source other than a
crystal oscillator is used, EXTAL must be tied off. See Section 4.5.2
26
CLKO
Output
Clock Output (CLKO)—This pin outputs a buffered clock signal. When
enabled, this signal is the system clock divided by four.
42
TCK
Input
Test Clock Input (TCK)—This input pin provides a gated clock to
synchronize the test logic and to shift serial data to the JTAG/Enhanced
OnCE port. The pin is connected internally to a pull-down resistor.
40
TDI
Input
Test Data Input (TDI)—This input pin provides a serial input data stream to
the JTAG/Enhanced OnCE port. It is sampled on the rising edge of TCK
and has an on-chip pull-up resistor.
39
TDO
Output (Z)
Test Data Output (TDO)—This tri-statable output pin provides a serial
output data stream from the JTAG/Enhanced OnCE port. It is driven in the
Shift-IR and Shift-DR controller states, and changes on the falling edge of
TCK.
92
93
Description
56855 Technical Data, Rev. 6
16
Freescale Semiconductor
General Characteristics
Table 3-1. 56855 Signal and Package Information for the 100-pin LQFP (Continued)
Pin No.
Signal Name
Type
41
TMS
Input
Description
Test Mode Select Input (TMS)—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:
38
TRST
Input
Always tie the TMS pin to VDD through a 2.2K resistor.
Test Reset (TRST)—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 whenever RESET is asserted. The only
exception occurs in a debugging environment, since the Enhanced
OnCE/JTAG module is under the control of the debugger. In this case it is
not necessary to assert TRST when asserting RESET. Outside of a
debugging environment RESET should be permanently asserted by
grounding the signal, thus disabling the Enhanced OnCE/JTAG module on
the device.
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.
37
DE
Input/Output
Debug Event (DE)—This is an open-drain, bidirectional, active low signal.
As an input, it is a means of entering debug mode of operation from an
external command controller. As an output, it is a means of acknowledging
that the chip has entered debug mode.
This pin is connected internally to a weak pull-up resistor.
Part 4 Specifications
4.1 General Characteristics
The 56855 is fabricated in high-density CMOS with 5-volt tolerant TTL-compatible digital inputs. The
term “5-volt 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.
Absolute maximum ratings given in Table 4-1 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 56855 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
56855 Technical Data, Rev. 6
Freescale Semiconductor
17
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 4-1 Absolute Maximum Ratings
Characteristic
Supply voltage, core
Supply voltage, IO
Supply voltage, analog
Symbol
Min
Max
Unit
VDD1
VSS – 0.3
VSS + 2.0
V
VDDIO2
VSSIO – 0.3
VSSA – 0.3
VSSIO + 4.0
VDDA + 4.0
V
VIN
VINA
VSSIO – 0.3
VSSA – 0.3
VSSIO + 5.5
VDDA + 0.3
V
I
—
8
mA
TJ
-40
120
°C
TSTG
-55
150
°C
VDDIO
Digital input voltages
Analog input voltages (XTAL, EXTAL)
Current drain per pin excluding VDD, GND
Junction temperature
Storage temperature range
2
1. VDD must not exceed VDDIO
2. VDDIO and VDDA must not differ by more that 0.5V
Table 4-2 Recommended Operating Conditions
Characteristic
Symbol
Min
Max
Unit
VDD
1.62
1.98
V
Supply voltage for I/O Power
VDDIO
3.0
3.6
V
Supply voltage for Analog Power
VDDA
3.0
3.6
V
Supply voltage for Logic Power
56855 Technical Data, Rev. 6
18
Freescale Semiconductor
General Characteristics
Table 4-2 Recommended Operating Conditions
Characteristic
Symbol
Min
Max
Unit
Ambient operating temperature
TA
-40
85
°C
PLL clock frequency1
fpll
—
240
MHz
Operating Frequency2
fop
—
120
MHz
Frequency of peripheral bus
fipb
—
60
MHz
Frequency of external clock
fclk
—
240
MHz
Frequency of oscillator
fosc
2
4
MHz
Frequency of clock via XTAL
fxtal
—
240
MHz
Frequency of clock via EXTAL
fextal
2
4
MHz
1. Assumes clock source is direct clock to EXTAL or crystal oscillator running 2-4MHz. PLL must be enabled, locked, and
selected. The actual frequency depends on the source clock frequency and programming of the CGM module.
2. Master clock is derived from on of the following four sources:
fclk = fxtal when the source clock is the direct clock to EXTAL
fclk = fpll when PLL is selected
fclk = fosc when the source clock is the crystal oscillator and PLL is not selected
fclk = fextal when the source clock is the direct clock to EXTAL and PLL is not selected
Table 4-3 Thermal Characteristics1
100-pin LQFP
Characteristic
Symbol
Value
Unit
Thermal resistance junction-to-ambient
(estimated)
θJA
41.2
°C/W
I/O pin power dissipation
PI/O
User Determined
W
Power dissipation
PD
PD = (IDD × VDD) + PI/O
W
PDMAX
(TJ – TA) / RθJA 2
°C
Maximum allowed PD
1. See Section 6.1 for more detail.
2. TJ = Junction Temperature
TA = Ambient Temperature
56855 Technical Data, Rev. 6
Freescale Semiconductor
19
4.2 DC Electrical Characteristics
Table 4-4 DC Electrical Characteristics
Operating Conditions: VSS = VSSIO = VSSA = 0 V, VDD = 1.62-1.98V, VDDIO = VDDA = 3.0–3.6V, TA = –40° to +120°C, CL ≤ 50pF, fop = 120MHz
Characteristic
Symbol
Min
Typ
Max
Unit
Input high voltage (XTAL/EXTAL)
VIHC
VDDA – 0.8
VDDA
VDDA + 0.3
V
Input low voltage (XTAL/EXTAL)
VILC
-0.3
—
0.5
V
Input high voltage
VIH
2.0
—
5.5
V
Input low voltage
VIL
-0.3
—
0.8
V
Input current low (pullups disabled)
IIL
-1
—
1
μA
Input current high (pullups disabled)
IIH
-1
—
1
μA
Output tri-state current low
IOZL
-10
—
10
μA
Output tri-state current high
IOZH
-10
—
10
μA
Output High Voltage
VOH
VDDIO – 0.7
—
—
V
Output Low Voltage
VOL
—
—
0.4
V
Output High Current
IOH
8
—
16
mA
Output Low Current
IOL
8
—
16
mA
Input capacitance
CIN
—
8
—
pF
Output capacitance
COUT
—
12
—
pF
VDD supply current (Core logic, memories, peripherals)
IDD4
—
—
—
70
0.05
5
110
10
14
mA
mA
mA
—
40
0
50
1.5
mA
mA
—
60
120
μA
1
Run
Deep Stop2
Light Stop3
VDDIO supply current (I/O circuity)
IDDIO
Run5
Deep Stop2
VDDA supply current (analog circuity)
Deep
IDDA
Stop2
Low Voltage Interrupt6
VEI
—
2.5
2.85
V
Low Voltage Interrupt Recovery Hysteresis
VEIH
—
50
—
mV
Power on Reset7
POR
—
1.5
2.0
V
Note:
Run (operating) IDD measured using external square wave clock source (fosc = 4MHz) into XTAL. All inputs 0.2V from rail;
no DC loads; outputs unloaded. All ports configured as inputs; measured with all modules enabled. PLL set to 240MHz out.
1.
Running Core, performing 50% NOP and 50% FIR. Clock at 120 MHz.
2.
Deep Stop Mode - Operation frequency = 4 MHz, PLL set to 4 MHz, crystal oscillator and time of day module operating.
3.
Light Stop Mode - Operation frequency = 120 MHz, PLL set to 240 MHz, crystal oscillator and time of day module operating.
4.
IDD includes current for core logic, internal memories, and all internal peripheral logic circuitry.
56855 Technical Data, Rev. 6
20
Freescale Semiconductor
Supply Voltage Sequencing and Separation Cautions
5.
Running core and performing external memory access. Clock at 120 MHz.
6.
When VDD drops below VEI max value, an interrupt is generated.
7. Power-on reset occurs whenever the digital supply drops below 1.8V. While power is ramping up, this signal remains active
for as long as the internal 2.5V is below 1.8V no matter how long the ramp up rate is. The internally regulated voltage is typically
100 mV less than VDD during ramp up until 2.5V is reached, at which time it self-regulates.
150
EMI Mode5
MAC Mode1
120
IDD (mA)
90
60
30
0
20
40
60
80
100
120
Figure 4-1 Maximum Run IDDTOTAL vs. Frequency (see Notes 1. and 5. in Table 4-4)
4.3 Supply Voltage Sequencing and Separation Cautions
Figure 4-2 shows two situations to avoid in sequencing the VDD and VDDIO, VDDA supplies.
56855 Technical Data, Rev. 6
Freescale Semiconductor
21
DC Power Supply Voltage
3.3V
VDDIO, VDDA
2
1.8V
Supplies Stable
VDD
1
0
Time
Notes: 1. VDD rising before VDDIO, VDDA
2. VDDIO, VDDA rising much faster than VDD
Figure 4-2 Supply Voltage Sequencing and Separation Cautions
VDD should not be allowed to rise early (1). This is usually avoided by running the regulator for the VDD
supply (1.8V) from the voltage generated by the 3.3V VDDIO supply, see Figure 4-3. This keeps VDD from
rising faster than VDDIO.
VDD should not rise so late that a large voltage difference is allowed between the two supplies (2).
Typically this situation is avoided by using external discrete diodes in series between supplies, as shown
in Figure 4-3. The series diodes forward bias when the difference between VDDIO and VDD reaches
approximately 2.1, causing VDD to rise as VDDIO ramps up. When the VDD regulator begins proper
operation, the difference between supplies will typically be 0.8V and conduction through the diode chain
reduces to essentially leakage current. During supply sequencing, the following general relationship
should be adhered to:
VDDIO > VDD > (VDDIO - 2.1V)
In practice, VDDA is typically connected directly to VDDIO with some filtering.
56855 Technical Data, Rev. 6
22
Freescale Semiconductor
AC Electrical Characteristics
Supply
VDDIO, VDDA
3.3V
Regulator
VDD
1.8V
Regulator
Figure 4-3 Example Circuit to Control Supply Sequencing
4.4 AC Electrical Characteristics
Timing waveforms in Section 4.2 are tested with a VIL maximum of 0.8 V and a VIH minimum of 2.0 V
for all pins except XTAL, which is tested using the input levels in Section 4.2. In Figure 4-4 the levels of
VIH and VIL for an input signal are shown.
Low
VIH
Input Signal
High
90%
50%
10%
Midpoint1
VIL
Fall Time
Rise Time
Note: The midpoint is VIL + (VIH – VIL)/2.
Figure 4-4 Input Signal Measurement References
Figure 4-5 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 4-5 Signal State
56855 Technical Data, Rev. 6
Freescale Semiconductor
23
4.5 External Clock Operation
The 56855 system clock can be derived from a 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.
4.5.1
Crystal Oscillator
The internal oscillator is designed to interface with a parallel-resonant crystal resonator in the frequency
range specified for the external crystal in Table 4-5. In Figure 4-6 a typical 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.
Crystal Frequency = 2–4 MHz (optimized for 4MHz)
EXTAL XTAL
Rz
Sample External Crystal Parameters:
Rz = 10MΩ
TOD_SEL bit in CGM must be set to 0
Figure 4-6 Crystal Oscillator
4.5.2
High Speed External Clock Source (> 4MHz)
The recommended method of connecting an external clock is given in Figure 4-7. The external clock
source is connected to XTAL and the EXTAL pin is held at ground, VDDA, or VDDA/2. The TOD_SEL
bit in CGM must be set to 0.
56855
XTAL
EXTAL
GND,VDDA,
External
Clock
or VDDA/2
(up to 240MHz)
Figure 4-7 Connecting a High Speed External Clock Signal using XTAL
56855 Technical Data, Rev. 6
24
Freescale Semiconductor
External Clock Operation
4.5.3
Low Speed External Clock Source (2-4MHz)
The recommended method of connecting an external clock is given in Figure 4-8. The external clock
source is connected to XTAL and the EXTAL pin is held at VDDA/2. The TOD_SEL bit in CGM must be
set to 0.
56855
XTAL
EXTAL
External
Clock
(2-4MHz)
VDDA/2
Figure 4-8 Connecting a Low Speed External Clock Signal using XTAL
Table 4-5 External Clock Operation Timing Requirements4
Operating Conditions: VSS = VSSIO = VSSA = 0 V, VDD = 1.62-1.98V, VDDIO = VDDA = 3.0–3.6V, TA = –40° to +120°C, CL ≤ 50pF, fop = 120MHz
Characteristic
Symbol
Min
Typ
Max
Unit
Frequency of operation (external clock driver)1
fosc
0
—
240
MHz
Clock Pulse Width4
tPW
6.25
—
—
ns
External clock input rise time2, 4
trise
—
—
TBD
ns
External clock input fall time3, 4
tfall
—
—
TBD
ns
1.
See Figure 4-7 for details on using the recommended connection of an external clock driver.
2.
External clock input rise time is measured from 10% to 90%.
3.
External clock input fall time is measured from 90% to 10%.
4.
Parameters listed are guaranteed by design.
VIH
External
Clock
90%
50%
10%
tPW
tPW
90%
50%
10%
tfall
trise
VIL
Note: The midpoint is VIL + (VIH – VIL)/2.
Figure 4-9 External Clock Timing
56855 Technical Data, Rev. 6
Freescale Semiconductor
25
Table 4-6 PLL Timing
Operating Conditions: VSS = VSSIO = VSSA = 0 V, VDD = 1.62-1.98V, VDDIO = VDDA = 3.0–3.6V, TA = –40° to +120°C, CL ≤ 50pF, fop = 120MHz
Characteristic
Symbol
Min
Typ
Max
Unit
External reference crystal frequency for the PLL1
fosc
2
4
4
MHz
PLL output frequency
fclk
40
—
240
MHz
PLL stabilization time 2
tplls
—
1
10
ms
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 4MHz input crystal.
2.
This is the minimum time required after the PLL setup is changed to ensure reliable operation.
4.6 External Memory Interface Timing
The External Memory Interface is designed to access static memory and peripheral devices. Figure 4-10
shows sample timing and parameters that are detailed in Table 4-7.
The timing of each parameter consists of both a fixed delay portion and a clock related portion; as well as user
controlled wait states. The equation:
t = D + P * (M + W)
should be used to determine the actual time of each parameter. The terms in the above equation are defined as:
t
parameter delay time
D fixed portion of the delay, due to on-chip path delays.
P
the period of the system clock, which determines the execution rate of the part (i.e. when the device is
operating at 120 MHz, P = 8.33 ns).
M Fixed portion of a clock period inherent in the design. This number is adjusted to account for possible
clock duty cycle derating.
W the sum of the applicable wait state controls. See the “Wait State Controls” column of Table 4-7 for
the applicable controls for each parameter. See the EMI chapter of the 83x Peripheral Manual for
details of what each wait state field controls.
Some of the parameters contain two sets of numbers. These parameters have two different paths and clock edges
that must be considered. Check both sets of numbers and use the smaller result. The appropriate entry may change
if the operating frequency of the part changes.
The timing of write cycles is different when WWS = 0 than when WWS > 0. Therefore, some parameters contain
two sets of numbers to account for this difference. The “Wait States Configuration” column of Table 4-7 should be
used to make the appropriate selection.
56855 Technical Data, Rev. 6
26
Freescale Semiconductor
External Memory Interface Timing
A0-Axx,CS
tRD
tARDD
tARDA
tRDA
tRDRD
RD
tWAC
tAWR
tWRWR
tWRRD
tWR
tRDWR
WR
tDWR
tDOH
tDOS
tAD
tRDD
tDRD
Data Out
D0-D15
Data In
Note: During read-modify-write instructions and internal instructions, the address lines do not change state.
Figure 4-10 External Memory Interface Timing
Table 4-7 External Memory Interface Timing
Operating Conditions: VSS = VSSIO = VSSA = 0 V, VDD = 1.62-1.98 V, VDDIO = VDDA = 3.0–3.6V, TA = –40× to +120×C, CL £ 50pF, P = 8.333ns
Characteristic
Address Valid to WR Asserted
WR Width Asserted to WR
Deasserted
Symbol
tAWR
tWR
Data Out Valid to WR Asserted
tDWR
Valid Data Out Hold Time after WR
Deasserted
tDOH
Valid Data Out Set Up Time to WR
Deasserted
tDOS
Valid Address after WR
Deasserted
tWAC
RD Deasserted to Address Invalid
tRDA
Wait States
Configuration
D
M
Wait States
Controls
Unit
WWS=0
-0.79
0.50
WWS>0
-1.98
0.69
WWSS
ns
WWS=0
-0.86
0.19
WWS>0
-0.01
0.00
WWS
ns
WWS=0
-1.52
0.00
WWS=0
- 5.69
0.25
WWS>0
-2.10
0.19
WWSS
ns
WWS>0
-4.66
0.50
-1.47
0.25
WWSH
ns
-2.36
0.19
-4.67
0.50
-1.60
0.25
WWSH
- 0.44
0.00
RWSH
WWS,WWSS
ns
ns
56855 Technical Data, Rev. 6
Freescale Semiconductor
27
Table 4-7 External Memory Interface Timing (Continued)
Operating Conditions: VSS = VSSIO = VSSA = 0 V, VDD = 1.62-1.98 V, VDDIO = VDDA = 3.0–3.6V, TA = –40× to +120×C, CL £ 50pF, P = 8.333ns
Characteristic
Symbol
Wait States
Configuration
D
M
Wait States
Controls
Unit
Address Valid to RD Deasserted
tARDD
-2.07
1.00
RWSS,RWS
ns
Valid Input Data Hold after RD
Deasserted
tDRD
0.00
N/A1
—
ns
RD Assertion Width
tRD
-1.34
1.00
RWS
ns
Address Valid to Input Data Valid
tAD
-10.27
1.00
-13.5
1.19
RWSS,RWS
ns
- 0.94
0.00
RWSS
ns
Address Valid to RD Asserted
tARDA
RD Asserted to Input Data Valid
tRDD
-9.53
1.00
-12.64
1.19
RWSS,RWS
ns
WR Deasserted to RD Asserted
tWRRD
-0.75
0.25
WWSH,RWSS
ns
RD Deasserted to RD Asserted
tRDRD
-0.162
0.00
RWSS,RWSH
ns
WR Deasserted to WR Asserted
tWRWR
WWS=0
-0.44
0.75
WWS>0
-0.11
1.00
WWSS, WWSH
ns
0.14
0.50
-0.57
0.69
MDAR, BMDAR,
RWSH, WWSS
ns
RD Deasserted to WR Asserted
tRDWR
1. N/A since device captures data before it deasserts RD
2. If RWSS = RWSH = 0, RD does not deassert during back-to-back reads and D=0.00 should be used.
4.7 Reset, Stop, Wait, Mode Select, and Interrupt Timing
Table 1. Reset, Stop, Wait, Mode Select, and Interrupt Timing1, 2
Operating Conditions: VSS = VSSIO = VSSA = 0 V, VDD = 1.62-1.98V, VDDIO = VDDA = 3.0–3.6V, TA = –40° to +120°C, CL ≤ 50pF, fop = 120MHz
Characteristic
Symbol
Min
Max
Unit
See Figure
RESET Assertion to Address, Data and Control
Signals High Impedance
tRAZ
—
11
ns
4-11
Minimum RESET Assertion Duration3
tRA
30
—
ns
4-11
RESET Deassertion to First External Address Output
tRDA
—
120T
ns
4-11
Edge-sensitive Interrupt Request Width
tIRW
1T + 3
—
ns
4-12
56855 Technical Data, Rev. 6
28
Freescale Semiconductor
Reset, Stop, Wait, Mode Select, and Interrupt Timing
Table 1. Reset, Stop, Wait, Mode Select, and Interrupt Timing1, 2
(Continued)
Operating Conditions: VSS = VSSIO = VSSA = 0 V, VDD = 1.62-1.98V, VDDIO = VDDA = 3.0–3.6V, TA = –40° to +120°C, CL ≤ 50pF, fop = 120MHz
Characteristic
Symbol
Min
Max
Unit
See Figure
IRQA, IRQB Assertion to External Data Memory
Access Out Valid, caused by first instruction execution
in the interrupt service routine
tIDM
18T
—
ns
4-13
tIDM -FAST
14T
—
tIG
18T
—
ns
4-13
tIG -FAST
14T
—
tIRI
22T
—
ns
4-14
tIRI -FAST
18T
—
1.5T
—
IRQA, IRQB Assertion to General Purpose Output
Valid, caused by first instruction execution in the
interrupt service routine
IRQA Low to First Valid Interrupt Vector Address Out
recovery from Wait State4
Delay from IRQA Assertion (exiting Stop) to External
Data Memory5
tIW
Delay from IRQA Assertion (exiting Wait) to External
Data Memory
Fast6
Normal7
tIF
RSTO pulse width8
normal operation
internal reset mode
ns
4-15
4-15
18T
22ET
—
—
ns
ns
4-16
tRSTO
128ET
8ET
—
—
—
—
1. In the formulas, T = clock cycle. For fop = 120MHz operation and fipb = 60MHz, T = 8.33ns.
2. Parameters listed are guaranteed by design.
3. At reset, the PLL is disabled and bypassed. The part is then put into Run mode and tclk assumes the period of the source clock,
txtal, textal or tosc.
4. 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.
5. The interrupt instruction fetch is visible on the pins only in Mode 3.
6. Fast stop mode:
Fast stop recovery applies when external clocking is in use (direct clocking to XTAL) or when fast stop mode recovery is requested (OMR bit 6 is set to 1). In both cases the PLL and the master clock are unaffected by stop mode entry. Recovery takes one
less cycle and tclk will continue same value it had before stop mode was entered.
7. Normal stop mode:
As a power saving feature, normal stop mode disables and bypasses the PLL. Stop mode will then shut down the master clock,
recovery will take an extra cycle (to restart the clock), and tclk will resume at the input clock source rate.
8. ET = External Clock period, For an external crystal frequency of 8MHz, ET=125 ns.
56855 Technical Data, Rev. 6
Freescale Semiconductor
29
RESET
tRA
tRAZ
tRDA
A0–A20,
D0–D15
First Fetch
CS,
RD, WR
First Fetch
Figure 4-11 Asynchronous Reset Timing
IRQA
IRQB
tIRW
Figure 4-12 External Interrupt Timing (Negative-Edge-Sensitive)
A0–A20,
CS,
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 4-13 External Level-Sensitive Interrupt Timing
56855 Technical Data, Rev. 6
30
Freescale Semiconductor
Host Interface Port
IRQA,
IRQB
tIRI
A0–A20,
CS,
RD, WR
First Interrupt Vector
Instruction Fetch
Figure 4-14 Interrupt from Wait State Timing
tIW
IRQA
tIF
A0–A20,
CS,
RD, WR
First Instruction Fetch
Not IRQA Interrupt Vector
Figure 4-15 Recovery from Stop State Using Asynchronous Interrupt Timing
RESET
tRSTO
Figure 4-16 Reset Output Timing
4.8 Host Interface Port
Table 4-8 Host Interface Port Timing1
Operating Conditions: VSS = VSSIO = VSSA = 0 V, VDD = 1.62-1.98V, VDDIO = VDDA = 3.0–3.6V, TA = –40° to +120°C, CL ≤ 50pF, fop = 120MHz
Characteristic
Symbol
Min
Max
Unit
See Figure
Access time
TACKDV
—
13
ns
4-17
Disable time
TACKDZ
3
—
ns
4-17
Time to disassert
TACKREQH
3.5
9
ns
4-17
4-20
Lead time
TREQACKL
0
—
ns
4-17
4-20
56855 Technical Data, Rev. 6
Freescale Semiconductor
31
Table 4-8 Host Interface Port Timing1 (Continued)
Operating Conditions: VSS = VSSIO = VSSA = 0 V, VDD = 1.62-1.98V, VDDIO = VDDA = 3.0–3.6V, TA = –40° to +120°C, CL ≤ 50pF, fop = 120MHz
Characteristic
Symbol
Min
Max
Unit
See Figure
Access time
TRADV
—
13
ns
4-18
4-19
Disable time
TRADX
5
—
ns
4-18
4-19
Disable time
TRADZ
3
—
ns
4-18
4-19
Setup time
TDACKS
3
—
ns
4-20
Hold time
TACKDH
1
—
ns
4-20
Setup time
TADSS
3
—
ns
4-21
4-23
Hold time
TDSAH
1
—
ns
4-21
4-22
Pulse width
TWDS
5
—
ns
4-21
4-22
TACKREQL
4T + 5
5
5T + 9
13
ns
ns
4-17
4-20
Time to re-assert
1. After second write in 16-bit mode
2. After first write in 16-bit mode
or after write in 8-bit mode
1. The formulas: T = clock cycle. f ipb = 60MHz, T = 16.7ns.
HACK
TACKDZ
TACKDV
HD
TREQACKL
TACKREQH
TACKREQL
HREQ
Figure 4-17 Controller-to-Host DMA Read Mode
56855 Technical Data, Rev. 6
32
Freescale Semiconductor
Host Interface Port
HA
TRADX
HCS
HDS
HRW
TRADV
TRADZ
HD
Figure 4-18 Single Strobe Read Mode
HA
TRADX
HCS
HWR
HRD
TRADZ
HD
TRADV
Figure 4-19 Dual Strobe Read Mode
56855 Technical Data, Rev. 6
Freescale Semiconductor
33
HACK
TDACKS
TACKDH
HD
TREQACKL
TACKREQL
TACKREQH
HREQ
Figure 4-20 Host-to-Controller DMA Write Mode
HA
TDSAH
HCS
TWDS
HDS
TDSAH
HRW
TADSS
TADSS
TDSAH
HD
Figure 4-21 Single Strobe Write Mode
HA
HCS
TWDS
HWR
TDSAH
TADSS
HRD
TADSS
HD
Figure 4-22 Dual Strobe Write Mode
56855 Technical Data, Rev. 6
34
Freescale Semiconductor
Quad Timer Timing
4.9 Quad Timer Timing
Table 4-9 Quad Timer Timing1, 2
Operating Conditions: VSS = VSSIO = VSSA = 0 V, VDD = 1.62-1.98V, VDDIO = VDDA = 3.0–3.6V, TA = –40° to +120°C, CL ≤ 50pF, fop = 120MHz
Characteristic
Symbol
Min
Max
Unit
PIN
2T + 3
—
ns
Timer input high/low period
PINHL
1T + 3
—
ns
Timer output period
POUT
2T - 3
—
ns
POUTHL
1T - 3
—
ns
Timer input period
Timer output high/low period
1. In the formulas listed, T = clock cycle. For fop = 120MHz operation and fipb = 60MHz, T = 8.33ns.
2. Parameters listed are guaranteed by design.
Timer Inputs
PIN
PINHL
PINHL
POUT
POUTHL
POUTHL
Timer Outputs
Figure 4-23 Timer Timing
56855 Technical Data, Rev. 6
Freescale Semiconductor
35
4.10 Enhanced Synchronous Serial Interface (ESSI) Timing
Table 4-10 ESSI Master Mode1 Switching Characteristics
Operating Conditions: VSS = VSSIO = VSSA = 0 V, VDD = 1.62-1.98V, VDDIO = VDDA = 3.0–3.6V, TA = –40° to +120°C, CL ≤ 50pF, fop = 120MHz
Parameter
Symbol
Min
Typ
Max
Units
fs
—
—
152
MHz
SCK period3
tSCKW
66.7
—
—
ns
SCK high time
tSCKH
33.44
—
—
ns
SCK low time
tSCKL
33.44
—
—
ns
—
—
4
—
ns
Delay from SCK high to SC2 (bl) high - Master5
tTFSBHM
-1.0
—
1.0
ns
Delay from SCK high to SC2 (wl) high - Master5
tTFSWHM
-1.0
—
1.0
ns
Delay from SC0 high to SC1 (bl) high - Master5
tRFSBHM
-1.0
—
1.0
ns
Delay from SC0 high to SC1 (wl) high - Master5
tRFSWHM
-1.0
—
1.0
ns
Delay from SCK high to SC2 (bl) low - Master5
tTFSBLM
-1.0
—
1.0
ns
Delay from SCK high to SC2 (wl) low - Master5
tTFSWLM
-1.0
—
1.0
ns
Delay from SC0 high to SC1 (bl) low - Master5
tRFSBLM
-1.0
—
1.0
ns
Delay from SC0 high to SC1 (wl) low - Master5
tRFSWLM
-1.0
—
1.0
ns
SCK high to STD enable from high impedance - Master
tTXEM
-0.1
—
2
ns
SCK high to STD valid - Master
tTXVM
-0.1
—
2
ns
SCK high to STD not valid - Master
tTXNVM
-0.1
—
—
ns
SCK high to STD high impedance - Master
tTXHIM
-4
—
0
ns
SRD Setup time before SC0 low - Master
tSM
4
—
—
ns
SRD Hold time after SC0 low - Master
tHM
4
—
—
ns
SCK frequency
Output clock rise/fall time
Synchronous Operation (in addition to standard internal clock parameters)
SRD Setup time before SCK low - Master
tTSM
4
—
—
ns
SRD Hold time after SCK low - Master
tTHM
4
—
—
ns
1. Master mode is internally generated clocks and frame syncs
2. Max clock frequency is IP_clk/4 = 60MHz / 4 = 15MHz for an 120MHz part.
56855 Technical Data, Rev. 6
36
Freescale Semiconductor
Enhanced Synchronous Serial Interface (ESSI) Timing
3. All the timings for the ESSI are given for a non-inverted serial clock polarity (TSCKP=0 in SCR2 and RSCKP=0 in SCSR)
and a non-inverted frame sync (TFSI=0 in SCR2 and RFSI=0 in SCSR). If the polarity of the clock and/or the frame sync have
been inverted, all the timings remain valid by inverting the clock signal SCK/SC0 and/or the frame sync SC2/SC1 in the tables
and in the figures.
4. 50 percent duty cycle
5. bl = bit length; wl = word length
tSCKH
tSCKW
tSCKL
SCK output
tTFSBHM
tTFSBLM
SC2 (bl) output
tTFSWHM
tTFSWLM
SC2 (wl) output
tTXVM
tTXEM
tTXNVM
tTXHIM
First Bit
STD
Last Bit
SC0 output
tRFSBHM
tRFBLM
SC1 (bl) output
tRFSWHM
tRFSWLM
SC1 (wl) output
tSM
tHM
tTSM
tTHM
SRD
Figure 4-24 Master Mode Timing Diagram
56855 Technical Data, Rev. 6
Freescale Semiconductor
37
Table 4-11 ESSI Slave Mode1 Switching Characteristics
Operating Conditions: VSS = VSSIO = VSSA = 0 V, VDD = 1.62-1.98V, VDDIO = VDDA = 3.0–3.6V, TA = –40° to +120°C, CL ≤ 50pF, fop = 120MHz
Parameter
Symbol
Min
Typ
Max
Units
fs
—
—
152
MHz
SCK period3
tSCKW
66.7
—
—
ns
SCK high time
tSCKH
33.44
—
—
ns
SCK low time
tSCKL
33.44
—
—
ns
—
—
4
—
ns
Delay from SCK high to SC2 (bl) high - Slave5
tTFSBHS
-1
—
29
ns
Delay from SCK high to SC2 (wl) high - Slave5
tTFSWHS
-1
—
29
ns
Delay from SC0 high to SC1 (bl) high - Slave5
tRFSBHS
-1
—
29
ns
Delay from SC0 high to SC1 (wl) high - Slave5
tRFSWHS
-1
—
29
ns
Delay from SCK high to SC2 (bl) low - Slave5
tTFSBLS
-29
—
29
ns
Delay from SCK high to SC2 (wl) low - Slave5
tTFSWLS
-29
—
29
ns
Delay from SC0 high to SC1 (bl) low - Slave5
tRFSBLS
-29
—
29
ns
Delay from SC0 high to SC1 (wl) low - Slave5
tRFSWLS
-29
—
29
ns
SCK high to STD enable from high impedance - Slave
tTXES
—
—
15
ns
SCK high to STD valid - Slave
tTXVS
4
—
15
ns
SC2 high to STD enable from high impedance (first bit) - Slave
tFTXES
4
—
15
ns
SC2 high to STD valid (first bit) - Slave
tFTXVS
4
—
15
ns
SCK high to STD not valid - Slave
tTXNVS
4
—
15
ns
SCK high to STD high impedance - Slave
tTXHIS
4
—
15
ns
SRD Setup time before SC0 low - Slave
tSS
4
—
—
ns
SRD Hold time after SC0 low - Slave
tHS
4
—
—
ns
SCK frequency
Output clock rise/fall time
Synchronous Operation (in addition to standard external clock parameters)
SRD Setup time before SCK low - Slave
tTSS
4
—
—
ns
SRD Hold time after SCK low - Slave
tTHS
4
—
—
ns
1. Slave mode is externally generated clocks and frame syncs
2. Max clock frequency is IP_clk/4 = 60MHz / 4 = 15MHz for a 120MHz part.
56855 Technical Data, Rev. 6
38
Freescale Semiconductor
Enhanced Synchronous Serial Interface (ESSI) Timing
3. All the timings for the ESSI are given for a non-inverted serial clock polarity (TSCKP=0 in SCR2 and RSCKP=0 in SCSR)
and a non-inverted frame sync (TFSI=0 in SCR2 and RFSI=0 in SCSR). If the polarity of the clock and/or the frame sync have
been inverted, all the timings remain valid by inverting the clock signal SCK/SC0 and/or the frame sync SC2/SC1 in the tables
and in the figures.
4. 50 percent duty cycle
5. bl = bit length; wl = word length
tSCKW
tSCKH
tSCKL
SCK input
tTFSBLS
tTFSBHS
SC2 (bl) input
tTFSWHS
tTFSWLS
SC2 (wl) input
tFTXVS
tFTXES
tTXNVS
tTXVS
tTXES
tTXHIS
First Bit
STD
SC0 input
Last Bit
tRFBLS
tRFSBHS
SC1 (bl) input
tRFSWHS
tRFSWLS
SC1 (wl) input
tSS
tHS
tTSS
tTHS
SRD
Figure 4-25 Slave Mode Clock Timing
56855 Technical Data, Rev. 6
Freescale Semiconductor
39
4.11 Serial Communication Interface (SCI) Timing
Table 4-12 SCI Timing4
Operating Conditions: VSS = VSSIO = VSSA = 0 V, VDD = 1.62-1.98V, VDDIO = VDDA = 3.0–3.6V, TA = –40° to +120°C, CL ≤ 50pF, fop = 120MHz
Characteristic
Symbol
Min
Max
Unit
BR
—
(fMAX)/(32)
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 4-26 RXD Pulse Width
TXD
SCI receive
data pin
(Input)
TXDPW
Figure 4-27 TXD Pulse Width
56855 Technical Data, Rev. 6
40
Freescale Semiconductor
JTAG Timing
4.12 JTAG Timing
Table 4-13 JTAG Timing1, 3
Operating Conditions: VSS = VSSIO = VSSA = 0 V, VDD = 1.62-1.98V, VDDIO = VDDA = 3.0–3.6V, TA = –40° to +120°C, CL ≤ 50pF, fop = 120MHz
Characteristic
Symbol
Min
Max
Unit
TCK frequency of operation2
fOP
DC
30
MHz
TCK cycle time
tCY
33.3
—
ns
TCK clock pulse width
tPW
16.6
—
ns
TMS, TDI data setup time
tDS
3
—
ns
TMS, TDI data hold time
tDH
3
—
ns
TCK low to TDO data valid
tDV
—
12
ns
TCK low to TDO tri-state
tTS
—
10
ns
tTRST
35
—
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 120MHz operation,
T = 8.33ns.
2. TCK frequency of operation must be less than 1/4 the processor rate.
3. Parameters listed are guaranteed by design.
tCY
tPW
tPW
VIH
VM
TCK
(Input)
VM = VIL + (VIH – VIL)/2
VM
VIL
Figure 4-28 Test Clock Input Timing Diagram
56855 Technical Data, Rev. 6
Freescale Semiconductor
41
TCK
(Input)
tDS
TDI
TMS
(Input)
tDH
Input Data Valid
tDV
TDO
(Output)
Output Data Valid
tTS
TDO
(Output)
Figure 4-29 Test Access Port Timing Diagram
TRST
(Input)
tTRST
Figure 4-30 TRST Timing Diagram
DE
tDE
Figure 4-31 Enhanced OnCE—Debug Event
56855 Technical Data, Rev. 6
42
Freescale Semiconductor
GPIO Timing
4.13 GPIO Timing
Table 4-14 GPIO Timing1, 2
Operating Conditions: VSS = VSSIO = VSSA = 0 V, VDD = 1.62-1.98V, VDDIO = VDDA = 3.0–3.6V, TA = –40° to +120°C, CL ≤ 50pF, fop = 120MHz
Characteristic
Symbol
Min
Max
Unit
PIN
2T + 3
—
ns
GPIO input high/low period
PINHL
1T + 3
—
ns
GPIO output period
POUT
2T - 3
—
ns
POUTHL
1T - 3
—
ns
GPIO input period
GPIO output high/low period
1.
In the formulas listed, T = clock cycle. For fop = 120MHz operation and fipb = 60MHz, T = 8.33ns
2.
Parameters listed are guaranteed by design.
GPIO Inputs
PIN
PINHL
PINHL
POUT
POUTHL
POUTHL
GPIO Outputs
Figure 4-32 GPIO Timing
56855 Technical Data, Rev. 6
Freescale Semiconductor
43
Part 5 Packaging
5.1 Package and Pin-Out Information 56855
D15
D14
D13
VSSIO
VDDIO
D12
D11
SC02
SC01
SC00
SCK0
SRD0
STD0
VSSIO
VDDIO
VSS
VDD
D10
D9
D8
D7
D6
VSSIO
TIO0
VDDIO
This section contains package and pin-out information for the 100-pin LQFP configuration of the 56855.
PIN 76
PIN 1
ORIENTATION
MARK
PIN 51
PIN 26
TXD1
RXD1
VSSIO
VDDIO
D5
D4
D3
D2
D1
VSS
VDD
CS3
CS2
CS1
CS0
VSSIO
D0
VDDIO
A20
A19
A18
A17
A16
TXDO
RXD0
CLKO
RSTO
RESET
VDDIO
VSSIO
A8
A9
A10
A11
VDD
VSS
DE
TRST
TDO
TDI
TMS
TCK
VDDIO
VSSIO
A12
A13
A14
A15
VDDIO
VSSIO
VDDIO
VSSIO
RD
WR
A0
A1
A2
A3
VDD
VSS
MODA
MODB
MODC
VDDIO
VSSIO
IRQA
IRQB
VDDA
VSSA
XTAL
EXTAL
A4
A5
A6
A7
Figure 5-1 Top View, 56855 100-pin LQFP Package
56855 Technical Data, Rev. 6
44
Freescale Semiconductor
Package and Pin-Out Information 56855
Table 5-1 56855 Pin Identification By Pin Number
Pin No.
Signal Name
Pin No.
Signal Name
Pin No.
Signal Name
Pin No.
Signal Name
1
VDDIO
26
CLKO
51
RXD0
76
VDDIO
2
VSSIO
27
RSTO
52
TXD0
77
TIO0
3
RD
28
RESET
53
A16
78
VSSIO
4
WR
29
VDDIO
54
A17
79
D6
5
A0
30
VSSIO
55
A18
80
D7
6
A1
31
A8
56
A19
81
D8
7
A2
32
A9
57
A20
82
D9
8
A3
33
A10
58
VDDIO
83
D10
9
VDD
34
A11
59
D0
84
VDD
10
VSS
35
VDD
60
VSSIO
85
VSS
11
MODA
36
VSS
61
CS0
86
VDDIO
12
MODB
37
DE
62
CS1
87
VSSIO
13
MODC
38
TRST
63
CS2
88
STD0
14
VDDIO
39
TDO
64
CS3
89
SRD0
15
VSSIO
40
TDI
65
VDD
90
SCK0
16
IRQA
41
TMS
66
VSS
91
SC00
17
IRQB
42
TCK
67
D1
92
SC01
18
VDDA
43
VDDIO
68
D2
93
SC02
19
VSSA
44
VSSIO
69
D3
94
D11
20
XTAL
45
A12
70
D4
95
D12
21
EXTAL
46
A13
71
D5
96
VDDIO
22
A4
47
A14
72
VDDIO
97
VSSIO
23
A5
48
A15
73
VSSIO
98
D13
24
A6
49
VDDIO
74
RXD1
99
D14
25
A7
50
VSSIO
75
TXD1
100
D15
56855 Technical Data, Rev. 6
Freescale Semiconductor
45
S
0.15 (0.006)S
AC T-U
Z
S
S
-T-
AC Z
B
-Z-
0.15
0.15 (0.006)S
(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 INCHES
DIM MIN MAX MIN MAX
A 13.950 14.050 0.549 0.553
B 13.950 14.050 0.549 0.553
C
1.400 1.600 0.055 0.063
D
0.170 0.270 0.007 0.011
E
1.350 1.450 0.053 0.057
F
0.170 0.230 0.007 0.009
G
0.500 BSC
0.020 BSC
H 0.050 0.150 0.002 0.006
J
0.090 0.200 0.004 0.008
K 0.500 0.700 0.020 0.028
M
12° REF
12° REF
N
0.090 0.160 0.004 0.006
Q
1°
5°
1°
5°
R
0.150 0.250 0.006 0.010
S 15.950 16.050 0.628 0.632
V 15.950 16.050 0.628 0.632
W
0.200 REF
0.008 REF
X
1.000 REF
0.039 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
W
Q°
K
X
0.20 (0.008)M AC T-U
S
Z
S
SECTION AE-AE
DETAIL AD
Figure 5-2 100-pin LQPF Mechanical Information
Please see www.freescale.com for the most current case outline.
56855 Technical Data, Rev. 6
46
Freescale Semiconductor
Thermal Design Considerations
Part 6 Design Considerations
6.1 Thermal Design Considerations
An estimation of the chip junction temperature, TJ, in °C can be obtained from the equation:
Equation 1:
TJ = TA + (PD x 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 = RθJC + RθCA
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.
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
across the surface.
Measure the thermal resistance from the junction to where the leads are attached to the case. This definition
is approximately equal to a junction to board thermal resistance.
Use the value obtained by the equation (TJ – TT)/PD where TT is the temperature of the package case
determined by a thermocouple.
56855 Technical Data, Rev. 6
Freescale Semiconductor
47
As noted above, the junction-to-case thermal resistances quoted in this data sheet are determined using the
first definition. From a practical standpoint, that value is also suitable for determining the junction
temperature from a case thermocouple reading in forced convection environments. In natural convection,
using the junction-to-case thermal resistance to estimate junction temperature from a thermocouple
reading on the case of the package will estimate a junction temperature slightly hotter than actual. Hence,
the new thermal metric, Thermal Characterization Parameter, or ΨJT, has been defined to be (TJ – TT)/PD.
This value gives a better estimate of the junction temperature in natural convection when using the surface
temperature of the package. Remember that surface temperature readings of packages are subject to
significant errors caused by inadequate attachment of the sensor to the surface and to errors caused by heat
loss to the sensor. The recommended technique is to attach a 40-gauge thermocouple wire and bead to the
top center of the package with thermally conductive epoxy.
6.2 Electrical Design Considerations
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.
Use the following list of considerations to assure correct operation:
•
Provide a low-impedance path from the board power supply to each VDD pin on the controller, and from the
board ground to each VSS (GND) pin.
•
The minimum bypass requirement is to place six 0.01–0.1 μF capacitors positioned as close as possible to
the package supply pins. The recommended bypass configuration is to place one bypass capacitor on each
of the ten VDD/VSS pairs, including VDDA/VSSA.
•
Ensure that capacitor leads and associated printed circuit traces that connect to the chip VDD and VSS (GND)
pins are less than 0.5 inch per capacitor lead.
•
Use at least a four-layer Printed Circuit Board (PCB) with two inner layers for VDD and GND.
•
Bypass the VDD and GND layers of the PCB with approximately 100 μF, preferably with a high-grade
capacitor such as a tantalum capacitor.
•
Because the device’s output signals have fast rise and fall times, PCB trace lengths should be minimal.
56855 Technical Data, Rev. 6
48
Freescale Semiconductor
Electrical Design Considerations
•
Consider all device loads as well as parasitic capacitance due to PCB traces when calculating capacitance.
This is especially critical in systems with higher capacitive loads that could create higher transient currents
in the VDD and GND circuits.
•
All inputs must be terminated (i.e., not allowed to float) using CMOS levels.
•
Take special care to minimize noise levels on the VDDA and VSSA pins.
•
When using Wired-OR mode on the SPI or the IRQx pins, the user must provide an external pull-up device.
•
Designs that utilize the TRST pin for JTAG port or Enhance OnCE module functionality (such as
development or debugging systems) should allow a means to assert TRST whenever RESET is asserted, as
well as a means to assert TRST independently of RESET. Designs that do not require debugging
functionality, such as consumer products, should tie these pins together.
•
The internal POR (Power on Reset) will reset the part at power on with reset asserted or pulled high but
requires that TRST be asserted at power on.
56855 Technical Data, Rev. 6
Freescale Semiconductor
49
Part 7 Ordering Information
Table 7-1 lists the pertinent information needed to place an order. Consult a Freescale Semiconductor
sales office or authorized distributor to determine availability and to order parts.
Table 7-1 56855 Ordering Information
Part
Supply
Voltage
Package Type
Pin
Count
Frequency
(MHz)
Order Number
DSP56855
1.8V, 3.3V
Low-Profile Quad Flat Pack (LQFP)
100
120
DSP56855BU120
DSP56855
1.8V, 3.3V
Low-Profile Quad Flat Pack (LQFP)
100
120
DSP56855BUE *
*This package is RoHS compliant.
56855 Technical Data, Rev. 6
50
Freescale Semiconductor
Electrical Design Considerations
56855 Technical Data, Rev. 6
Freescale Semiconductor
51
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DSP56855
Rev. 6
01/2007