AD ADSP-BF539BBCZ-5F4

Blackfin
Embedded Processor
ADSP-BF539/ADSP-BF539F
FEATURES
External memory controller with glueless support
for SDRAM, SRAM, flash, and ROM
Flexible memory booting options from SPI and external
memory
1.0 V to 1.25 V core VDD with on-chip voltage regulation
3.0 V to 3.3 V I/O VDD
Up to 3.3 V tolerant I/O with specific 5 V tolerant pins
316-ball Pb-free CSP_BGA package
Up to 533 MHz high performance Blackfin processor
Two 16-bit MACs, two 40-bit ALUs, four 8-bit video ALUs,
40-bit shifter
RISC-like register and instruction model for ease of
programming and compiler friendly support
Advanced debug, trace, and performance monitoring
PERIPHERALS
Parallel peripheral interface (PPI),
supporting ITU-R 656 video data formats
4 dual-channel, full-duplex synchronous serial ports, supporting 16 stereo I2S channels
2 DMA controllers supporting 26 peripheral DMAs
4 memory-to-memory DMAs
Controller area network (CAN) 2.0B controller
Media transceiver (MXVR) for connection
to a MOST network
3 SPI-compatible ports
Three 32-bit timer/counters with PWM support
3 UARTs with support for IrDA
2 TWI controllers compatible with I2C industry standard
Up to 38 general-purpose I/O pins (GPIO)
Up to 16 general-purpose flag pins (GPF)
Real-time clock, watchdog timer, and 32-bit core timer
On-chip PLL capable of 0.5 to 64 frequency multiplication
Debug/JTAG interface
MEMORY
148K bytes of on-chip memory:
16K bytes of instruction SRAM/cache
64K bytes of instruction SRAM
32K bytes of data SRAM
32K bytes of data SRAM/cache
4K bytes of scratchpad SRAM
512K 16-bit or 256K 16-bit flash memory
(ADSP-BF539F only)
Memory management unit providing memory protection
JTAG TEST AND EMULATION
VOLTAGE REGULATOR
B
TWI0-1
GPIO
PORT
E
DMA
CONTROLLER1
SPI1-2
UART1-2
SPORT2-3
DMA CORE
BUS 1
L1 INSTRUCTION
MEMORY
L1 DATA
MEMORY
DMA
EXTERNAL
BUS 1
DMA CORE BUS 0
DMA
EXTERNAL
BUS 0
EXTERNAL PORT
FLASH, SDRAM CONTROL
WATCHDOG
TIMER
RTC
PPI
DMA
CONTROLLER 0
DMA ACCESS BUS 0
GPIO
PORT
D
INTERRUPT
CONTROLLER
DMA CORE
BUS 2
MXVR
DMA ACCESS BUS 1
GPIO
PORT
C
CAN 2.0B
PERIPHERAL ACCESS BUS
PERIPHERAL ACCESS BUS
TIMER0-2
GPIO
PORT
F
SPI0
UART0
SPORT0-1
16
512kB OR 1MB
FLASH MEMORY
BOOT ROM
(ADSP-BF539F ONLY)
Figure 1. Functional Block Diagram
Blackfin and the Blackfin logo are registered trademarks of Analog Devices, Inc.
Rev. A
Information furnished by Analog Devices is believed to be accurate and reliable.
However, no responsibility is assumed by Analog Devices for its use, nor for any
infringements of patents or other rights of third parties that may result from its use.
Specifications subject to change without notice. No license is granted by implication
or otherwise under any patent or patent rights of Analog Devices. Trademarks and
registered trademarks are the property of their respective owners.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106 U.S.A.
Tel: 781.329.4700
www.analog.com
Fax: 781.461.3113
©2008 Analog Devices, Inc. All rights reserved.
ADSP-BF539/ADSP-BF539F
TABLE OF CONTENTS
General Description ................................................. 3
Specifications ........................................................ 26
Low Power Architecture ......................................... 3
Operating Conditions ........................................... 26
Automotive Products ............................................. 3
Electrical Characteristics ....................................... 27
System Integration ................................................ 3
Absolute Maximum Ratings ................................... 28
ADSP-BF539/ADSP-BF539F Processor Peripherals ....... 3
Package Information ............................................ 28
Blackfin Processor Core .......................................... 4
ESD Sensitivity ................................................... 28
Memory Architecture ............................................ 4
Timing Specifications ........................................... 29
DMA Controllers .................................................. 9
Clock and Reset Timing ..................................... 30
Real-Time Clock ................................................... 9
Asynchronous Memory Read Cycle Timing ............ 31
Watchdog Timer .................................................. 9
Asynchronous Memory Write Cycle Timing ........... 33
Timers ............................................................. 10
SDRAM Interface Timing .................................. 35
Serial Ports (SPORTs) .......................................... 10
External Port Bus Request and Grant Cycle Timing .. 36
Serial Peripheral Interface (SPI) Ports ...................... 10
Parallel Peripheral Interface Timing ...................... 38
2-Wire Interface ................................................. 11
Serial Ports Timing ........................................... 41
UART Ports ...................................................... 11
Serial Peripheral Interface Ports—Master Timing ..... 44
Programmable I/O Pins ........................................ 11
Serial Peripheral Interface Ports—Slave Timing ....... 45
Parallel Peripheral Interface ................................... 12
General-Purpose Port Timing ............................. 46
Controller Area Network (CAN) Interface ................ 13
Timer Cycle Timing .......................................... 47
Media Transceiver MAC layer (MXVR) ................... 13
JTAG Test And Emulation Port Timing ................. 48
Dynamic Power Management ................................ 13
MXVR Timing ................................................ 49
Voltage Regulation .............................................. 15
Output Drive Currents ......................................... 50
Clock Signals ..................................................... 15
Power Dissipation ............................................... 52
Booting Modes ................................................... 16
Test Conditions .................................................. 52
Instruction Set Description ................................... 17
Thermal Characteristics ........................................ 55
Development Tools ............................................. 17
316-Ball CSP_BGA Ball Assignment ........................... 56
Designing an Emulator Compatible Processor Board ... 18
Outline Dimensions ................................................ 59
Example Connections and Layout Considerations ...... 18
Surface-Mount Design .......................................... 60
Voltage Regulator Layout Guidelines ....................... 20
Ordering Guide ..................................................... 60
MXVR Board Layout Guidelines ............................ 19
Pin Descriptions .................................................... 21
REVISION HISTORY
2/08—Rev. 0 to Rev. A
Identifying pins CANRX and PC4 as 5 V-tolerant when configured as an input and an open-drain when configured as an
output.
Rev. A |
Page 2 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
GENERAL DESCRIPTION
The ADSP-BF539/ADSP-BF539F processors are members of
the Blackfin® family of products, incorporating the Analog
Devices, Inc./Intel Micro Signal Architecture (MSA). Blackfin
processors combine a dual-MAC, state-of-the-art signal processing engine, the advantages of a clean, orthogonal RISC-like
microprocessor instruction set, and single-instruction, multiple-data (SIMD) multimedia capabilities into a single
instruction set architecture.
The ADSP-BF539/ADSP-BF539F processors are completely
code compatible with other Blackfin processors, differing only
with respect to performance, peripherals, and on-chip memory.
Specific performance, peripherals, and memory configurations
are shown in Table 1 on Page 3.
Table 1. Processor Features
Feature
ADSP-BF539 ADSP-BF539F4 ADSP-BF539F8
SPORTs
4
4
4
UARTs
3
3
3
SPI
3
3
3
TWI
2
2
2
CAN
1
1
1
MXVR
1
1
1
PPI
1
1
1
Instruction
SRAM/Cache
16K bytes
16K bytes
16K bytes
Instruction
SRAM
64K bytes
64K bytes
64K bytes
Data
SRAM/Cache
32K bytes
32K bytes
32K bytes
Data SRAM
32K bytes
32K bytes
32K bytes
Scratchpad
4K bytes
4K bytes
4K bytes
Flash
Not
applicable
256K 16-bit
512K 16-bit
Maximum
Speed Grade
533 MHz
533 MHz
1066 MMACS 1066 MMACS
533 MHz
1066 MMACS
Package
Option
BC-316
BC-316
BC-316
AUTOMOTIVE PRODUCTS
Some ADSP-BF539/ADSP-BF539F models are available for
automotive applications with controlled manufacturing. Note
that these special models may have specifications that differ
from the general release models. For information on which
models are available for automotive applications, see “Ordering
Guide” on page 60.
SYSTEM INTEGRATION
The ADSP-BF539/ADSP-BF539F processors are highly integrated system-on-a-chip solutions for the next generation of
industrial and automotive applications including audio and
video signal processing. By combining advanced memory configurations, such as on-chip flash memory, with industrystandard interfaces with a high performance signal processing
core, users can develop cost-effective solutions quickly without
the need for costly external components. The system peripherals
include a MOST Network Media Transceiver (MXVR), three
UART ports, three SPI ports, four serial ports (SPORT), one
CAN interface, two 2-wire interfaces (TWI), four general-purpose timers (three with PWM capability), a real-time clock, a
watchdog timer, a parallel peripheral interface, general-purpose
I/O, and general-purpose flag pins.
ADSP-BF539/ADSP-BF539F PROCESSOR
PERIPHERALS
By integrating a rich set of industry-leading system peripherals
and memory, Blackfin processors are the platform of choice for
next generation applications that require RISC-like programmability, multimedia support, and leading edge signal
processing in one integrated package.
LOW POWER ARCHITECTURE
Blackfin processors provide world class power management and
performance. Blackfin processors are designed in a low power
and low voltage design methodology and feature dynamic
power management, the ability to vary both the voltage and frequency of operation to significantly lower overall power
consumption. Varying the voltage and frequency can result in a
Rev. A |
substantial reduction in power consumption, compared with
simply varying the frequency of operation. This translates into
longer battery life and lower heat dissipation.
Page 3 of 60 |
The ADSP-BF539/ADSP-BF539F processors contain a rich set
of peripherals connected to the core via several high bandwidth
buses, providing flexibility in system configuration as well as
excellent overall system performance (see Figure 1 on Page 1).
The general-purpose peripherals include functions such as
UART, timers with PWM (pulse-width modulation) and pulse
measurement capability, general-purpose flag I/O pins, a realtime clock, and a watchdog timer. This set of functions satisfies
a wide variety of typical system support needs and is augmented
by the system expansion capabilities of the device. In addition to
these general-purpose peripherals, the ADSP-BF539/ADSPBF539F processors contain high speed serial and parallel ports
for interfacing to a variety of audio, video, and modem codec
functions. An MXVR transceiver transmits and receives audio
and video data and control information on a MOST automotive
multimedia network. A CAN 2.0B controller is provided for
automotive control networks. An interrupt controller manages
interrupts from the on-chip peripherals or external sources.
And power management control functions tailor the performance and power characteristics of the processor and system to
many application scenarios.
All of the peripherals, except for general-purpose I/O, CAN,
TWI, real-time clock, and timers, are supported by a flexible
DMA structure. There are also four separate memory DMA
channels dedicated to data transfers between the processor’s
February 2008
ADSP-BF539/ADSP-BF539F
various memory spaces, including external SDRAM and asynchronous memory. Multiple on-chip buses running at up to
133 MHz provide enough bandwidth to keep the processor core
running along with activity on all of the on-chip and external
peripherals.
The ADSP-BF539/ADSP-BF539F processors include an on-chip
voltage regulator in support of the ADSP-BF539/ADSP-BF539F
processor dynamic power management capability. The voltage
regulator provides a range of core voltage levels from a single
2.7 V to 3.6 V input. The voltage regulator can be bypassed at
the user's discretion.
BLACKFIN PROCESSOR CORE
As shown in Figure 2, the Blackfin processor core contains two
16-bit multipliers, two 40-bit accumulators, two 40-bit ALUs,
four video ALUs, and a 40-bit shifter. The computation units
process 8-bit, 16-bit, or 32-bit data from the register file.
The compute register file contains eight 32-bit registers. When
performing compute operations on 16-bit operand data, the
register file operates as 16 independent 16-bit registers. All
operands for compute operations come from the multiported
register file and instruction constant fields.
Each MAC can perform a 16-bit by 16-bit multiply in each
cycle, accumulating the results into the 40-bit accumulators.
Signed and unsigned formats, rounding, and saturation are
supported.
The ALUs perform a traditional set of arithmetic and logical
operations on 16-bit or 32-bit data. In addition, many special
instructions are included to accelerate various signal processing
tasks. These include bit operations such as field extract and population count, modulo 232 multiply, divide primitives, saturation
and rounding, and sign/exponent detection. The set of video
instructions include byte alignment and packing operations, 16bit and 8-bit adds with clipping, 8-bit average operations, and 8bit subtract/absolute value/accumulate (SAA) operations. Also
provided are the compare/select and vector search instructions.
For certain instructions, two 16-bit ALU operations can be performed simultaneously on register pairs (a 16-bit high half and
16-bit low half of a compute register). By also using the second
ALU, quad 16-bit operations are possible.
The 40-bit shifter can perform shifts and rotates and is used to
support normalization, field extract, and field deposit
instructions.
The program sequencer controls the flow of instruction execution, including instruction alignment and decoding. For
program flow control, the sequencer supports PC relative and
indirect conditional jumps (with static branch prediction), and
subroutine calls. Hardware is provided to support zero overhead looping. The architecture is fully interlocked, meaning that
the programmer need not manage the pipeline when executing
instructions with data dependencies.
The address arithmetic unit provides two addresses for simultaneous dual fetches from memory. It contains a multiported
register file consisting of four sets of 32-bit index, modify,
Rev. A |
Page 4 of 60 |
length, and base registers (for circular buffering), and eight
additional 32-bit pointer registers (for C-style indexed stack
manipulation).
Blackfin processors support a modified Harvard architecture in
combination with a hierarchical memory structure. Level 1 (L1)
memories are those that typically operate at the full processor
speed with little or no latency. At the L1 level, the instruction
memory holds instructions only. The two data memories hold
data, and a dedicated scratchpad data memory stores stack and
local variable information.
In addition, multiple L1 memory blocks are provided, offering a
configurable mix of SRAM and cache. The Memory Management Unit (MMU) provides memory protection for individual
tasks that can be operating on the core and can protect system
registers from unintended access.
The architecture provides three modes of operation: user mode,
supervisor mode, and emulation mode. User mode has
restricted access to certain system resources, thus providing a
protected software environment, while supervisor mode has
unrestricted access to the system and core resources.
The Blackfin processor instruction set has been optimized so
that 16-bit opcodes represent the most frequently used instructions, resulting in excellent compiled code density. Complex
DSP instructions are encoded into 32-bit opcodes, representing
fully featured multifunction instructions. Blackfin processors
support a limited multi-issue capability, where a 32-bit instruction can be issued in parallel with two 16-bit instructions,
allowing the programmer to use many of the core resources in a
single instruction cycle.
The Blackfin processor assembly language uses an algebraic syntax for ease of coding and readability. The architecture has been
optimized for use in conjunction with the C/C++ compiler,
resulting in fast and efficient software implementations.
MEMORY ARCHITECTURE
The ADSP-BF539/ADSP-BF539F processors view memory as a
single unified 4G byte address space, using 32-bit addresses. All
resources, including internal memory, external memory, and
I/O control registers, occupy separate sections of this common
address space. The memory portions of this address space are
arranged in a hierarchical structure to provide a good cost/performance balance of some very fast, low latency on-chip
memory as cache or SRAM, and larger, lower cost and performance off-chip memory systems. See Figure 3.
The L1 memory system is the primary highest performance
memory available to the Blackfin processor. The off-chip memory system, accessed through the external bus interface unit
(EBIU), provides expansion with SDRAM, flash memory, and
SRAM, optionally accessing up to 516M bytes of physical
memory.
The memory DMA controller provides high bandwidth data
movement capability. It performs block transfers of code or data
between the internal memory and the external memory spaces.
February 2008
ADSP-BF539/ADSP-BF539F
ADDRESS ARITHMETIC UNIT
32
DA0
32
L3
B3
M3
I2
L2
B2
M2
I1
L1
B1
M1
I0
L0
B0
M0
SP
FP
P5
DAG1
P4
P3
DAG0
P2
P1
P0
TO MEMORY
DA1
I3
32
PREG
32
RAB
SD
LD1
LD0
32
32
32
ASTAT
32
32
SEQUENCER
R7.H
R6.H
R7.L
R6.L
R5.H
R5.L
R4.H
R4.L
R3.H
R3.L
R2.H
R2.L
R1.H
R1.L
R0.H
R0.L
16
ALIGN
16
8
8
8
8
DECODE
BARREL
SHIFTER
40
40
A0
32
40
40
A1
LOOP BUFFER
CONTROL
UNIT
32
DATA ARITHMETIC UNIT
Figure 2. Blackfin Processor Core
Internal (On-Chip) Memory
The ADSP-BF539/ADSP-BF539F processor has three blocks of
on-chip memory providing high bandwidth access to the core.
The first is the L1 instruction memory, consisting of 80K bytes
SRAM, of which 16K bytes can be configured as a four-way setassociative cache. This memory is accessed at full
processor speed.
The second on-chip memory block is the L1 data memory, consisting of two banks of up to 32K bytes each. Each memory bank
is configurable, offering both cache and SRAM functionality.
This memory block is accessed at full processor speed.
The third memory block is a 4K byte scratch pad SRAM which
runs at the same speed as the L1 memories, but is only accessible
as data SRAM and cannot be configured as cache memory.
External (Off-Chip) Memory
The PC133-compliant SDRAM controller can be programmed
to interface to up to 512M bytes of SDRAM. The SDRAM controller allows one row to be open for each internal SDRAM
bank, for up to four internal SDRAM banks, improving overall
system performance.
The asynchronous memory controller can be programmed to
control up to four banks of devices with very flexible timing
parameters for a wide variety of devices. Each bank occupies a
1M byte segment regardless of the size of the devices used, so
that these banks will only be contiguous if each is fully populated with 1M byte of memory.
Flash Memory (ADSP-BF539F Only)
The ADSP-BF539F4 and ADSP-BF539F8 processors contain a
separate flash die, connected to the EBIU bus, within the package of the ADSP-BF539F processors. Figure 4 shows how the
flash memory die and Blackfin processor die are connected.
External memory is accessed via the EBIU. This 16-bit interface
provides a glueless connection to a bank of synchronous DRAM
(SDRAM) as well as up to four banks of asynchronous memory
devices including flash, EPROM, ROM, SRAM, and memory
mapped I/O devices.
Rev. A |
Page 5 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
The ADSP-BF539F4 contains a 4M bit (256K 16-bit) bottom
boot sector Spansion S29AL004D known good die flash memory†. The ADSP-BF539F8 contains an 8M bit (512K 16-bit)
bottom boot sector Spansion S29AL008D known good die flash
memory. Features include the following:
0xFFFF FFFF
CORE MMR REGISTERS (2M BYTE)
0xFFE0 0000
SYSTEM MMR REGISTERS (2M BYTE)
0xFFC0 0000
RESERVED
0xFFB0 1000
SCRATCHPAD SRAM (4K BYTE)
• Access times as fast as 70 ns (EBIU registers be set
appropriately)
INTERNAL MEMORY MAP
0xFFB0 0000
RESERVED
0xFFA1 4000
INSTRUCTION SRAM / CACHE (16K BYTE)
0xFFA1 0000
INSTRUCTION SRAM (64K BYTE)
0xFFA0 0000
RESERVED
0xFF90 8000
DATA BANK B SRAM / CACHE (16K BYTE)
0xFF90 4000
DATA BANK B SRAM (16K BYTE)
• Sector protection
• One million write cycles per sector
• 20 year data retention
The Blackfin processor connects to the flash memory die with
address, data, chip enable, write enable, and output enable controls as if it were an external memory device.
0xFF90 0000
RESERVED
0xFF80 8000
DATA BANK A SRAM / CACHE (16K BYTE)
The flash chip enable pin FCE must be connected to AMS0 or
AMS3–1 through a printed circuit board trace. When connected
to AMS0, the Blackfin processor can boot from the flash die.
When connected to AMS3–1, the flash memory will appear as
nonvolatile memory in the processor memory map, shown in
Figure 3 on Page 6.
0xFF80 4000
DATA BANK A SRAM (16K BYTE)
0xFF80 0000
RESERVED
0xEF00 0000
EXTERNAL MEMORY MAP
RESERVED
0x2040 0000
ASYNC MEMORY BANK 3 (1M BYTE) OR
ON-CHIP FLASH (ADSP-BF539F ONLY)
0x2030 0000
0x2020 0000
ASYNC MEMORY BANK 2 (1M BYTE) OR
ON-CHIP FLASH (ADSP-BF539F ONLY)
ASYNC MEMORY BANK 1 (1M BYTE) OR
ON-CHIP FLASH (ADSP-BF539F ONLY)
0x2010 0000
0x2000 0000
ASYNC MEMORY BANK 0 (1M BYTE) OR
ON-CHIP FLASH (ADSP-BF539F ONLY)
Flash Memory Programming
The ADSP-BF539F4 and ADSP-BF539F8 flash memory can be
programmed before or after mounting on the printed
circuit board.
RESERVED
0x0800 0000
SDRAM MEMORY (16M BYTE TO 512M BYTE)
0x0000 0000
ADDR19-1
ARE
AWE
ARDY
DATA15-0
The VisualDSP++‡ tools can be used to program the flash memory after the device is mounted on a printed circuit board.
A18-0
OE
WE
RY/BY
DQ15-0
VSS
VCC
BYTE
CE
RESET
GND
VDDEXT
AMS3-0
RESET
Flash Memory Sector Protection
To use the sector protection feature, a high voltage (+12 V nominal) must be applied to the flash FRESET pin. Refer to the flash
data sheet for details.
FLASH DIE
BLACKFIN DIE
ADDR19-1
ARE
AWE
ARDY
DATA15-0
GND
VDDEXT
Figure 3. ADSP-BF539/ADSP-BF539F Internal/External Memory Map
I/O Memory Space
Blackfin processors do not define a separate I/O space. All
resources are mapped through the flat 32-bit address space. Onchip I/O devices have their control registers mapped into memory mapped registers (MMRs) at addresses near the top of the
4G byte address space. These are separated into two smaller
blocks, one of which contains the control MMRs for all core
functions, and the other of which contains the registers needed
for setup and control of the on-chip peripherals outside of the
core. The MMRs are accessible only in supervisor mode and
appear as reserved space to on-chip peripherals.
FCE
FRESET
RESET
ADSP-BF539F
PACKAGE
AMS3-0
To program the flash prior to mounting on the printed circuit
board, use a hardware programming tool that can provide the
data, address, and control stimuli to the flash die through the
external pins on the package. During this programming, VDDEXT
and GND must be provided to the package and the Blackfin
must be held in reset with bus request (BR) asserted and a
CLKIN provided.
Figure 4. Internal Connection of Flash Memory (ADSP-BF539Fx)
†
‡
Rev. A |
Page 6 of 60 |
Refer to the Spansion website for the appropriate data sheets.
VisualDSP++ is a registered trademark of Analog Devices, Inc.
February 2008
ADSP-BF539/ADSP-BF539F
Booting
Table 2. Core Event Controller (CEC)
The ADSP-BF539/ADSP-BF539F processor contains a small
boot kernel, which configures the appropriate peripheral for
booting. If the ADSP-BF539/ADSP-BF539F processor is configured to boot from boot ROM memory space, the processor
starts executing from the on-chip boot ROM. For more information, see Booting Modes on Page 16.
Priority
(0 is Highest)
Event Class
EVT Entry
0
Emulation/Test Control
EMU
1
Reset
RST
2
Nonmaskable Interrupt
NMI
Event Handling
3
Exception
EVX
The event controller on the ADSP-BF539/ADSP-BF539F processor handles all asynchronous and synchronous events to the
processor. The ADSP-BF539/ADSP-BF539F processor provides
event handling that supports both nesting and prioritization.
Nesting allows multiple event service routines to be active
simultaneously. Prioritization ensures that servicing of a higher
priority event takes precedence over servicing of a lower priority
event. The controller provides support for five different types of
events:
4
Reserved
—
5
Hardware Error
IVHW
6
Core Timer
IVTMR
7
General Interrupt 7
IVG7
8
General Interrupt 8
IVG8
9
General Interrupt 9
IVG9
10
General Interrupt 10
IVG10
11
General Interrupt 11
IVG11
12
General Interrupt 12
IVG12
13
General Interrupt 13
IVG13
14
General Interrupt 14
IVG14
15
General Interrupt 15
IVG15
• Emulation – An emulation event causes the processor to
enter emulation mode, allowing command and control of
the processor via the JTAG interface.
• Reset – This event resets the processor.
• Nonmaskable Interrupt (NMI) – The NMI event can be
generated by the software watchdog timer or by the NMI
input signal to the processor. The NMI event is frequently
used as a power-down indicator to initiate an orderly shutdown of the system.
• Exceptions – Events that occur synchronously to program
flow (i.e., the exception will be taken before the instruction
is allowed to complete). Conditions such as data alignment
violations and undefined instructions cause exceptions.
• Interrupts – Events that occur asynchronously to program
flow. They are caused by input pins, timers, and other
peripherals, as well as by an explicit software instruction.
System Interrupt Controllers (SIC)
The system interrupt controllers (SIC0, SIC1) provide the mapping and routing of events from the many peripheral interrupt
sources to the prioritized general-purpose interrupt inputs of
the CEC. Although the ADSP-BF539/ADSP-BF539F processors
provide a default mapping, the user can alter the mappings and
priorities of interrupt events by writing the appropriate values
into the interrupt assignment registers (SIC_IARx). Table 3
describes the inputs into the SICs and the default mappings into
the CEC.
Each event type has an associated register to hold the return
address and an associated return-from-event instruction. When
an event is triggered, the state of the processor is saved on the
supervisor stack.
Table 3. System and Core Event Mapping
Event Source
Core
Event Name
The ADSP-BF539/ADSP-BF539F processor’s event controller
consists of two stages, the core event controller (CEC) and the
system interrupt controllers (SIC). The core event controller
works with the system interrupt controllers to prioritize and
control all system events. Conceptually, interrupts from the
peripherals enter into one of the SIC, and are then routed
directly into the general-purpose interrupts of the CEC.
PLL Wake-up Interrupt
IVG7
DMA Controller 0 Error
IVG7
DMA Controller 1 Error
IVG7
Core Event Controller (CEC)
The CEC supports nine general-purpose interrupts (IVG15–7),
in addition to the dedicated interrupt and exception events. Of
these general-purpose interrupts, the two lowest priority interrupts (IVG15–14) are recommended to be reserved for software
interrupt handlers, leaving seven prioritized interrupt inputs to
support the peripherals of the ADSP-BF539/ADSP-BF539F processors. Table 2 describes the inputs to the CEC, identifies their
names in the event vector table (EVT), and lists their priorities.
Rev. A |
Page 7 of 60 |
PPI Error Interrupt
IVG7
SPORT0 Error Interrupt
IVG7
SPORT1 Error Interrupt
IVG7
SPORT2 Error Interrupt
IVG7
SPORT3 Error Interrupt
IVG7
MXVR Synchronous Data Interrupt
IVG7
SPI0 Error Interrupt
IVG7
SPI1 Error Interrupt
IVG7
SPI2 Error Interrupt
IVG7
UART0 Error Interrupt
IVG7
UART1 Error Interrupt
IVG7
February 2008
ADSP-BF539/ADSP-BF539F
Table 3. System and Core Event Mapping (Continued)
Event Source
Core
Event Name
UART2 Error Interrupt
IVG7
CAN Error Interrupt
IVG7
Real-Time Clock Interrupt
IVG8
DMA0 Interrupt (PPI)
IVG8
DMA1 Interrupt (SPORT0 Rx)
IVG9
DMA2 Interrupt (SPORT0 Tx)
IVG9
DMA3 Interrupt (SPORT1 Rx)
IVG9
DMA4 Interrupt (SPORT1 Tx)
IVG9
DMA8 Interrupt (SPORT2 Rx)
IVG9
DMA9 Interrupt (SPORT2 Tx)
IVG9
DMA10 Interrupt (SPORT3 Rx)
IVG9
DMA11 Interrupt (SPORT3 Tx)
IVG9
DMA5 Interrupt (SPI0)
IVG10
DMA14 Interrupt (SPI1)
IVG10
DMA15 Interrupt (SPI2)
IVG10
DMA6 Interrupt (UART0 Rx)
IVG10
DMA7 Interrupt (UART0 Tx)
IVG10
DMA16 Interrupt (UART1 Rx)
IVG10
DMA17 Interrupt (UART1 Tx)
IVG10
DMA18 Interrupt (UART2 Rx)
IVG10
DMA19 Interrupt (UART2 Tx)
IVG10
Timer0, Timer1, Timer2 Interrupts
IVG11
TWI0 Interrupt
IVG11
TWI1 Interrupt
IVG11
CAN Receive Interrupt
IVG11
CAN Transmit Interrupt
IVG11
MXVR Status Interrupt
IVG11
MXVR Control Message Interrupt
IVG11
MXVR Asynchronous Packet Interrupt
IVG11
Programmable Flags Interrupts
IVG12
MDMA0 Stream 0 Interrupt
IVG13
MDMA0 Stream 1 Interrupt
IVG13
MDMA1 Stream 0 Interrupt
IVG13
MDMA1 Stream 1 Interrupt
IVG13
Software Watchdog Timer
IVG13
• CEC Interrupt Mask Register (IMASK) – The IMASK register controls the masking and unmasking of individual
events. When a bit is set in the IMASK register, that event is
unmasked and will be processed by the CEC when asserted.
A cleared bit in the IMASK register masks the event,
preventing the processor from servicing the event even
though the event can be latched in the ILAT register. This
register can be read or written while in supervisor mode.
(Note that general-purpose interrupts can be globally
enabled and disabled with the STI and CLI instructions,
respectively.)
• CEC Interrupt Pending Register (IPEND) – The IPEND
register keeps track of all nested events. A set bit in the
IPEND register indicates whether the event is currently
active or nested at some level. This register is updated automatically by the controller but can be read while in
supervisor mode.
Each SIC allows further control of event processing by providing three 32-bit interrupt control and status registers. Each
register contains a bit corresponding to each of the peripheral
interrupt events shown in Table 3 on Page 7.
• SIC Interrupt Mask Registers (SIC_IMASKx)– These registers control the masking and unmasking of each peripheral
interrupt event. When a bit is set in these registers, that
peripheral event is unmasked and will be processed by the
system when asserted. A cleared bit in these registers masks
the peripheral event, preventing the processor from servicing the event.
• SIC Interrupt Status Registers (SIC_ISRx) – As multiple
peripherals can be mapped to a single event, these registers
allow the software to determine which peripheral event
source triggered the interrupt. A set bit indicates that the
peripheral is asserting the interrupt, and a cleared bit indicates that the peripheral is not asserting the event.
• SIC Interrupt Wake-up Enable Registers (SIC_IWRx) – By
enabling the corresponding bit in these registers, a peripheral can be configured to wake up the processor, should the
core be idled when the event is generated. (For more information, see Dynamic Power Management on Page 13.)
Event Control
The ADSP-BF539/ADSP-BF539F processors provide the user
with a very flexible mechanism to control the processing of
events. In the CEC, three registers are used to coordinate and
control events. Each register is 16 bits wide:
• CEC Interrupt Latch Register (ILAT) – The ILAT register
indicates when events have been latched. The appropriate
bit is set when the processor has latched the event and is
Rev. A |
cleared when the event has been accepted into the system.
This register is updated automatically by the controller, but
it can also be written to clear (cancel) latched events. This
register may be read while in supervisor mode and may
only be written while in supervisor mode when the corresponding IMASK bit is cleared.
Page 8 of 60 |
Because multiple interrupt sources can map to a single generalpurpose interrupt, multiple pulse assertions can occur simultaneously, before or during interrupt processing for an interrupt
event already detected on this interrupt input. The IPEND register contents are monitored by the SIC as the interrupt
acknowledgement.
The appropriate ILAT register bit is set when an interrupt rising
edge is detected (detection requires two core clock cycles). The
bit is cleared when the respective IPEND register bit is set. The
IPEND bit indicates that the event has entered into the processor pipeline. At this point the CEC will recognize and queue the
February 2008
ADSP-BF539/ADSP-BF539F
next rising edge event on the corresponding event input. The
minimum latency from the rising edge transition of the generalpurpose interrupt to the IPEND output asserted is three core
clock cycles; however, the latency can be much higher, depending on the activity within and the state of the processor.
DMA CONTROLLERS
The ADSP-BF539/ADSP-BF539F processor has multiple, independent DMA controllers that support automated data transfers
with minimal overhead for the processor core. DMA transfers
can occur between the ADSP-BF539/ADSP-BF539F processor
internal memories and any of its DMA capable peripherals.
Additionally, DMA transfers can be accomplished between any
of the DMA-capable peripherals and external devices connected
to the external memory interfaces, including the SDRAM controller and the asynchronous memory controller. DMA capable
peripherals include the SPORTs, SPI ports, UARTs, and PPI.
Each individual DMA capable peripheral has at least one dedicated DMA channel. In addition, the MXVR peripheral has its
own dedicated DMA controller, which supports its own unique
set of operating modes.
The ADSP-BF539/ADSP-BF539F processor DMA controllers
support both 1-dimensional (1-D) and 2-dimensional (2-D)
DMA transfers. DMA transfer initialization can be implemented from registers or from sets of parameters called
descriptor blocks.
The 2-D DMA capability supports arbitrary row and column
sizes up to 64K elements by 64K elements and arbitrary row and
column step sizes up to ±32K elements. Furthermore, the column step size can be less than the row step size, allowing
implementation of interleaved data streams. This feature is
especially useful in video applications where data can be
deinterleaved on the fly.
32.768 kHz crystal external to the ADSP-BF539/ADSP-BF539F
processors. The RTC peripheral has dedicated power supply
pins so that it can remain powered up and clocked even when
the rest of the processor is in a low power state. The RTC provides several programmable interrupt options, including
interrupt per second, minute, hour, or day clock ticks, interrupt
on programmable stopwatch countdown, or interrupt at a programmed alarm time.
The 32.768 kHz input clock frequency is divided down to a 1 Hz
signal by a prescaler. The counter function of the timer consists
of four counters: a 60-second counter, a 60-minute counter, a
24-hour counter, and an 32,768-day counter.
When enabled, the alarm function generates an interrupt when
the output of the timer matches the programmed value in the
alarm control register. There are two alarms: the first alarm is
for a time of day. The second alarm is for a day and time of
that day.
The stopwatch function counts down from a programmed
value, with one second resolution. When the stopwatch is
enabled and the counter underflows, an interrupt is generated.
Like the other peripherals, the RTC can wake up the ADSPBF539/ADSP-BF539F processor from sleep mode upon generation of any RTC wake-up event. Additionally, an RTC wake-up
event can wake up the ADSP-BF539/ADSP-BF539F processor
from deep sleep mode, and wake up the on-chip internal voltage
regulator from a powered down state.
Connect RTC pins RTXI and RTXO with external components
as shown in Figure 5.
RTXI
Examples of DMA types supported by the ADSP-BF539/ADSPBF539F processors DMA controller include:
• A single, linear buffer that stops upon completion
RTXO
R1
X1
C1
C2
• A circular, auto-refreshing buffer that interrupts on each
full or fractionally full buffer
• 1-D or 2-D DMA using a linked list of descriptors
• 2-D DMA using an array of descriptors, specifying only the
base DMA address within a common page
In addition to the dedicated peripheral DMA channels, there are
four memory DMA channels provided for transfers between the
various memories of the ADSP-BF539/ADSP-BF539F processor
system. This enables transfers of blocks of data between any of
the memories—including external SDRAM, ROM, SRAM, and
flash memory—with minimal processor intervention. Memory
DMA transfers can be controlled by a very flexible descriptorbased methodology or by a standard register-based autobuffer
mechanism.
REAL-TIME CLOCK
The ADSP-BF539/ADSP-BF539F processor real-time clock
(RTC) provides a robust set of digital watch features, including
current time, stopwatch, and alarm. The RTC is clocked by a
Rev. A |
Page 9 of 60 |
SUGGESTED COMPONENTS:
ECLIPTEK EC38J (THROUGH-HOLE PACKAGE)
EPSON MC405 12 pF LOAD (SURFACE-MO UNT PACKAGE)
C1 = 22pF
C2 = 22pF
R1 = 10MΩ
NOTE: C1 AND C2 ARE SPECIFIC TO CRYSTAL SPECI FIED FOR X1.
CONTACT CRYSTAL MANUFACTURER FOR DETAILS. C1 AND C2
SPECIFI CATIONS ASSUME BOARD TRACE CAPACITANCE OF 3pF.
Figure 5. External Components for RTC
WATCHDOG TIMER
The ADSP-BF539/ADSP-BF539F processors include a 32-bit
timer that can be used to implement a software watchdog function. A software watchdog can improve system availability by
forcing the processor to a known state through generation of a
hardware reset, nonmaskable interrupt (NMI), or general-purpose interrupt, if the timer expires before being reset by
software. The programmer initializes the count value of the
February 2008
ADSP-BF539/ADSP-BF539F
• Framing – Each transmit and receive port can run with or
without frame sync signals for each data word. Frame sync
signals can be generated internally or externally, active high
or low, and with either of two pulse widths and early or late
frame sync.
timer, enables the appropriate interrupt, and then enables the
timer. Thereafter, the software must reload the counter before it
counts to zero from the programmed value. This protects the
system from remaining in an unknown state where software,
which would normally reset the timer, has stopped running due
to an external noise condition or software error.
• Companding in hardware – Each SPORT can perform
A-law or μ-law companding according to ITU recommendation G.711. Companding can be selected on the transmit
and/or receive channel of the SPORT without additional
latencies.
If configured to generate a hardware reset, the watchdog timer
resets both the core and the ADSP-BF539/ADSP-BF539F processor peripherals. After a reset, software can determine if the
watchdog was the source of the hardware reset by interrogating
a status bit in the watchdog timer control register.
• DMA operations with single-cycle overhead – Each SPORT
can automatically receive and transmit multiple buffers of
memory data. The processor can link or chain sequences of
DMA transfers between a SPORT and memory.
The timer is clocked by the system clock (SCLK), at a maximum
frequency of fSCLK.
TIMERS
• Interrupts – Each transmit and receive port generates an
interrupt upon completing the transfer of a data word or
after transferring an entire data buffer or buffers through
DMA.
There are four general-purpose programmable timer units in
the ADSP-BF539/ADSP-BF539F processors. Three timers have
an external pin that can be configured either as a pulse-width
modulator (PWM) or timer output, as an input to clock the
timer, or as a mechanism for measuring pulse widths and periods of external events. These timers can be synchronized to an
external clock input to the PF1 pin (TACLK), an external clock
input to the PPI_CLK pin (TMRCLK), or to the internal SCLK.
SERIAL PERIPHERAL INTERFACE (SPI) PORTS
The timer units can be used in conjunction with UART0 to
measure the width of the pulses in the data stream to provide an
auto-baud detect function for a serial channel.
The ADSP-BF539/ADSP-BF539F processors incorporate three
SPI-compatible ports that enable the processor to communicate
with multiple SPI compatible devices.
The timers can generate interrupts to the processor core providing periodic events for synchronization, either to the system
clock or to a count of external signals.
The SPI interface uses three pins for transferring data: two data
pins (master output-slave input, MOSIx, and master input-slave
output, MISOx) and a clock pin (serial clock, SCKx). An SPI
chip select input pin (SPIxSS) lets other SPI devices select the
processor. For SPI0, seven SPI chip select output pins
(SPI0SEL7–1) let the processor select other SPI devices. SPI1
and SPI2 each have a single SPI chip select output pin
(SPI1SEL1 and SPI2SEL1) for SPI point-to-point communication. Each of the SPI select pins is a reconfigured GPIO pin.
Using these pins, the SPI ports provide a full-duplex, synchronous serial interface, which supports both master/slave modes
and multimaster environments.
In addition to the three general-purpose programmable timers,
a fourth timer is also provided. This extra timer is clocked by the
internal processor clock and is typically used as a system tick
clock for generation of operating system periodic interrupts.
SERIAL PORTS (SPORTs)
The ADSP-BF539/ADSP-BF539F processors incorporate four
dual-channel synchronous serial ports for serial and multiprocessor communications. The SPORTs support the following
features:
2
• I S capable operation.
• Bidirectional operation – Each SPORT has two sets of independent transmit and receive pins, enabling 16 channels of
I2S stereo audio.
• Buffered (8-deep) transmit and receive ports – Each port
has a data register for transferring data words to and from
other processor components and shift registers for shifting
data in and out of the data registers.
• Clocking – Each transmit and receive port can either use an
external serial clock or generate its own, in frequencies
ranging from (fSCLK/131,070) Hz to (fSCLK/2) Hz.
• Word length – Each SPORT supports serial data words
from 3 bits to 32 bits in length, transferred most significant
bit first or least significant bit first.
Rev. A |
• Multichannel capability – Each SPORT supports 128 channels out of a 1024-channel window and is compatible with
the H.100, H.110, MVIP-90, and HMVIP standards.
The SPI ports’ baud rate and clock phase/polarities are programmable, and they each have an integrated DMA controller,
configurable to support transmit or receive data streams. Each
SPI DMA controller can only service unidirectional accesses at
any given time.
The SPI port clock rate is calculated as:
f SCLK
SPI Clock Rate = -------------------------------------2 × SPIx_BAUD
where the 16-bit SPIx_BAUD register contains a value of 2 to
65,535.
During transfers, the SPI port simultaneously transmits and
receives by serially shifting data in and out on its two serial data
lines. The serial clock line synchronizes the shifting and sampling of data on the two serial data lines.
Page 10 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
2-WIRE INTERFACE
PROGRAMMABLE I/O PINS
The ADSP-BF539/ADSP-BF539F processors incorporate two
2-wire interface (TWI) modules that are compatible with the
Philips Inter-IC bus standard. The TWI modules offer the capabilities of simultaneous master and slave operation, support for
7-bit addressing, and multimedia data arbitration. The TWI also
includes master clock synchronization and support for clock
low extension.
The ADSP-BF539/ADSP-BF539F processor has numerous
peripherals that may not all be required for every application.
Many of the pins thus have a secondary function, as programmable I/O pins. There are two types of programmable I/O pins
on the ADSP-BF539/ADSP-BF539F processor, with slightly different functionality: programmable flags and general-purpose
I/O.
The TWI interface uses two pins for transferring clock (SCLx)
and data (SDAx) and supports the protocol at speeds up to
400 kbps.
Programmable Flags (PFx)
The TWI interface pins are compatible with 5 V logic levels.
UART PORTS
The ADSP-BF539/ADSP-BF539F processors have 16 bidirectional, general-purpose programmable flag (PF15–0) pins. Each
programmable flag can be individually controlled by manipulation of the flag control, status, and interrupt registers:
• Flag direction control register – Specifies the direction of
each individual PFx pin as input or output.
The ADSP-BF539/ADSP-BF539F processor incorporates three
full-duplex universal asynchronous receiver/transmitter
(UART) ports, which are fully compatible with PC standard
UARTs. The UART ports provide a simplified UART interface
to other peripherals or hosts, supporting full-duplex, DMA supported, asynchronous transfers of serial data. The UART ports
include support for 5 data bits to 8 data bits, 1-stop bit or 2-stop
bits, and none, even, or odd parity. The UART ports support
two modes of operation:
• Flag control and status registers – The
ADSP-BF539/ADSP-BF539F processors employ a “write
one to modify” mechanism that allows any combination of
individual flags to be modified in a single instruction, without affecting the level of any other flags. Four control
registers are provided. One register is written in order to set
flag values, one register is written in order to clear flag values, one register is written in order to toggle flag values,
and one register is written in order to specify a flag value.
Reading the flag status register allows software to interrogate the sense of the flags.
• PIO (programmed I/O) – The processor sends or receives
data by writing or reading I/O mapped UART registers.
The data is double buffered on both transmit and receive.
• DMA (direct memory access) – The DMA controller transfers both transmit and receive data. This reduces the
number and frequency of interrupts required to transfer
data to and from memory. Each UART has two dedicated
DMA channels, one for transmit and one for receive. These
DMA channels have lower default priority than most DMA
channels because of their relatively low service rates.
• Flag interrupt mask registers – The two flag interrupt mask
registers allow each individual PFx pin to function as an
interrupt to the processor. Similar to the two flag control
registers that are used to set and clear individual flag values,
one flag interrupt mask register sets bits to enable interrupt
function, and the other flag interrupt mask register clears
bits to disable interrupt function. PFx pins defined as
inputs can be configured to generate hardware interrupts,
while output PFx pins can be triggered by software
interrupts.
Each UART port’s baud rate, serial data format, error code generation and status, and interrupts are programmable:
• Supporting bit rates ranging from (fSCLK/1,048,576) to
(fSCLK/16) bits per second.
• Flag interrupt sensitivity registers – The two flag interrupt
sensitivity registers specify whether individual PFx pins are
level- or edge-sensitive and specify—if edge-sensitive—
whether just the rising edge or both the rising and falling
edges of the signal are significant. One register selects the
type of sensitivity, and one register selects which edges are
significant for edge-sensitivity.
• Supporting data formats from 7 bits to 12 bits per frame.
• Both transmit and receive operations can be configured to
generate maskable interrupts to the processor.
Each UART port’s clock rate is calculated as:
f SCLK
UART Clock Rate = ---------------------------------------------16 × UART_Divisor
General-Purpose I/O
where the 16-bit UART_Divisor comes from the UARTx_DLH
register (most significant 8 bits) and UARTx_DLL register (least
significant 8 bits).
In conjunction with the general-purpose timer functions, autobaud detection is supported on UART0.
The ADSP-BF539/ADSP-BF539F processors have 38 generalpurpose I/O pins that are multiplexed with other peripherals.
They are arranged into ports C, D, E, and F as shown in Table 4
on Page 12. The GPIO differ from the programmable flags in
that the GPIO pins cannot generate interrupts to the processor.
The capabilities of the UARTs are further extended with support for the Infrared Data Association (IrDA®) Serial Infrared
Physical Layer Link Specification (SIR) protocol.
Rev. A |
Page 11 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
Peripheral
Alternate Programmable
Flag / GPIO Port Function
PPI
PF15–3
data. Up to 3 frame synchronization signals are also provided.
In ITU-R 656 mode, the PPI provides half-duplex, bidirectional
transfer of 8- or 10-bit video data. Additionally, on-chip decode
of embedded start-of-line (SOL) and start-of-field (SOF) preamble packets are supported.
SPORT2
PE7–0
General-Purpose Mode Descriptions
SPORT3
PE15–8
SPI0
PF7–0
SPI1
PD4–0
The general-purpose modes of the PPI are intended to suit a
wide variety of data capture and transmission applications.
Three distinct submodes are supported:
SPI2
PD9–5
• Input Mode – Frame syncs and data are inputs into the PPI.
UART1
PD11–10
UART2
PD13–12
• Frame Capture Mode – Frame syncs are outputs from the
PPI, but data are inputs.
CAN
PC1–0
MXVR
PC9–4
Table 4. Programmable Flag / GPIO Ports
• Output Mode – Frame syncs and data are outputs from
the PPI.
The general-purpose I/O pins can be individually controlled by
manipulation of the control and status registers. These pins will
not cause interrupts to be generated to the processor but can be
polled to determine their status.
• GPIO direction control register – Specifies the direction of
each individual GPIOx pin as input or output.
• GPIO control and status registers – The
ADSP-BF539/ADSP-BF539F processors employ a “write
one to modify” mechanism that allows any combination of
individual GPIO to be modified in a single instruction,
without affecting the level of any other GPIO. Four control
registers and a data register are provided for each GPIO
port. One register is written in order to set GPIO values,
one register is written in order to clear GPIO values, one
register is written in order to toggle GPIO values, and one
register is written in order to specify a GPIO input or output. Reading the GPIO data allows software to determine
the state of the input GPIO pins. PC1 and PC4 are opendrain when configured as GPIO outputs.
Note that the GP pin is used to specify the status of the GPIO
pins PC9–PC4 at power up. If GP is tied high, then pins
PC9–PC4 are configured as GPIO after reset. The pins cannot
be reconfigured through software, and special care must be
taken with the MLF pin. If the GP pin is tied low, then the pins
are configured as MXVR pins after reset but can be reconfigured as GPIO pins through software.
PARALLEL PERIPHERAL INTERFACE
The ADSP-BF539/ADSP-BF539F processors provide a parallel
peripheral interface (PPI) that can connect directly to parallel
A/D and D/A converters, video encoders and decoders, and
other general-purpose peripherals. The PPI consists of a dedicated input clock pin, up to 3 frame synchronization pins, and
up to 16 data pins. The input clock supports parallel data rates
up to fSCLK/2 MHz, and the synchronization signals can be configured as either inputs or outputs.
The PPI supports a variety of general-purpose and ITU-R 656
modes of operation. In general-purpose mode, the PPI provides
half-duplex, bidirectional data transfer with up to 16 bits of
Rev. A |
Input Mode
This mode is intended for ADC applications, as well as video
communication with hardware signaling. In its simplest form,
PPI_FS1 is an external frame sync input that controls when to
read data. The PPI_DELAY MMR allows for a delay (in
PPI_CLK cycles) between reception of this frame sync and the
initiation of data reads. The number of input data samples is
user programmable and defined by the contents of the
PPI_COUNT register. The PPI supports 8-bit, and 10-bit
through 16-bit data and are programmable in the
PPI_CONTROL register.
Frame Capture Mode
This mode allows the video source(s) to act as a slave (e.g., for
frame capture). The ADSP-BF539/ADSP-BF539F processors
control when to read from the video source(s). PPI_FS1 is an
HSYNC output, and PPI_FS2 is a VSYNC output.
Output Mode
This mode is used for transmitting video or other data with up
to three output frame syncs. Typically, a single frame sync is
appropriate for data converter applications, whereas two or
three frame syncs could be used for sending video with hardware signaling.
ITU-R 656 Mode Descriptions
The ITU-R 656 modes of the PPI are intended to suit a wide
variety of video capture, processing, and transmission applications. Three distinct submodes are supported:
• Active Video Only Mode
• Vertical Blanking Only Mode
• Entire Field Mode
Active Video Only Mode
This mode is used when only the active video portion of a field
is of interest and not any of the blanking intervals. The PPI will
not read in any data between the end of active video (EAV) and
start of active video (SAV) preamble symbols, or any data
present during the vertical blanking intervals. In this mode, the
control byte sequences are not stored to memory; they are
Page 12 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
filtered by the PPI. After synchronizing to the start of Field 1,
the PPI will ignore incoming samples until it sees an SAV code.
The user specifies the number of active video lines per frame (in
PPI_COUNT register).
Vertical Blanking Interval Mode
In this mode, the PPI only transfers vertical blanking interval
(VBI) data.
Entire Field Mode
In this mode, the entire incoming bit stream is read in through
the PPI. This includes active video, control preamble sequences,
and ancillary data that can be embedded in horizontal and vertical blanking intervals. Data transfer starts immediately after
synchronization to Field 1.
CONTROLLER AREA NETWORK (CAN) INTERFACE
The ADSP-BF539/ADSP-BF539F processors provide a CAN
controller that is a communication controller implementing the
controller area network (CAN) V2.0B protocol. This protocol is
an asynchronous communications protocol used in both industrial and automotive control systems. CAN is well suited for
control applications due to its ability to communicate reliably
over a network since the protocol incorporates CRC checking,
message error tracking, and fault node confinement.
The CAN controller is based on a 32-entry mailbox RAM and
supports both the standard and extended identifier (ID) message formats specified in the CAN protocol specification,
Revision 2.0, Part B.
Each mailbox consists of eight 16-bit data words. The data is
divided into fields, which includes a message identifier, a time
stamp, a byte count, up to 8 bytes of data, and several control
bits. Each node monitors the messages being passed on the network. If the identifier in the transmitted message matches an
identifier in one of its mailboxes, then the module knows that
the message was meant for it, passes the data into its appropriate
mailbox, and signals the processor of message arrival with an
interrupt.
The CAN controller can wake up the ADSP-BF539/ADSPBF539F processors from sleep mode upon generation of a wakeup event, such that the processor can be maintained in a low
power mode during idle conditions. Additionally, a CAN wakeup event can wake up the on-chip internal voltage regulator
from the hibernate state.
The electrical characteristics of each network connection are
very stringent; therefore, the CAN interface is typically divided
into two parts: a controller and a transceiver. This allows a single controller to support different drivers and CAN networks.
The ADSP-BF539/ADSP-BF539F CAN module represents the
controller part of the interface. This module’s network I/O is a
single transmit output and a single receive input, which connect
to a line transceiver.
MEDIA TRANSCEIVER MAC LAYER (MXVR)
The ADSP-BF539/ADSP-BF539F processors provide a media
transceiver (MXVR) MAC layer, allowing the processor to be
connected directly to a MOST network through just an FOT or
electrical PHY.
The MXVR is fully compatible with the industry standard
standalone MOST controller devices, supporting 22.579 Mbps
or 24.576 Mbps data transfer. It offers faster lock times, greater
jitter immunity, a sophisticated DMA scheme for data transfers,
and the high speed internal interface to the core and L1 memory
allows the full bandwidth of the network to be utilized. The
MXVR can operate as either the network master or as a
network slave.
Synchronous data is transferred to or from the synchronous
data channels through eight programmable DMA engines. The
synchronous data DMA engines can operate in various modes,
including modes that trigger DMA operation when data patterns are detected in the receive data stream. Furthermore, two
DMA engines support asynchronous traffic and a further support control message traffic.
Interrupts are generated when a user-defined amount of synchronous data has been sent or received by the processor or
when asynchronous packets or control messages have been sent
or received.
The MXVR peripheral can wake up the ADSP-BF539/ADSPBF539F processors from sleep mode when a wake-up preamble
is received over the network or based on any other MXVR interrupt event. Additionally, detection of network activity by the
MXVR can be used to wake up the ADSP-BF539/ADSP-BF539F
processors from sleep mode and wake up the on-chip internal
voltage regulator from the powered-down hibernate state. These
features allow the ADSP-BF539/ADSP-BF539F to operate in a
low-power state when there is no network activity or when data
is not currently being received or transmitted by the MXVR.
The MXVR clock is provided through a dedicated external crystal or crystal oscillator. For 44.1 kHz frame syncs, use a
45.1584 MHz crystal or oscillator; for 48 kHz frame syncs, use a
49.152 MHz crystal or oscillator. If using a crystal to provide the
MXVR clock, use a parallel-resonant, fundamental mode,
microprocessor-grade crystal.
DYNAMIC POWER MANAGEMENT
The ADSP-BF539/ADSP-BF539F processors provide four operating modes, each with a different performance/power profile.
In addition, dynamic power management provides the control
functions to dynamically alter the processor core supply voltage,
further reducing power dissipation. Control of clocking to each
of the ADSP-BF539/ADSP-BF539F processor peripherals also
reduces power consumption. See Table 5 for a summary of the
power settings for each mode.
The CAN clock is derived from the processor system clock
(SCLK) through a programmable divider and therefore does not
require an additional crystal.
Rev. A |
Page 13 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
Full-On Operating Mode—Maximum Performance
In the full-on mode, the PLL is enabled and is not bypassed,
providing capability for maximum operational frequency. This
is the power-up default execution state in which maximum performance can be achieved. The processor core and all enabled
peripherals run at full speed.
Active Operating Mode—Moderate Power Savings
In the active mode, the PLL is enabled but bypassed. Because the
PLL is bypassed, the processor’s core clock (CCLK) and system
clock (SCLK) run at the input clock (CLKIN) frequency. In this
mode, the CLKIN to CCLK multiplier ratio can be changed,
although the changes are not realized until the full-on mode is
entered. DMA access is available to appropriately configured L1
memories.
In the active mode, it is possible to disable the PLL through the
PLL Control register (PLL_CTL). If disabled, the PLL must be
re-enabled before transitioning to the full-on or sleep modes.
PLL
Bypassed
Core
Clock
(CCLK)
Enabled
No
Enabled Enabled On
Core
Power
PLL
Full-On
System
Clock
(SCLK)
Mode/State
Table 5. Power Settings
Active
Enabled/ disabled Yes
Enabled Enabled On
Sleep
Enabled
Disabled Enabled On
Deep Sleep Disabled
Disabled Disabled On
Hibernate
Disabled Disabled Off
Disabled
interrupt causes the processor to transition to the active mode.
Assertion of RESET while in deep sleep mode causes the processor to transition to the full-on mode.
Hibernate State—Maximum Static Power Savings
The hibernate state maximizes static power savings by disabling
the voltage and clocks to the processor core (CCLK) and to all
the synchronous peripherals (SCLK). The internal voltage regulator for the processor can be shut off by writing b#00 to the
FREQ bits of the VR_CTL register. This disables both CCLK
and SCLK. Furthermore, it sets the internal power supply voltage (VDDINT) to 0 V to provide the lowest static power
dissipation. Any critical information stored internally (memory
contents, register contents, etc.) must be written to a nonvolatile
storage device prior to removing power if the processor state is
to be preserved. Since VDDEXT is still supplied in this mode, all of
the external pins three-state, unless otherwise specified. This
allows other devices that can be connected to the processor to
have power still applied without drawing unwanted current.
The internal supply regulator can be woken up either by a realtime clock wake-up, by CAN bus traffic, by asserting the RESET
pin, or by MOST bus traffic causing the MRXON pin to assert.
If either CAN or MXVR is not used, a general-purpose wake-up
is possible.
Power Savings
As shown in Table 6, the ADSP-BF539/ADSP-BF539F processors support five different power domains. The use of multiple
power domains maximizes flexibility, while maintaining compliance with industry standards and conventions:
• The 3.3 V VDDRTC power domain supplies the RTC I/O and
logic so that the RTC can remain functional when the rest
of the chip is powered off.
Sleep Operating Mode—High Dynamic Power Savings
• The 3.3 V MXEVDD power domain supplies the MXVR
crystal and is separate to provide noise isolation.
The sleep mode reduces dynamic power dissipation by disabling
the clock to the processor core (CCLK). The PLL and system
clock (SCLK), however, continue to operate in this mode. Typically an external event or RTC activity will wake up the
processor. When in the sleep mode, assertion of wake-up will
cause the processor to sense the value of the BYPASS bit in the
PLL Control register (PLL_CTL). If Bypass is disabled, the processor will transition to the full-on mode. If Bypass is enabled,
the processor will transition to the active mode. When in the
sleep mode, system DMA access to L1 memory is not supported.
There are no sequencing requirements for the various power
domains.
Deep Sleep Operating Mode—Maximum Dynamic Power
Savings
Table 6. Power Domains
• The 1.25 V MPIVDD power domain supplies the MXVR
PLL and is separate to provide noise isolation.
• The 1.25 V VDDINT power domain supplies all internal logic
except for the RTC logic and the MXVR PLL.
• The 3.3 V VDDEXT power domain supplies all I/O except for
the RTC and MXVR crystals.
The deep sleep mode maximizes dynamic power savings by disabling the clocks to the processor core (CCLK) and to all
synchronous peripherals (SCLK). Asynchronous peripherals
such as the RTC may still be running but will not be able to
access internal resources or external memory. This powereddown mode can only be exited by assertion of the reset interrupt
(RESET) or by an asynchronous interrupt generated by the
RTC. When in deep sleep mode, an RTC asynchronous
Rev. A |
Page 14 of 60 |
Power Domain
VDD Range
RTC Crystal I/O and Logic
VDDRTC
MXVR Crystal I/O
MXEVDD
MXVR PLL Analog and Logic
MPIVDD
All Internal Logic Except RTC and MXVR PLL
VDDINT
All I/O Except RTC and MXVR Crystals
VDDEXT
February 2008
ADSP-BF539/ADSP-BF539F
The VDDRTC should either be connected to an isolated supply
such as a battery (if the RTC is to operate while the rest of the
chip is powered down) or should be connected to the VDDEXT
plane on the board. The VDDRTC should remain powered when
the processor is in hibernate state and should also remain powered even if the RTC functionality is not being used in an
application. The MXEVDD should be connected to the VDDEXT
plane on the board at a single location with local bypass capacitors. The MXEVDD should remain powered when the
processor is in hibernate state and should also remain powered
even when the MXVR functionality is not being used in an
application. The MPIVDD should be connected to the VDDINT
plane on the board at a single location through a ferrite bead
with local bypass capacitors.
logic voltage levels and is programmable with the voltage regulator control register (VR_CTL) in increments of 50 mV. To
reduce standby power consumption, the internal voltage regulator can be programmed to remove power to the processor core
while I/O power (VDDRTC, MXEVDD, VDDEXT) is still supplied.
While in the hibernate state, I/O power is still being applied,
eliminating the need for external buffers. The voltage regulator
can be activated from this power-down state through an RTC
wake-up, a CAN wake-up, an MXVR wake-up, a general-purpose wake-up, or by asserting RESET, all of which will then
initiate a boot sequence. The regulator can also be disabled and
bypassed at the user’s discretion.
The power dissipated by a processor is largely a function of the
clock frequency of the processor and the square of the operating
voltage. For example, reducing the clock frequency by 25%
results in a 25% reduction in dynamic power dissipation, while
reducing the voltage by 25% reduces dynamic power dissipation
by more than 40%. Further, these power savings are additive in
that, if the clock frequency and supply voltage are both reduced,
the power savings can be dramatic.
The dynamic power management feature of the
ADSP-BF539/ADSP-BF539F processors allow both the processor input voltage (VDDINT) and clock frequency (fCCLK) to be
dynamically controlled.
2.25V TO 3.6V
INPUT VOLTAGE
RANGE
VDDEXT
(LOW-INDUCTANCE)
+
VDDEXT
100µF
10µH
100nF
+
+
VDDINT
100µF
FDS9431A
100µF
10µF
LOW ESR
ZHCS1000
VROUT
The savings in power dissipation can be modeled using the
power savings factor and % power savings calculations.
SHORT AND LOWINDUCTANCE WIRE
The power savings factor is calculated as
NOTE: DESIGNER SHOULD MINIMIZE
TRACE LENGTH TO FDS9431A.
Power Savings Factor
f CCLKRED ⎛ V DDINTRED ⎞ 2 ⎛ T RED ⎞
- × -------------------------- × ------------= -------------------f CCLKNOM ⎝ V DDINTNOM⎠ ⎝ T NOM ⎠
VROUT
GND
Figure 6. Voltage Regulator Circuit
where
CLOCK SIGNALS
fCCLKNOM is the nominal core clock frequency.
The ADSP-BF539/ADSP-BF539F processors can be clocked by
an external crystal, a sine wave input, or a buffered, shaped
clock derived from an external clock oscillator.
fCCLKRED is the reduced core clock frequency.
VDDINTNOM is the nominal internal supply voltage.
VDDINTRED is the reduced internal supply voltage.
If an external clock is used, it should be a TTL-compatible signal
and must not be halted, changed, or operated below the specified frequency during normal operation. This signal is
connected to the processor’s CLKIN pin. When an external
clock is used, the XTAL pin must be left unconnected.
TNOM is the duration running at fCCLKNOM.
TRED is the duration running at fCCLKRED.
The Power Savings Factor is calculated as
% Power Savings = ( 1 – Power Savings Factor ) × 100%
VOLTAGE REGULATION
The Blackfin processor provides an on-chip voltage regulator
that can generate processor core voltage levels 1.0 V
(–5%/+10%) to 1.20 V (–5%/+10%) and 1.25 V (–4%/+10%)
from an external 2.7 V to 3.6 V supply. For operation below
2.7 V, an external voltage regulator must be used. Figure 6
shows the typical external components required to complete the
power management system.† The regulator controls the internal
†
SET OF DECOUPLING
CAPACITORS
See Switching Regulator Design Considerations for ADSP-BF533 Blackfin
Processors (EE-228).
Rev. A |
Alternatively, because the ADSP-BF539/ADSP-BF539F processors include an on-chip oscillator circuit, an external crystal can
be used. For fundamental frequency operation, use the circuit
shown in Figure 7 on Page 16. A parallel-resonant, fundamental
frequency, microprocessor-grade crystal is connected across the
CLKIN and XTAL pins. The on-chip resistance between CLKIN
and the XTAL pin is in the 500 kΩ range. Further parallel resistors are typically not recommended. The two capacitors and the
series resistor, shown in Figure 7 on Page 16, fine tune the phase
and amplitude of the sine frequency. The capacitor and resistor
values, shown in Figure 7 on Page 16, are typical values only.
The capacitor values are dependent upon the crystal manufacturer’s load capacitance recommendations and the physical PCB
Page 15 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
layout. The resistor value depends on the drive level specified by
the crystal manufacturer. System designs should verify the customized values based on careful investigation on multiple
devices over the allowed temperature range.
into the SSEL fields define a divide ratio between the PLL output
(VCO) and the system clock. SCLK divider values are 1 through
15. Table 7 illustrates typical system clock ratios.
A third-overtone crystal can be used at frequencies above
25 MHz. The circuit is then modified to ensure crystal operation
only at the third overtone, by adding a tuned inductor circuit as
shown in Figure 7.
Table 7. Example System Clock Ratios
Signal Name Divider Ratio Example Frequency Ratios (MHz)
SSEL3–0
VCO/SCLK
VCO
SCLK
Blackfin
CLKOUT
EN
100
300
50
1010
10:1
500
50
The core clock (CCLK) frequency can also be dynamically
changed by means of the CSEL1–0 bits of the PLL_DIV register.
Supported CCLK divider ratios are 1, 2, 4, and 8, as shown in
Table 8. This programmable core clock capability is useful for
fast core frequency modifications.
FOR OVERTONE
OPERATION ONLY
18pF*
NOTE: VALUES MARKED WITH * MUST BE CUSTOMIZED
DEPENDING ON THE CRYSTAL AND LAYOUT. PLEASE
ANALYZE CAREFULLY.
Table 8. Core Clock Ratios
Figure 7. External Crystal Connections
As shown in Figure 8, the core clock (CCLK) and system
peripheral clock (SCLK) are derived from the input clock
(CLKIN) signal. An on-chip PLL is capable of multiplying the
CLKIN signal by a user programmable 0.5× to 64× multiplication factor (bounded by specified minimum and maximum
VCO frequencies). The default multiplier is 10×, but it can be
modified by a software instruction sequence. On-the-fly frequency changes can be effected by simply writing to the
PLL_DIV register.
“FI NE” ADJUSTMENT
REQUI RES PLL SEQUENCING
100
6:1
Note that when the SSEL value is changed, it will affect all the
peripherals that derive their clock signals from the SCLK signal.
XTAL
18pF*
1:1
0110
The maximum frequency of the system clock is fSCLK. Note that
the divisor ratio must be chosen to limit the system clock frequency to its maximum of fSCLK. The SSEL value can be changed
dynamically without any PLL lock latencies by writing the
appropriate values to the PLL divisor register (PLL_DIV).
TO PLL CIRCUITRY
CLKIN
0001
“COARSE” ADJUSTMENT
ON-THE-FLY
Signal Name
CSEL1–0
Divider Ratio
VCO/CCLK
Example Frequency Ratios
VCO
CCLK
00
1:1
300
300
01
2:1
300
150
10
4:1
500
125
11
8:1
200
25
BOOTING MODES
The ADSP-BF539/ADSP-BF539F processors have three mechanisms (listed in Table 9) for automatically loading internal L1
instruction memory after a reset. A fourth mode is provided to
execute from external memory, bypassing the boot sequence.
Table 9. Booting Modes
CLKIN
PLL
0.5× TO 64×
÷ 1, 2, 4, 8
CCLK
÷ 1:15
SCLK
BMODE1–0 Description
VCO
SCLK ≤ CCLK
SCLK ≤ 133MHz
Figure 8. Frequency Modification Methods
All on-chip peripherals are clocked by the system clock (SCLK).
The system clock frequency is programmable by means of the
SSEL3–0 bits of the PLL_DIV register. The values programmed
Rev. A |
Page 16 of 60 |
00
Execute from 16-bit external memory
(bypass boot ROM)
01
Boot from 8-bit or 16-bit flash or boot from on-chip
flash (ADSP-BF539F only)
10
Boot from SPI serial master connected to SPI0
11
Boot from SPI serial slave EEPROM /flash
(8-,16-, or 24-bit address range, or Atmel
AT45DB041, AT45DB081, or AT45DB161serial flash)
connected to SPI0
February 2008
ADSP-BF539/ADSP-BF539F
The BMODE pins of the reset configuration register, sampled
during power-on resets and software initiated resets, implement
the following modes:
• Execute from 16-bit external memory – Execution starts
from address 0x2000 0000 with 16-bit packing. The boot
ROM is bypassed in this mode. All configuration settings
are set for the slowest device possible (3-cycle hold time;
15-cycle R/W access times; 4-cycle setup).
• Boot from 8-bit or 16-bit external flash memory – The 8-bit
flash boot routine located in boot ROM memory space is
set up using asynchronous memory bank 0. For
ADSP-BF539F processors, if FCE is connected to AMS0,
then the on-chip flash is booted. All configuration settings
are set for the slowest device possible (3-cycle hold time;
15-cycle R/W access times; 4-cycle setup).
fully featured multifunction instructions that allow the programmer to use many of the processor core resources in a single
instruction. Coupled with many features more often seen on
microcontrollers, this instruction set is very efficient when compiling C and C++ source code. In addition, the architecture
supports both user (algorithm/application code) and supervisor
(O/S kernel, device drivers, debuggers, ISRs) modes of operation, allowing multiple levels of access to core processor
resources.
The assembly language, which takes advantage of the processor’s unique architecture, offers the following advantages:
• Seamlessly integrated DSP/CPU features are optimized for
both 8-bit and 16-bit operations.
• A multi-issue load/store modified Harvard architecture,
which supports two 16-bit MAC or four 8-bit ALU plus
two load/store plus two pointer updates per cycle.
• Boot from SPI serial EEPROM/flash (8-, 16-, or 24-bit
addressable, or Atmel AT45DB041, AT45DB081, or
AT45DB161) connected to SPI0 – The SPI0 port uses the
PF2 output pin to select a single SPI EEPROM/flash device,
submits a read command and successive address bytes
(0x00) until a valid 8-, 16-, or 24-bit, or Atmel addressable
device is detected, and begins clocking data into the beginning of the L1 instruction memory.
• Boot from SPI host device connected to SPI0 – The Blackfin processor operates in SPI slave mode and is configured
to receive the bytes of the .LDR file from an SPI host (master) agent. To hold off the host device from transmitting
while the boot ROM is busy, the Blackfin processor asserts
a GPIO pin, called host wait (HWAIT), to signal the host
device not to send any more bytes until the flag is deasserted. The flag is chosen by the user and this information
is transferred to the Blackfin processor via bits 10:5 of the
FLAG header in the .LDR image.
For each of the boot modes, a 10-byte header is first read from
an external memory device. The header specifies the number of
bytes to be transferred and the memory destination address.
Multiple memory blocks can be loaded by any boot sequence.
Once all blocks are loaded, program execution commences from
the start of L1 instruction SRAM.
In addition, Bit 4 of the reset configuration register can be set by
application code to bypass the normal boot sequence during a
software reset. For this case, the processor jumps directly to the
beginning of L1 instruction memory.
To augment the boot modes, a secondary software loader is provided that adds additional booting mechanisms. This secondary
loader provides the ability to boot from 16-bit flash memory,
fast flash, variable baud rate, and other sources. In all boot
modes except bypass, program execution starts from on-chip L1
memory address 0xFFA0 0000.
INSTRUCTION SET DESCRIPTION
The Blackfin processor family assembly language instruction set
employs an algebraic syntax designed for ease of coding and
readability. The instructions have been specifically tuned to provide a flexible, densely encoded instruction set that compiles to
a very small final memory size. The instruction set also provides
Rev. A |
• All registers, I/O, and memory are mapped into a unified
4G byte memory space, providing a simplified programming model.
• Microcontroller features, such as arbitrary bit and bit-field
manipulation, insertion, and extraction; integer operations
on 8-, 16-, and 32-bit data types; and separate user and
supervisor stack pointers.
• Code density enhancements, which include intermixing of
16-bit and 32-bit instructions (no mode switching, no code
segregation). Frequently used instructions are encoded in
16 bits.
DEVELOPMENT TOOLS
The ADSP-BF539/ADSP-BF539F processors are supported by a
complete set of CROSSCORE† software and hardware development tools, including Analog Devices emulators and
VisualDSP++ development environment. The same emulator
hardware that supports other Blackfin processors also fully
emulates the ADSP-BF539/ADSP-BF539F processor.
The VisualDSP++ project management environment lets programmers develop and debug an application. This environment
includes an easy to use assembler (which is based on an algebraic syntax), an archiver (librarian/library builder), a linker, a
loader, a cycle-accurate instruction-level simulator, a C/C++
compiler, and a C/C++ runtime library that includes DSP and
mathematical functions. A key point for these tools is C/C++
code efficiency. The compiler has been developed for efficient
translation of C/C++ code to processor assembly. The processor
has architectural features that improve the efficiency of compiled C/C++ code.
The VisualDSP++ debugger has a number of important features. Data visualization is enhanced by a plotting package that
offers a significant level of flexibility. This graphical representation of user data enables the programmer to quickly determine
the performance of an algorithm. As algorithms grow in complexity, this capability can have increasing significance on the
†
Page 17 of 60 |
CROSSCORE is a registered trademark of Analog Devices, Inc.
February 2008
ADSP-BF539/ADSP-BF539F
designer’s development schedule, increasing productivity. Statistical profiling enables the programmer to nonintrusively poll
the processor as it is running the program. This feature, unique
to VisualDSP++, enables the software developer to passively
gather important code execution metrics without interrupting
the real-time characteristics of the program. Essentially, the
developer can identify bottlenecks in software quickly and efficiently. By using the profiler, the programmer can focus on
those areas in the program that impact performance and take
corrective action.
Debugging both C/C++ and assembly programs with the
VisualDSP++ debugger, programmers can:
• View mixed C/C++ and assembly code (interleaved source
and object information).
• Insert breakpoints.
• Set conditional breakpoints on registers, memory,
and stacks.
• Trace instruction execution.
• Perform linear or statistical profiling of program execution.
• Fill, dump, and graphically plot the contents of memory.
• Perform source level debugging.
Use the Expert Linker to visually manipulate the placement of
code and data on the embedded system. View memory utilization in a color-coded graphical form, easily move code and data
to different areas of the processor or external memory with the
drag of the mouse and examine run-time stack and heap usage.
The Expert Linker is fully compatible with existing Linker Definition File (LDF), allowing the developer to move between the
graphical and textual environments.
Analog Devices emulators use the IEEE 1149.1 JTAG Test
Access Port of the ADSP-BF539/ADSP-BF539F processors to
monitor and control the target board processor during emulation. The emulator provides full-speed emulation, allowing
inspection and modification of memory, registers, and processor stacks. Nonintrusive in-circuit emulation is assured by the
use of the processor’s JTAG interface—the emulator does not
affect target system loading or timing.
In addition to the software and hardware development tools
available from Analog Devices third parties provide a wide
range of tools supporting the Blackfin processor family. Hardware tools include Blackfin processor PC plug-in cards. Third
party software tools include DSP libraries, real-time operating
systems, and block diagram design tools.
DESIGNING AN EMULATOR COMPATIBLE
PROCESSOR BOARD
• Create custom debugger windows.
The VisualDSP++ IDDE lets programmers define and manage
software development. Its dialog boxes and property pages let
programmers configure and manage all of the Blackfin development tools, including the color syntax highlighting in the
VisualDSP++ editor. This capability permits programmers to:
• Control how the development tools process inputs and
generate outputs.
• Maintain a one-to-one correspondence with the tool’s
command line switches.
The VisualDSP++ Kernel (VDK) incorporates scheduling and
resource management tailored specifically to address the memory and timing constraints of DSP programming. These
capabilities enable engineers to develop code more effectively,
eliminating the need to start from the very beginning, when
developing new application code. The VDK features include
threads, critical and unscheduled regions, semaphores, events,
and device flags. The VDK also supports priority-based, preemptive, cooperative, and time-sliced scheduling approaches. In
addition, the VDK was designed to be scalable. If the application
does not use a specific feature, the support code for that feature
is excluded from the target system.
Because the VDK is a library, a developer can decide whether to
use it or not. The VDK is integrated into the VisualDSP++
development environment, but can also be used via standard
command line tools. When the VDK is used, the development
environment assists the developer with many error prone tasks
and assists in managing system resources, automating the generation of various VDK-based objects, and visualizing the
system state, when debugging an application that uses the VDK.
Rev. A |
The Analog Devices family of emulators are tools that every system developer needs to test and debug hardware and software
systems. Analog Devices has supplied an IEEE 1149.1 JTAG
Test Access Port (TAP) on each JTAG processor. The emulator
uses the TAP to access the internal features of the processor,
allowing the developer to load code, set breakpoints, observe
variables, observe memory, and examine registers. The processor must be halted to send data and commands, but once an
operation has been completed by the emulator, the processor
system is set running at full speed with no impact on
system timing.
To use these emulators, the target board must include a header
that connects the processor’s JTAG port to the emulator.
For details on target board design issues including mechanical
layout, single processor connections, multiprocessor scan
chains, signal buffering, signal termination, and emulator pod
logic, see Analog Devices JTAG Emulation Technical Reference
(EE-68) on the Analog Devices web site (www.analog.com)—
use site search on “EE-68.” This document is updated regularly
to keep pace with improvements to emulator support.
EXAMPLE CONNECTIONS AND LAYOUT
CONSIDERATIONS
Figure 9 shows an example circuit connection of the ADSPBF539/ADSP-BF539F to a MOST network. This diagram is
intended as an example, and exact connections and recommended circuit values should be obtained from Analog Devices.
Page 18 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
5V
5V
VDDINT (1.25V)
FB
MTXON
MPIVDD
Tx_Vdd
POWER GATING CIRCUIT
27 6
0.1MF
0.01MF
MOST FOT
Rx_Vdd
ADSP-BF539F
MTX
TX_Data
MRX
RX_Data
MOST
NETWORK
MXEGND
MRXON
Status
49.152MHz OSCILLATOR
MXI
CLKO
MXO
RFS0
336
MLF
L/RCLK
MFS
AUDIO DAC
336
MCLK
MMCLK
R1
220 6
33 6
C2
0.01MF
MBCLK
BCLK
AUDIO
CHANNELS
TSCLK0
C1
0.1MF
RSCLK0
MXEGND
SDATA
DT0PRI
Figure 9. Example Connections of ADSP-BF539/ADSP-BF539F to MOST Network
MXVR BOARD LAYOUT GUIDELINES
MXI/MXO with external crystal
• The crystal must be a 49.152 MHz or 45.1584 MHz fundamental mode crystal.
MLF pin
• Capacitors:
• The crystal and load capacitors should be placed physically
close to the MXI and MXO pins on the board.
C1: 0.1 μF (PPS type, 2% tolerance recommended)
C2: 0.01 μF (PPS type, 2% tolerance recommended)
• The load capacitors should be grounded to MXEGND.
• Resistor:
• The crystal and load capacitors should be wired up using
wide traces.
R1: 220 Ω (1% tolerance)
• The RC network connected to the MLF pin should be
located physically close to the MLF pin on the board.
• Board trace capacitance on each lead should not be more
than 3 pF.
• The RC network should be wired up and connected to the
MLF pin using wide traces.
• Trace capacitance plus load capacitance should equal the
load capacitance specification for the crystal.
• The capacitors in the RC network should be grounded to
MXEGND.
• Avoid routing other switching signals near the crystal and
components to avoid crosstalk. When not possible, shield
traces and components with ground.
• The RC network should be shielded using MXEGND
traces.
MXEGND–MXVR crystal oscillator and MXVR PLL ground
• Avoid routing other switching signals near the RC network
to avoid crosstalk.
• Should be routed with wide traces or as ground plane.
• Should be tied together to other board grounds at only one
point on the board.
MXI driven with external clock oscillator IC (recommended)
• MXI should be driven with the clock output of a
49.152 MHz or 45.1584 MHz clock oscillator IC.
• Avoid routing other switching signals near to MXEGND to
avoid crosstalk.
• MXO should be left unconnected.
MXEVDD–MXVR crystal oscillator 3.3 V power
• Avoid routing other switching signals near the oscillator
and clock output trace to avoid crosstalk. When not possible, shield traces with ground.
• Should be routed with wide traces or as power plane.
• Locally bypass MXEVDD with 0.1 μF and 0.01 μF decoupling capacitors to MXEGND.
• Avoid routing other switching signals near to MXEVDD to
avoid crosstalk.
Rev. A |
Page 19 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
MPIVDD–MXVR PLL 1.25 V power
• Should be routed with wide traces or as power plane.
• A ferrite bead should be placed between the 1.25 V VDDINT
power plane and the MPIVDD pin for noise isolation.
• Locally bypass MPIVDD with 0.1 μF and 0.01 μF decoupling capacitors to MXEGND.
• Avoid routing other switching signals near to MPIVDD to
avoid crosstalk.
Fiber optic transceiver (FOT) connections
• The traces between the ADSP-BF539/ADSP-BF539F processor and the FOT should be kept as short as possible.
• The receive data trace connecting the FOT receive data
output pin to the ADSP-BF539/ADSP-BF539F MRX input
pin should not have a series termination resistor. The edge
rate of the FOT receive data signal driven by the FOT is
typically very slow, and further degradation of the edge rate
is not desirable.
• The transmit data trace connecting the
ADSP-BF539/ADSP-BF539F MTX output pin to the FOT
Transmit Data input pin should have a 27 Ω series termination resistor placed close to the ADSP-BF539/ADSPBF539F MTX pin.
• The receive data trace and the transmit data trace between
the ADSP-BF539/ADSP-BF539F processor and the FOT
should not be routed close to each other in parallel over
long distances to avoid crosstalk.
VOLTAGE REGULATOR LAYOUT GUIDELINES
Regulator external component placement, board routing, and
bypass capacitors all have a significant effect on noise injected
into the other analog circuits on-chip. The VROUT1-0 traces
and voltage regulator external components should be considered as noise sources when doing board layout and should not
be routed or placed near sensitive circuits or components on the
board. All internal and I/O power supplies should be well
bypassed with bypass capacitors placed as close to the ADSPBF539/ADSP-BF539F as possible.
For further details on the on-chip voltage regulator and related
board design guidelines, see the Switching Regulator Design
Considerations for ADSP-BF533 Blackfin Processors (EE-228)
applications note on the Analog Devices website
(www.analog.com)—use site search on “EE-228”.
Rev. A |
Page 20 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
PIN DESCRIPTIONS
ADSP-BF539/ADSP-BF539F processor pin definitions are listed
in Table 10.
exception of the pins that need pull-ups or pull-downs, as noted
in the table.
All pins are three-stated during and immediately after reset,
except the memory interface, asynchronous memory control,
and synchronous memory control pins, which are driven high.
If BR is active, then the memory pins are also three-stated. All
unused I/O pins have their input buffers disabled with the
In order to maintain maximum functionality and reduce package size and pin count, some pins have dual, multiplexed
functionality. In cases where pin functionality is reconfigurable,
the default state is shown in plain text, while alternate functionality is shown in italics.
Table 10. Pin Descriptions
Pin Name
Driver
Type1
Type Description
Memory Interface
ADDR19–1
O
Address Bus for Async/Sync Access
A
DATA15–0
I/O
Data Bus for Async/Sync Access
A
ABE1–0/SDQM1–0
O
Byte Enables/Data Masks for Async/Sync Access
A
BR
I
Bus Request. (This pin should be pulled high when not used.)
BG
O
Bus Grant
A
BGH
O
Bus Grant Hang
A
AMS3–0
O
Bank Select
A
ARDY
I
Hardware Ready Control (This pin should always be pulled low when not used.)
AOE
O
Output Enable
A
ARE
O
Read Enable
A
AWE
O
Write Enable
A
FCE
I
Flash Enable (This pin should be left unconnected or pulled low for the
ADSP-BF539.)
FRESET
I
Flash Reset (This pin should be left unconnected or pulled low for the
ADSP-BF539.)
SRAS
O
Row Address Strobe
A
SCAS
O
Column Address Strobe
A
SWE
O
Write Enable
A
SCKE
O
Clock Enable
A
CLKOUT
O
Clock Output
B
SA10
O
A10 Pin
A
SMS
O
Bank Select
A
Asynchronous Memory Control
Flash Control
Synchronous Memory Control
Timers
TMR0
I/O
Timer 0
C
TMR1/PPI_FS1
I/O
Timer 1/PPI Frame Sync1
C
TMR2/PPI_FS2
I/O
Timer 2/PPI Frame Sync2
C
Rev. A |
Page 21 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
Table 10. Pin Descriptions (Continued)
Pin Name
Driver
Type1
Type Description
Parallel Peripheral Interface Port/GPIO
PF0/SPI0SS
I/O
Programmable Flag 0/SPI0 Slave Select Input
C
PF1/SPI0SEL1/TACLK
I/O
Programmable Flag 1/SPI0 Slave Select Enable 1/Timer Alternate Clock
C
PF2/SPI0SEL2
I/O
Programmable Flag 2/SPI0 Slave Select Enable 2
C
PF3/SPI0SEL3/PPI_FS3
I/O
Programmable Flag 3/SPI0 Slave Select Enable 3/PPI Frame Sync 3
C
PF4/SPI0SEL4/PPI15
I/O
Programmable Flag 4/SPI0 Slave Select Enable 4/PPI 15
C
PF5/SPI0SEL5/PPI14
I/O
Programmable Flag 5/SPI0 Slave Select Enable 5/PPI 14
C
PF6/SPI0SEL6/PPI13
I/O
Programmable Flag 6/SPI0 Slave Select Enable 6/PPI 13
C
PF7/SPI0SEL7/PPI12
I/O
Programmable Flag 7/SPI0 Slave Select Enable 7/PPI 12
C
PF8/PPI11
I/O
Programmable Flag 8/PPI 11
C
PF9/PPI10
I/O
Programmable Flag 9/PPI 10
C
PF10/PPI9
I/O
Programmable Flag 10/PPI 9
C
PF11/PPI8
I/O
Programmable Flag 11/PPI 8
C
PF12/PPI7
I/O
Programmable Flag 12/PPI 7
C
PF13/PPI6
I/O
Programmable Flag 13/PPI 6
C
PF14/PPI5
I/O
Programmable Flag 14/PPI 5
C
PF15/PPI4
I/O
Programmable Flag 15/PPI 4
C
C
PPI3–0
I/O
PPI3–0
PPI_CLK/TMRCLK
I
PPI Clock/External Timer Reference
Controller Area Network
CANTX/PC0
I/O 5 V CAN Transmit/GPIO
C
CANRX/PC1
I/OD
5V
CAN Receive/GPIO
C2
MTX/PC5
I/O
MXVR Transmit Data/GPIO
C
MTXON/PC9
I/O
MXVR Transmit FOT On/GPIO
C
MRX/PC4
I /OD MXVR Receive Data/GPIO (This pin should be pulled low when not used.)
5V
C2
MRXON
I5V
MXVR FOT Receive On (This pin should be pulled high when not used.)
C
MXI
I
MXVR Crystal Input (This pin should be pulled low when not used.)
MXO
O
MXVR Crystal Output (This pin should be left unconnected when not used.)
Media Transceiver (MXVR)/
General-Purpose I/O
MLF
A I/O
MXVR Loop Filter (This pin should be pulled low when not used.)
MMCLK/PC6
I/O
MXVR Master Clock/GPIO
C
MBCLK/PC7
I/O
MXVR Bit Clock/GPIO
C
MFS/PC8
I/O
MXVR Frame Sync/GPIO
C
GP
I
GPIO PC4–9 Enable (This pin should be pulled low when MXVR is used.)
Rev. A |
Page 22 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
Table 10. Pin Descriptions (Continued)
Pin Name
Driver
Type1
Type Description
2-Wire Interface Ports
These pins are open-drain and require a pull-up resistor. See version 2.1 of
the I2C specification for proper resistor values.
SDA0
I/O 5 V TWI0 Serial Data
E
SCL0
I/O 5 V TWI0 Serial Clock
E
SDA1
I/O 5 V TWI1 Serial Data
E
SCL1
I/O 5 V TWI1 Serial Clock
E
Serial Port0
RSCLK0
I/O
SPORT0 Receive Serial Clock
D
RFS0
I/O
SPORT0 Receive Frame Sync
C
DR0PRI
I
SPORT0 Receive Data Primary
DR0SEC
I
SPORT0 Receive Data Secondary
TSCLK0
I/O
SPORT0 Transmit Serial Clock
D
TFS0
I/O
SPORT0 Transmit Frame Sync
C
DT0PRI
O
SPORT0 Transmit Data Primary
C
DT0SEC
O
SPORT0 Transmit Data Secondary
C
RSCLK1
I/O
SPORT1 Receive Serial Clock
D
RFS1
I/O
SPORT1 Receive Frame Sync
C
DR1PRI
I
SPORT1 Receive Data Primary
DR1SEC
I
SPORT1 Receive Data Secondary
TSCLK1
I/O
SPORT1 Transmit Serial Clock
D
TFS1
I/O
SPORT1 Transmit Frame Sync
C
DT1PRI
O
SPORT1 Transmit Data Primary
C
DT1SEC
O
SPORT1 Transmit Data Secondary
C
RSCLK2/PE0
I/O
SPORT2 Receive Serial Clock/GPIO
D
RFS2/PE1
I/O
SPORT2 Receive Frame Sync/GPIO
C
DR2PRI/PE2
I/O
SPORT2 Receive Data Primary/GPIO
C
Serial Port1
Serial Port2
DR2SEC/PE3
I/O
SPORT2 Receive Data Secondary/GPIO
C
TSCLK2/PE4
I/O
SPORT2 Transmit Serial Clock/GPIO
D
TFS2/PE5
I/O
SPORT2 Transmit Frame Sync/GPIO
C
DT2PRI /PE6
I/O
SPORT2 Transmit Data Primary/GPIO
C
DT2SEC/PE7
I/O
SPORT2 Transmit Data Secondary/GPIO
C
Rev. A |
Page 23 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
Table 10. Pin Descriptions (Continued)
Type Description
Driver
Type1
RSCLK3/PE8
I/O
SPORT3 Receive Serial Clock/GPIO
D
RFS3/PE9
I/O
SPORT3 Receive Frame Sync/GPIO
C
DR3PRI/PE10
I/O
SPORT3 Receive Data Primary/GPIO
C
DR3SEC/PE11
I/O
SPORT3 Receive Data Secondary/GPIO
C
TSCLK3/PE12
I/O
SPORT3 Transmit Serial Clock/GPIO
D
TFS3/PE13
I/O
SPORT3 Transmit Frame Sync/GPIO
C
DT3PRI /PE14
I/O
SPORT3 Transmit Data Primary/GPIO
C
DT3SEC/PE15
I/O
SPORT3 Transmit Data Secondary/GPIO
C
MOSI0
I/O
SPI0 Master Out Slave In
C
MISO0
I/O
SPI0 Master In Slave Out (This pin should always be pulled high through a 4.7 kΩ C
resistor if booting via the SPI port.)
SCK0
I/O
SPI0 Clock
D
MOSI1/PD0
I/O
SPI1 Master Out Slave In/GPIO
C
MISO1/PD1
I/O
SPI1 Master In Slave Out/GPIO
C
Pin Name
Serial Port3
SPI0 Port
SPI1 Port
SCK1/PD2
I/O
SPI1 Clock/GPIO
D
SPI1SS/PD3
I/O
SPI1 Slave Select Input/GPIO
D
SPI1SEL1/PD4
I/O
SPI1 Slave Select Enable/GPIO
D
MOSI2 /PD5
I/O
SPI2 Master Out Slave In/GPIO
C
MISO2/PD6
I/O
SPI2 Master In Slave Out/GPIO
C
SCK2/PD7
I/O
SPI2 Clock/GPIO
D
SPI2SS/PD8
I/O
SPI2 Slave Select Input/GPIO
D
SPI2SEL1/PD9
I/O
SPI2 Slave Select Enable/GPIO
D
RX0
I
UART Receive
TX0
O
UART Transmit
C
RX1/PD10
I/O
UART1 Receive/GPIO
D
TX1/PD11
I/O
UART1 Transmit/GPIO
D
RX2 /PD12
I/O
UART2 Receive/GPIO
D
TX2/PD13
I/O
UART2 Transmit/GPIO
D
RTXI
I
RTC Crystal Input (This pin should be pulled low when not used.)
RTXO
O
RTC Crystal Output
SPI2 Port
UART0 Port
UART1 Port
UART2 Port
Real-Time Clock
Rev. A |
Page 24 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
Table 10. Pin Descriptions (Continued)
Pin Name
Driver
Type1
Type Description
JTAG Port
TCK
I
JTAG Clock
TDO
O
JTAG Serial Data Out
TDI
I
JTAG Serial Data In
TMS
I
JTAG Mode Select
TRST
I
JTAG Reset (This pin should be pulled low if the JTAG port will not be used.)
EMU
O
Emulation Output
CLKIN
I
Clock/Crystal Input
XTAL
O
Crystal Output
RESET
I
Reset
NMI
I
Nonmaskable Interrupt (This pin should be pulled high when not used.)
BMODE1–0
I
Boot Mode Strap
VROUT0
O
External FET Drive 0 (This pin should be left unconnected when not used.)
VROUT1
O
External FET Drive 1 (This pin should be left unconnected when not used.)
VDDEXT
P
I/O Power Supply
VDDINT
P
Internal Power Supply
VDDRTC
P
Real-Time Clock Power Supply
MPIVDD
P
MXVR Internal Power Supply
MXEVDD
P
MXVR External Power Supply
MXEGND
G
MXVR Ground
GND
G
Ground
C
C
Clock
Mode Controls
Voltage Regulator
Supplies
1
2
Refer to Figure 30 on Page 50 to Figure 39 on Page 51.
This pin is 5V-tolerant when configured as an input and an open-drain when configured as an output; therefore, only the VOL curves in Figure 34 on Page 50 and
Figure 35 on Page 50 and the Fall Time curves in Figure 47 on Page 53 and Figure 48 on Page 54 apply when configured as an output.
Rev. A |
Page 25 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
SPECIFICATIONS
Component specifications are subject to change
without notice.
OPERATING CONDITIONS
Parameter
Conditions
Min
1, 2
Nom
Max
Unit
VDDINT
Internal Supply Voltage
0.95
1.25
1.37
V
VDDEXT
External Supply Voltage3
2.7
3.3
3.6
V
VDDRTC
Real-Time Clock Power Supply
Voltage
2.7
3.3
3.6
V
VIH
High Level Input Voltage4
@ VDDEXT = Maximum
3.6
V
5
@ VDDEXT = Maximum
2.0
5.5
V
VIHCLKIN High Level Input Voltage6
@ VDDEXT = Maximum
2.2
3.6
V
VIH5V
High Level Input Voltage
2.0
VIL
Low Level Input Voltage4, 7
@ VDDEXT = Minimum
–0.3
+0.6
V
VIL5V
Low Level Input Voltage5
@ VDDEXT = Minimum
–0.3
+0.8
V
TJ
Junction Temperature
316-Ball Chip Scale Ball Grid Array (CSP_BGA) 533 MHz
@ TAMBIENT = –40°C to +85°C
–40
+105
°C
1
Parameter value applies also to MPIVDD.
The regulator can generate VDDINT at levels of 1.0 V to 1.2 V with –5% to +10% tolerance and 1.25 V with -4% to +10% tolerance.
3
Parameter value applies also to MXEVDD.
4
The 3.3 V tolerant pins are capable of accepting up to 3.6 V maximum VIH The following bidirectional pins are 3.3 V tolerant: DATA15–0, SCK2–0, MISO2–0, MOSI2–0,
PF15–0, PPI3–0, MTXON, MMCLK, MBCLK, MFS, MTX, SPI1SS, SPI1SEL1, SPI2SS, SPI2SEL1, RX2–1, TX2–1, DT2PRI, DT2SEC, TSCLK3–0, DR2PRI, DR2SEC, DT3PRI,
DT3SEC, RSCLK3–0, TFS3–0, RFS3–0, DR3PRI, DR3SEC, and TMR2–0. The following input-only pins are 3.3 V tolerant: RESET, RX0, TCK, TDI, TMS, TRST, ARDY,
BMODE1–0, BR, DR0PRI, DR0SEC, DR1PRI, DR1SEC, NMI, PPI_CLK, RTXI, and GP.
5
The 5 V tolerant pins are capable of accepting up to 5.5 V maximum VIH. The following bidirectional pins are 5 V tolerant: SCL0, SCL1, SDA0, SDA1, and CANTX. The
following input-only pins are 5 V tolerant: CANRX, MRX, MRXON.
6
Parameter value applies to the CLKIN and MXI input pins.
7
Parameter value applies to all input and bidirectional pins.
2
Rev. A |
Page 26 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
ELECTRICAL CHARACTERISTICS
Parameter1
2
VOH
High Level Output Voltage
VOL
Low Level Output Voltage2
IIH
High Level Input Current3
High Level Input Current JTAG
IIHP
4
3
Low Level Input Current
IIL
5
Test Conditions
Min
@ VDDEXT = +3.0 V, IOH = –0.5 mA
2.4
Typ
Max
Unit
@ VDDEXT = 3.0 V, IOL = 2.0 mA
0.4
V
@ VDDEXT = Maximum, VIN = VDD Maximum
10.0
μA
@ VDDEXT = Maximum, VIN = VDD Maximum
50.0
μA
@ VDDEXT = Maximum, VIN = 0 V
10.0
μA
V
IOZH
Three-State Leakage Current
@ VDDEXT = Maximum, VIN = VDD Maximum
10.0
μA
IOZL
Three-State Leakage Current5
@ VDDEXT = Maximum, VIN = 0 V
10.0
μA
CIN
Input Capacitance6, 7
fCCLK = 1 MHz, TAMBIENT = 25°C, VIN = 2.5 V
4
8
pF
IDDIHIBERNATE
VDDINT Current in Hibernate State
VDDEXT = 3.65 V with Voltage Regulator Off
(VDDINT = 0 V)
50
μA
IDDDEEPSLEEP8
VDDINT Current in Deep Sleep Mode VDDINT = 0.95 V, TJUNCTION = 25°C
28
mA
IDDSLEEP
VDDINT Current in Sleep Mode
32
mA
VDDINT = 0.95 V, TJUNCTION = 25°C @ fSCLK = 50 MHz
8, 9
VDDINT Current Dissipation (Typical) VDDINT = 0.95 V, fCCLK = 50 MHz, TJUNCTION = 25°C
47
mA
IDD_TYP8, 9
VDDINT Current Dissipation (Typical) VDDINT = 1.2 V, fCCLK = 533 MHz, TJUNCTION = 25°C
227
mA
IDDRTC
VDDRTC Current
20
μA
IDD_TYP
VDDRTC = 3.3 V, TJUNCTION = 25°C
1
Specifications subject to change without notice.
Applies to output and bidirectional pins.
3
Applies to input pins except JTAG inputs.
4
Applies to JTAG input pins (TCK, TDI, TMS, TRST).
5
Applies to three-statable pins.
6
Applies to all signal pins.
7
Guaranteed, but not tested.
8
See Power Dissipation on Page 52.
9
Processor executing 75% dual MAC, 25% ADD with moderate data bus activity.
2
Rev. A |
Page 27 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
ABSOLUTE MAXIMUM RATINGS
Stresses greater than those listed in the table may cause permanent damage to the device. These are stress ratings only.
Functional operation of the device at these or any other conditions greater than those indicated in the operational sections of
this specification is not implied. Exposure to absolute maximum
rating conditions for extended periods may affect device
reliability.
Parameter
PACKAGE INFORMATION
The information presented in Figure 10 and Table 12 provides
information about how to read the package brand and relate it
to specific product features. For a complete listing of product
offerings, see the Ordering Guide on Page 60.
a
Rating
Internal (Core) Supply Voltage (VDDINT)
External (I/O) Supply Voltage (VDDEXT)
1
2
ADSP-BF539
–0.3 V to +1.4 V
tppZccc
–0.3 V to +3.8 V
vvvvvv.x n.n
Input Voltage3, 4
–0.5 V to +3.6 V
Input Voltage4, 5
–0.5 V to +5.5 V
Output Voltage Swing
–0.5 V to VDDEXT + 0.5 V
Load Capacitance6
200 pF
Junction Temperature Under Bias
+125°C
Storage Temperature Range
–65°C to +150°C
yyww country_of_origin
B
Figure 10. Product Information on Package
Table 12. Package Brand Information
1
Parameter value applies also to MPIVDD.
Parameter value applies also to MXEVDD and VDDRTC.
3
Applies to 100% transient duty cycle. For other duty cycles, see Table 11.
4
Applies only when VDDEXT is within specifications. When VDDEXT is outside specifications, the range is VDDEXT 0.2 V.
5
Applies to pins designated as 5 V tolerant only.
6
For proper SDRAM controller operation, the maximum load capacitance is 50 pF
for ADDR19–1, DATA15–0, ABE1–0/SDQM1–0, CLKOUT, SCKE, SA10, SRAS,
SCAS, SWE, and SMS.
2
1
Table 11. Maximum Duty Cycle for Input Transient Voltage
VIN Min (V)
VIN Max (V)2
Maximum Duty Cycle
–0.50
+3.80
100%
–0.70
+4.00
40%
–0.80
+4.10
25%
–0.90
+4.20
15%
–1.00
+4.30
10%
Brand Key
Field Description
W
Automotive Grade (Optional)
t
Temperature Range
pp
Package Type
Z
RoHS Compliant Part
ccc
See Ordering Guide
vvvvvv.x
Assembly Lot Code
n.n
Silicon Revision
yyww
Date Code
1
Applies to all signal pins with the exception of CLKIN, MXI, MXO, MLF,
VROUT1–0, XTAL, RTXI, and RTXO
2
Only one of the listed options can apply to a particular design.
ESD SENSITIVITY
ESD (electrostatic discharge) sensitive device.
Charged devices and circuit boards can discharge
without detection. Although this product features
patented or proprietary circuitry, damage may occur
on devices subjected to high energy ESD. Therefore,
proper ESD precautions should be take to avoid
performance degradation or loss of functionality.
Rev. A |
Page 28 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
TIMING SPECIFICATIONS
Table 13 describes the timing requirements for the
ADSP-BF539/ADSP-BF539F processor clocks. Take care in
selecting MSEL, SSEL, and CSEL ratios so as not to exceed the
maximum core clock, system clock, and voltage-controlled
oscillator (VCO) operating frequencies, as described in Absolute Maximum Ratings on Page 28. Table 14 describes phaselocked loop operating conditions. Table 15 lists system clock
requirements.
Table 13. Core Clock (CCLK) Requirements
Parameter
fCCLK
fCCLK
fCCLK
fCCLK
Description
CLK Frequency (VDDINT =
CLK Frequency (VDDINT =
CLK Frequency (VDDINT =
CLK Frequency (VDDINT =
Internal Regulator
Setting
1.2 V Minimum)
1.14 V Minimum)
1.045 V Minimum)
0.95 V Minimum)
1.25 V
1.20 V
1.10 V
1.00 V
Max
533
500
444
400
Unit
MHz
MHz
MHz
MHz
Table 14. Phase-Locked Loop Operating Conditions
Parameter Description
Min
Max
Unit
fVCO
50
Max fCCLK
MHz
Max
1332
100
Unit
MHz
MHz
Voltage Controlled Oscillator (VCO) Frequency
Table 15. System Clock (SCLK) Requirements
Parameter1 Description
fSCLK
CLKOUT/SCLK Frequency (VDDINT ≥ 1.14 V)
fSCLK
CLKOUT/SCLK Frequency (VDDINT < 1.14 V)
1
2
tSCLK (= 1/fSCLK) must be greater than or equal to tCCLK
Guaranteed to tSCLK = 7.5 ns. See Table 21 on Page 35.
Rev. A |
Page 29 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
Clock and Reset Timing
Table 16 and Figure 11 describe clock and reset operations. Per
Absolute Maximum Ratings on Page 28, combinations of
CLKIN and clock multipliers must not select core/peripheral
clocks that exceed maximum operating conditions.
Table 16. Clock and Reset Timing
Parameter
Min
Max
100.0
Unit
Timing Requirements
tCKIN
CLKIN Period1, 2, 3
20.0
tCKINL
CLKIN Low Pulse
8.0
tCKINH
CLKIN High Pulse
8.0
ns
tWRST
RESET Asserted Pulse Width Low4
11 tCKIN
ns
1
ns
ns
Applies to PLL bypass mode and PLL non-bypass mode.
If the DF bit in the PLL_CTL register is set, then the maximum tCKIN period is 50 ns.
3
CLKIN frequency must not change on the fly.
4
Applies after power-up sequence is complete. At power-up, the processor’s internal phase-locked loop requires no more than 2000 CLKIN cycles, while RESET is asserted,
assuming stable power supplies and CLKIN (not including startup time of external clock oscillator).
2
tCKIN
CLKIN
tCKINL
tCKINH
tWRST
RESET
Figure 11. Clock and Reset Timing
Rev. A |
Page 30 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
Asynchronous Memory Read Cycle Timing
Table 17 and Table 18 on Page 32 and Figure 12 and Figure 13
on Page 32 describe asynchronous memory read cycle operations for synchronous and for asynchronous ARDY.
Table 17. Asynchronous Memory Read Cycle Timing with Synchronous ARDY
Parameter
Min
Max
Unit
Timing Requirements
tSDAT
DATA15–0 Setup Before CLKOUT
2.1
ns
tHDAT
DATA15–0 Hold After CLKOUT
0.8
ns
tSARDY
ARDY Setup Before the Falling Edge of CLKOUT
4.0
ns
tHARDY
ARDY Hold After the Falling Edge of CLKOUT
0.0
ns
tDO
Output Delay After CLKOUT1
tHO
1
Output Hold After CLKOUT
6.0
1
ns
0.8
ns
Output pins include AMS3–0, ABE1–0, ADDR19–1, AOE, ARE.
SETUP
2 CYCLES
PROGRAMMED READ ACCESS
4 CYCLES
HOLD
1 CYCLE
ACCESS EXTENDED
3 CYCLES
CLKOUT
tDO
tHO
AMSx
ABE1–0
BE, ADDRESS
ADDR19–1
AOE
tDO
tHO
ARE
tHARDY
tSARDY
tHARDY
ARDY
tSARDY
tSDAT
tHDAT
DATA15–0
READ
Figure 12. Asynchronous Memory Read Cycle Timing with Synchronous ARDY
Rev. A |
Page 31 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
Table 18. Asynchronous Memory Read Cycle Timing with Asynchronous ARDY
Parameter
Min
Max
Unit
Timing Requirements
tSDAT
DATA15–0 Setup Before CLKOUT
2.1
tHDAT
DATA15–0 Hold After CLKOUT
0.8
tDANR
ARDY Negated Delay from AMSx Asserted1
tHAA
ARDY Asserted Hold After ARE Negated
tDO
Output Delay After CLKOUT2
tHO
Output Hold After CLKOUT
ns
ns
(S+RA–2) tSCLK
0.0
ns
6.0
2
0.8
S = number of programmed setup cycles, RA = number of programmed read access cycles.
2
Output pins include AMS3–0, ABE1–0, ADDR19–1, AOE, ARE.
PROGRAMMED READ ACCESS
4 CYCLES
HOLD
1 CYCLE
ACCESS EXTENDED
CLKOUT
tDO
tHO
AMSx
ABE1–0
BE, ADDRESS
ADDR19–1
AOE
tDO
tHO
ARE
tHAA
tDANR
ARDY
tSDAT
tHDAT
DATA15–0
READ
Figure 13. Asynchronous Memory Read Cycle Timing with Asynchronous ARDY
Rev. A |
Page 32 of 60 |
February 2008
ns
ns
1
SETUP
2 CYCLES
ns
ADSP-BF539/ADSP-BF539F
Asynchronous Memory Write Cycle Timing
Table 19 and Table 20 on Page 34 and Figure 14 and Figure 15
on Page 34 describe asynchronous memory write cycle operations for synchronous and for asynchronous ARDY.
Table 19. Asynchronous Memory Write Cycle Timing with Synchronous ARDY
Parameter
Min
Max
Unit
Timing Requirements
tSARDY
ARDY Setup Before the Falling Edge of CLKOUT
4.0
ns
tHARDY
ARDY Hold After the Falling Edge of CLKOUT
0.0
ns
Switching Characteristics
tDDAT
DATA15–0 Disable After CLKOUT
tENDAT
DATA15–0 Enable After CLKOUT
tDO
Output Delay After CLKOUT
tHO
Output Hold After CLKOUT1
1
6.0
1.0
1
Output pins include AMS3–0, ABE1–0, ADDR19–1, DATA15–0, AOE, AWE.
SETUP
2 CYCLES
ACCESS
EXTENDED
1 CYCLE
PROGRAMMED WRITE
ACCESS 2 CYCLES
HOLD
1 CYCLE
CLKOUT
t DO
t HO
AMSx
ABE1–0
BE, ADDRESS
ADDR19–1
tDO
tHO
AWE
t SARDY
ARDY
t SARDY
t ENDAT
DATA15–0
ns
6.0
0.8
t HARDY
t HARDY
t DDAT
WRITE DATA
Figure 14. Asynchronous Memory Write Cycle Timing with Synchronous ARDY
Rev. A |
Page 33 of 60 |
February 2008
ns
ns
ns
ADSP-BF539/ADSP-BF539F
Table 20. Asynchronous Memory Write Cycle Timing with Asynchronous ARDY
Parameter
Min
Max
Unit
(S+WA–2) tSCLK
ns
Timing Requirements
tDANR
ARDY Negated Delay from AMSx Asserted1
tHAA
ARDY Asserted Hold After ARE Negated
0.0
ns
Switching Characteristics
tDDAT
DATA15–0 Disable After CLKOUT
tENDAT
DATA15–0 Enable After CLKOUT
tDO
Output Delay After CLKOUT
tHO
Output Hold After CLKOUT2
1
2
6.0
1.0
2
S = Number of programmed setup cycles, WA = Number of programmed write access cycles.
Output pins include AMS3–0, ABE1–0, ADDR19–1, DATA15–0, AOE, AWE.
SETUP
2 CYCLES
PROGRAMMED WRITE
ACCESS 2 CYCLES
ACCESS
EXTENDED
HOLD
1 CYCLE
CLKOUT
t DO
t HO
AMSx
ABE1–0
BE, ADDRESS
ADDR19–1
tDO
tHO
AWE
tDANW
tHAA
ARDY
t ENDAT
DATA15–0
ns
6.0
0.8
WRITE DATA
Figure 15. Asynchronous Memory Write Cycle Timing with Asynchronous ARDY
Rev. A |
Page 34 of 60 |
February 2008
ns
ns
ns
ADSP-BF539/ADSP-BF539F
SDRAM Interface Timing
Table 21. SDRAM Interface Timing
Parameter
Min
Max
Unit
Timing Requirements
tSSDAT
DATA Setup Before CLKOUT
2.1
ns
tHSDAT
DATA Hold After CLKOUT
0.8
ns
Switching Characteristics
tSCLK
CLKOUT Period1
7.5
ns
tSCLKH
CLKOUT Width High
2.5
ns
tSCLKL
CLKOUT Width Low
2.5
ns
tDCAD
Command, ADDR, Data Delay After CLKOUT
tHCAD
Command, ADDR, Data Hold After CLKOUT2
tDSDAT
Data Disable After CLKOUT
tENSDAT
Data Enable After CLKOUT
1
2
2
6.0
0.8
ns
6.0
1.0
tSCLKH
CLKOUT
tSSDAT
tSCLKL
t HSDAT
DATA (IN)
tDCAD
tENSDAT
t DCAD
CMND ADDR
(OUT)
t HCAD
NOTE: COMMAND = SRAS, SCAS, SWE, SDQM, SMS, SA10, SCKE.
Figure 16. SDRAM Interface Timing
Rev. A |
Page 35 of 60 |
tD SDA T
tHCAD
DATA(OUT)
February 2008
ns
ns
SDRAM timing for TJUNCTION = 125°C is limited to 100 MHz.
Command pins include: SRAS, SCAS, SWE, SDQM, SMS, SA10, SCKE.
t SCLK
ns
ADSP-BF539/ADSP-BF539F
External Port Bus Request and Grant Cycle Timing
Table 22 and Table 23 on Page 37 and Figure 17 and Figure 18
on Page 37 describe external port bus request and grant cycle
operations for synchronous and for asynchronous BR.
Table 22. External Port Bus Request and Grant Cycle Timing with Synchronous BR
Parameter
Min
Max
Unit
Timing Requirements
tBS
BR Setup to Falling Edge of CLKOUT
4.0
ns
tBH
Falling Edge of CLKOUT to BR Deasserted Hold Time
0.0
ns
Switching Characteristics
tSD
CLKOUT Low to AMSx, Address, and ARE/AWE Disable
4.5
ns
tSE
CLKOUT Low to AMSx, Address, and ARE/AWE Enable
4.5
ns
tDBG
CLKOUT High to BG High Setup
3.6
ns
tEBG
CLKOUT High to BG Deasserted Hold Time
3.6
ns
tDBH
CLKOUT High to BGH High Setup
3.6
ns
tEBH
CLKOUT High to BGH Deasserted Hold Time
3.6
ns
CLKOUT
tBH
tBS
BR
tSD
tSE
AMSx
tSD
tSE
ADDR19-1
ABE1-0
tSD
tSE
AWE
ARE
tDBG
tEBG
BG
tDBH
BGH
Figure 17. External Port Bus Request and Grant Cycle Timing with Synchronous BR
Rev. A |
Page 36 of 60 |
February 2008
tEBH
ADSP-BF539/ADSP-BF539F
Table 23. External Port Bus Request and Grant Cycle Timing with Asynchronous BR
Parameter
Min
Max
Unit
Timing Requirement
tWBR
2 tSCLK
BR Pulse Width
ns
Switching Characteristics
tSD
CLKOUT Low to AMSx, Address, and ARE/AWE Disable
tSE
CLKOUT Low to AMSx, Address, and ARE/AWE Enable
4.5
ns
tDBG
CLKOUT High to BG High Setup
3.6
ns
tEBG
CLKOUT High to BG Deasserted Hold Time
3.6
ns
tDBH
CLKOUT High to BGH High Setup
3.6
ns
tEBH
CLKOUT High to BGH Deasserted Hold Time
3.6
ns
4.5
ns
CLKOUT
tWBR
BR
tSD
tSE
AMSx
tSD
tSE
ADDR19-1
ABE1-0
tSD
tSE
AWE
ARE
tDBG
tEBG
BG
tDBH
BGH
Figure 18. External Port Bus Request and Grant Cycle Timing with Asynchronous BR
Rev. A |
Page 37 of 60 |
February 2008
tEBH
ADSP-BF539/ADSP-BF539F
Parallel Peripheral Interface Timing
Table 24 and Figure 19, Figure 20, Figure 21, and Figure 22
describe Parallel Peripheral Interface operations.
Table 24. Parallel Peripheral Interface Timing
Parameter
Min
Max
Unit
Timing Requirements
tPCLKW
PPI_CLK Width
6.0
1
ns
tPCLK
PPI_CLK Period
tSFSPE
External Frame Sync Setup Before PPI_CLK
tHFSPE
External Frame Sync Hold After PPI_CLK
1.0
ns
tSDRPE
Receive Data Setup Before PPI_CLK
2.0
ns
tHDRPE
Receive Data Hold After PPI_CLK
4.0
ns
15.0
ns
5.0
ns
Switching Characteristics—GP Output and Frame Capture Modes
tDFSPE
Internal Frame Sync Delay After PPI_CLK
tHOFSPE
Internal Frame Sync Hold After PPI_CLK
tDDTPE
Transmit Data Delay After PPI_CLK
tHDTPE
Transmit Data Hold After PPI_CLK
1
10.0
0.0
PPI_CLK frequency cannot exceed fSCLK/2
FRAME
SYNC IS
DRIVEN
OUT
DATA0
IS
SAMPLED
POLC = 0
PPI_CLK
PPI_CLK
POLC = 1
tDFSPE
t
ns
10.0
0.0
HOFSPE
POLS = 1
PPI_FS1
POLS = 0
POLS = 1
PPI_FS2
POLS = 0
tSDRPE
tHDRPE
PPI_DATA
Figure 19. PPI GP Rx Mode with Internal Frame Sync Timing
Rev. A |
Page 38 of 60 |
February 2008
ns
ns
ns
ADSP-BF539/ADSP-BF539F
FRAME
SYNC IS
SAMPLED
FOR
DATA0
DATA0 IS
SAMPLED
DATA1 IS
SAMPLED
PPI_CLK
POLC = 0
PPI_CLK
POLC = 1
tHFSPE
tSFSPE
POLS = 1
PPI_FS1
POLS = 0
POLS = 1
PPI_FS2
POLS = 0
t
t
SDRPE
HDRPE
PPI_DATA
Figure 20. PPI GP Rx Mode with External Frame Sync Timing
FRAME
SYNC IS
SAMPLED
DATA0 IS
DRIVEN
OUT
PPI_CLK
POLC = 0
PPI_CLK
POLC = 1
tHFSPE
t
SFSPE
POLS = 1
PPI_FS1
POLS = 0
POLS = 1
PPI_FS2
POLS = 0
tHDTPE
PPI_DATA
DATA0
t
DDTPE
Figure 21. PPI GP Tx Mode with External Frame Sync Timing
Rev. A |
Page 39 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
FRAME
SYNC IS
DRIVEN
OUT
DATA0 IS
DRIVEN
OUT
PPI_CLK
POLC = 0
PPI_CLK
POLC = 1
tDFSPE
tHOFSPE
POLS = 1
PPI_FS1
POLS = 0
POLS = 1
PPI_FS2
POLS = 0
t
DDTPE
t
HDTPE
PPI_DATA
DATA0
Figure 22. PPI GP Tx Mode with Internal Frame Sync Timing
Rev. A |
Page 40 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
Serial Ports Timing
Table 25 through Table 28 on Page 42 and Figure 23 on Page 42
through Figure 24 on Page 43 describe Serial Port operations.
Table 25. Serial Ports—External Clock
Parameter
Min
Max
Unit
Timing Requirements
tSFSE
TFSx/RFSx Setup Before TSCLKx/RSCLKx (Externally Generated TFSx/RFSx)1
tHFSE
TFSx/RFSx Hold After TSCLKx/RSCLKx (Externally Generated TFSx/RFSx)
tSDRE
Receive Data Setup Before RSCLKx1
1
1
3.0
ns
3.0
ns
3.0
ns
tHDRE
Receive Data Hold After RSCLKx
3.0
ns
tSCLKEW
TSCLKx/RSCLKx Width
4.5
ns
tSCLKE
TSCLKx/RSCLKx Period
15.0
ns
Switching Characteristics
tDFSE
TFSx/RFSx Delay After TSCLKx/RSCLKx (Internally Generated TFSx/RFSx)2
tHOFSE
TFSx/RFSx Hold After TSCLKx/RSCLKx (Internally Generated TFSx/RFSx)2
tDDTE
Transmit Data Delay After TSCLKx
tHDTE
Transmit Data Hold After TSCLKx2
1
2
10.0
0.0
2
ns
ns
10.0
0.0
ns
ns
Referenced to sample edge.
Referenced to drive edge.
Table 26. Serial Ports—Internal Clock
Parameter
Min
Max
Unit
Timing Requirements
tSFSI
TFSx/RFSx Setup Before TSCLKx/RSCLKx (Externally Generated TFSx/RFSx)1
8.0
ns
tHFSI
TFSx/RFSx Hold After TSCLKx/RSCLKx (Externally Generated TFSx/RFSx)1
–1.5
ns
tSDRI
Receive Data Setup Before RSCLKx1
8.0
ns
tHDRI
Receive Data Hold After RSCLKx1
–1.5
ns
tSCLKEW
TSCLKx/RSCLKx Width
4.5
ns
tSCLKE
TSCLKx/RSCLKx Period
15.0
ns
Switching Characteristics
tDFSI
TFSx/RFSx Delay After TSCLKx/RSCLKx (Internally Generated TFSx/RFSx)2
tHOFSI
TFSx/RFSx Hold After TSCLKx/RSCLKx (Internally Generated TFSx/RFSx)
tDDTI
Transmit Data Delay After TSCLKx2
tHDTI
Transmit Data Hold After TSCLKx
tSCLKIW
TSCLKx/RSCLKx Width
1
2
2
3.0
–1.0
ns
3.0
2
ns
ns
–2.0
ns
4.5
ns
Referenced to sample edge.
Referenced to drive edge.
Table 27. Serial Ports—Enable and Three-State
Parameter
Min
Max
Unit
Switching Characteristics
tDTENE
Data Enable Delay from External TSCLKx1
0
1
tDDTTE
Data Disable Delay from External TSCLKx
tDTENI
Data Enable Delay from Internal TSCLKx1
tDDTTI
Data Disable Delay from Internal TSCLKx1
1
10.0
–2.0
Page 41 of 60 |
February 2008
ns
ns
3.0
Referenced to drive edge.
Rev. A |
ns
ns
ADSP-BF539/ADSP-BF539F
Table 28. External Late Frame Sync
Parameter
Min
Max
Unit
10.0
ns
Switching Characteristics
Data Delay from Late External TFSx or External RFSx with MCE = 1, MFD = 01, 2
tDDTLFSE
Data Enable from Late FS or MCE = 1, MFD = 0
tDTENLFS
1, 2
0
ns
1
MCE = 1, TFSx enable and TFSx valid follow tDTENLFS and tDDTLFSE.
2
If external RFSx/TFSx setup to RSCLKx/TSCLKx > tSCLKE/2, then tDDTTE/I and tDTENE/I apply; otherwise tDDTLFSE and tDTENLFS apply.
DATA RECEIVE—INTERNAL CLOCK
DATA RECEIVE—EXTERNAL CLOCK
DRIVE
EDGE
DRIVE
EDGE
SAMPLE
EDGE
SAMPLE
EDGE
tSCLKIW
tSCLKEW
RSCLKx
RSCLKx
tDFSI
tDFSE
tHOFSI
tSFSI
tHFSI
RFSx
tHOFSE
tSFSE
tHFSE
tSDRE
tHDRE
RFSx
tSDRI
tHDRI
DRx
DRx
NOTE: EITHER THE RISING EDGE OR FALLING EDGE OF RSCLKx OR TSCLKx CAN BE USED AS THE ACTIVE SAMPLING EDGE.
DATA TRANSMIT—INTERNAL CLOCK
DRIVE
EDGE
DATA TRANSMIT—EXTERNAL CLOCK
DRIVE
EDGE
SAMPLE
EDGE
tSCLKIW
SAMPLE
EDGE
tSCLKEW
TSCLKx
TSCLKx
tDFSI
tHOFSI
tDFSE
tSFSI
tHFSI
tHOFSE
TFSx
tSFSE
TFSx
tDDTI
tDDTE
tHDTI
tHDTE
DTx
DTx
NOTE: EITHER THE RISING EDGE OR FALLING EDGE OF RSCLKx OR TSCLKx CAN BE USED AS THE ACTIVE SAMPLING EDGE.
Figure 23. Serial Ports
Rev. A |
Page 42 of 60 |
February 2008
tHFSE
ADSP-BF539/ADSP-BF539F
EXTERNAL RFSx WITH MCE = 1, MFD = 0
DRIVE
RSCLKx
SAMPLE
DRIVE
tSFSE/I
tHOFSE/I
RFSx
tDDTTE/I
tDTENE/I
tDTENLFS
1ST BIT
DTx
2ND BIT
tDDTLFSE
LATE EXTERNAL TFSx
DRIVE
TSCLKx
SAMPLE
DRIVE
tHOFSE/I
tSFSE/I
TFSx
tDDTTE/I
tDTENE/I
tDTENLFS
DTx
1ST BIT
2ND BIT
tDDTLFSE
Figure 24. External Late Frame Sync
Rev. A |
Page 43 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
Serial Peripheral Interface Ports—Master Timing
Table 29 and Figure 25 describe SPI ports master operations.
Table 29. Serial Peripheral Interface (SPI) Ports—Master Timing
Parameter
Min
Max
Unit
Timing Requirements
tSSPIDM
Data Input Valid to SCKx Edge (Data Input Setup)
7.5
ns
tHSPIDM
SCKx Sampling Edge to Data Input Invalid
–1.5
ns
Switching Characteristics
tSDSCIM
SPIxSELy Low to First SCKx edge
2tSCLK –1.5
ns
tSPICHM
Serial Clock High Period
2tSCLK –1.5
ns
tSPICLM
Serial Clock Low Period
2tSCLK –1.5
ns
tSPICLK
Serial Clock Period
4tSCLK –1.5
ns
tHDSM
Last SCKx Edge to SPIxSELy High
2tSCLK –1.5
ns
tSPITDM
Sequential Transfer Delay
2tSCLK –1.5
ns
tDDSPIDM
SCKx Edge to Data Out Valid (Data Out Delay)
0
6
ns
tHDSPIDM
SCKx Edge to Data Out Invalid (Data Out Hold)
–1.0
+4.0
ns
SPIxSELy
(OUTPUT)
tSDSCIM
tSPICHM
tSPICLM
tSPICLM
tSPICHM
tSPICLK
tHDSM
SCKx
(CPOL = 0)
(OUTPUT)
SCKx
(CPOL = 1)
(OUTPUT)
tDDSPIDM
MOSIx
(OUTPUT)
tHDSPIDM
MSB
CPHA=1
tSSPIDM
MISOx
(INPUT)
LSB
tHSPIDM
tSSPIDM
MSB VALID
LSB VALID
tDDSPIDM
MOSIx
(OUTPUT)
CPHA=0
MISOx
(INPUT)
tHSPIDM
tHDSPIDM
MSB
tSSPIDM
LSB
tHSPIDM
MSB VALID
LSB VALID
Figure 25. Serial Peripheral Interface (SPI) Ports—Master Timing
Rev. A |
Page 44 of 60 |
February 2008
tSPITDM
ADSP-BF539/ADSP-BF539F
Serial Peripheral Interface Ports—Slave Timing
Table 30 and Figure 26 describe SPI ports slave operations.
Table 30. Serial Peripheral Interface (SPI) Ports—Slave Timing
Parameter
Min
Max
Unit
Timing Requirements
tSPICHS
Serial Clock High Period
2tSCLK –1.5
ns
tSPICLS
Serial Clock Low Period
2tSCLK –1.5
ns
tSPICLK
Serial Clock Period
4tSCLK –1.5
ns
tHDS
Last SCKx Edge to SPIxSS Not Asserted
2tSCLK –1.5
ns
tSPITDS
Sequential Transfer Delay
2tSCLK –1.5
ns
tSDSCI
SPIxSS Assertion to First SCKx Edge
2tSCLK –1.5
ns
tSSPID
Data Input Valid to SCKx Edge (Data Input Setup)
1.6
ns
tHSPID
SCKx Sampling Edge to Data Input Invalid
1.6
ns
Switching Characteristics
tDSOE
SPIxSS Assertion to Data Out Active
0
8
ns
tDSDHI
SPIxSS Deassertion to Data High impedance
0
8
ns
tDDSPID
SCKx Edge to Data Out Valid (Data Out Delay)
0
10
ns
tHDSPID
SCKx Edge to Data Out Invalid (Data Out Hold)
0
10
ns
SPIxSS
(INPUT)
tSPICHS
tSPICLS
tSPICLS
tSPICHS
tSPICLK
tHDS
tSPITDS
SCKx
(CPOL = 0)
(INPUT)
tSDSCI
SCKx
(CPOL = 1)
(INPUT)
tDSOE
tDDSPID
tHDSPID
MISOx
(OUTPUT)
tDSDHI
MSB
CPHA=1
tSSPID
MOSIx
(INPUT)
LSB
tHSPID
tSSPID
tHSPID
MSB VALID
tDSOE
MISOx
(OUTPUT)
tDDSPID
LSB VALID
tDDSPID
tDSDHI
MSB
LSB
tHSPID
CPHA=0
tSSPID
MOSIx
(INPUT)
MSB VALID
LSB VALID
Figure 26. Serial Peripheral Interface (SPI) Ports—Slave Timing
Rev. A |
Page 45 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
General-Purpose Port Timing
Table 31 and Figure 27 describe general-purpose operations.
Table 31. General-Purpose Port Timing
Parameter
Min
Max
Unit
Timing Requirement
tWFI
GP Port Pin Input Pulse Width
tSCLK + 1
ns
Switching Characteristic
tGPOD
GP Port Pin Output Delay from CLKOUT Low
6
CLKOUT
tGPOD
GPP OUTPUT
tGPOD
GPP O/D OUTPUT
tWFI
GPP INPUT
Figure 27. General-Purpose Port Cycle Timing
Rev. A |
Page 46 of 60 |
February 2008
ns
ADSP-BF539/ADSP-BF539F
Timer Cycle Timing
Table 32 and Figure 28 describe timer expired operations. The
input signal is asynchronous in “width capture mode” and
“external clock mode” and has an absolute maximum input frequency of fSCLK/2 MHz.
Table 32. Timer Cycle Timing
Parameter
Min
Max
Unit
Timing Characteristics
tWL
Timer Pulse Width Input Low1 (Measured in SCLK Cycles)
1
SCLK
tWH
Timer Pulse Width Input High1 (Measured in SCLK Cycles)
1
SCLK
Switching Characteristic
tHTO
1
Timer Pulse width Output (measured in SCLK Cycles)
1
(232 – 1)
SCLK
The minimum pulse widths apply for TMRx input pins in width capture and external clock modes. They also apply to the PF1 or PPI_CLK input pins in PWM output mode.
CLKOUT
tHTO
TMRx
(PWM OUTPUT MODE)
TMRx
(WIDTH CAPTURE AND
EXTERNAL CLOCK MODES)
tWL
tWH
Figure 28. Timer PWM_OUT Cycle Timing
Rev. A |
Page 47 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
JTAG Test And Emulation Port Timing
Table 33 and Figure 29 describe JTAG port operations.
Table 33. JTAG Port Timing
Parameter
Min
Max
Unit
Timing Requirements
tTCK
TCK Period
20
tSTAP
TDI, TMS Setup Before TCK High
4
ns
tHTAP
TDI, TMS Hold After TCK High
4
ns
tSSYS
System Inputs Setup Before TCK High1
4
ns
5
ns
4
TCK
1
tHSYS
System Inputs Hold After TCK High
tTRSTW
TRST Pulse Width2 (Measured in TCK Cycles)
ns
Switching Characteristics
tDTDO
TDO Delay from TCK Low
tDSYS
System Outputs Delay After TCK Low3
0
1
10
ns
12
ns
System Inputs=ARDY, BMODE1–0, BR, DATA15–0, NMI, PF15–0, PPI_CLK, PPI3-0, SCL1-0, SDA1-0, MTXON, MRXON, MMCLK, MBCLK, MFS, MTX, MRX, SPI1SS,
SPI1SEL1, SCK2-0, MISO2-0, MOSI2-0, SPI2SS, SPI2SEL1, RX2-0, TX2-1, DR0PRI, DR0SEC, DR1PRI, DR1SEC, DT2PRI, DT2SEC, DR2PRI, DR2SEC, TSCLK3-0,
RSCLK3-0, TFS3-0, RFS3-0, DT3PRI, DT3SEC, DR3PRI, DR3SEC, CANTX, CANRX, RESET, and TMR2–0.
2
50 MHz maximum
3
System Outputs = AMS, AOE, ARE, AWE, ABE, BG, DATA15–0, PF15–0, PPI3–0, MTXON, MMCLK, MBCLK, MFS, MTX, SPI1SS, SPI1SEL1, SCK2-0,
MISO2-0, MOSI2-0, SPI2SS, SPI2SEL1, RX2-1, TX2-0, DT2PRI, DT2SEC, DR2PRI, DR2SEC, DT3PRI, DT3SEC, DR3PRI, DR3SEC, TSCLK3-0, TFS3-0, RSCLK3-0,
RFS3-0, CLKOUT, CANTX, SA10, SCAS, SCKE, SMS, SRAS, SWE, and TMR2–0.
tTCK
TCK
tSTAP
tHTAP
TMS
TDI
tDTDO
TDO
tSSYS
tHSYS
SYSTEM
INPUTS
tDSYS
SYSTEM
OUTPUTS
Figure 29. JTAG Port Timing
Rev. A |
Page 48 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
MXVR Timing
Table 34 and Table 35 describe the MXVR timing requirements.
Table 34. MXVR Timing—MXI Center Frequency Requirements
Parameter
fMXI
fs = 38 kHz
38.912
MXI Center Frequency
fs = 44.1 kHz fs = 48 kHz
45.1584
49.152
Unit
MHz
Table 35. MXVR Timing— MXI Clock Requirements
Parameter
Timing Requirements
FSMXI
MXI Clock Frequency Stability
FTMXI
MXI Frequency Tolerance Over Temperature
MXI Clock Duty Cycle
DCMXI
Rev. A |
Page 49 of 60 |
February 2008
Min
Max
Unit
–50
–300
40
+50
+300
60
ppm
ppm
%
ADSP-BF539/ADSP-BF539F
OUTPUT DRIVE CURRENTS
200
The following figures show typical current-voltage characteristics for the output drivers of the ADSP-BF539/ADSP-BF539F
processor. The curves represent the current drive capability of
the output drivers as a function of output voltage.
SOURCE CURRENT (mA)
100
SOURCE CURRENT (mA)
VD D EX T = 2.75V
60
V OH
40
VD D E XT = 3.3V
VD DE XT = 3.6V
100
120
80
VD D E XT = 3.0V
150
VO H
50
0
-50
-100
VOL
-150
20
-200
0
0
0. 5
1.0
1.5
2.0
2.5
3. 0
3.5
4.0
SOURCE VOLTAGE (V)
-20
-40
Figure 33. Drive Current B (High VDDEXT)
V OL
-60
80
-80
-100
0
0.5
1.0
1.5
2.0
Figure 30. Drive Current A (Low VDDEXT)
150
V DD E XT = 3.0V
SOURCE CURRENT (mA)
V DD E XT = 2.75V
SOURCE CURRENT (mA)
SOURCE VOL TAGE (V)
V DD E XT = 3.3V
VD D EX T = 3.6V
100
60
3.0
2.5
V OH
20
0
-20
VOL
-40
50
VO H
-60
0
0
0.5
1.0
1.5
2.0
2. 5
3.0
SOURCE VOLTAGE (V)
-50
Figure 34. Drive Current C (Low VDDEXT)
VOL
-100
100
V D DE XT = 3.0V
80
-150
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
Figure 31. Drive Current A (High VDDEXT)
150
100
VD D EX T = 2.75V
V D DE XT = 3.3V
VD DE XT = 3.6V
60
SOURCE CURRENT (mA)
SOURCE VOLTAGE (V)
SOURCE CURRENT (mA)
40
40
VOH
20
0
-20
-40
VO L
50
-60
V OH
-80
0
0
0. 5
1.0
1.5
2.0
2.5
SOURCE VOLTAGE (V)
-50
Figure 35. Drive Current C (High VDDEXT)
V OL
-100
-150
0
0.5
1.0
1.5
2.0
2. 5
3.0
SOURCE VOLTAGE (V)
Figure 32. Drive Current B (Low VDDEXT)
Rev. A |
Page 50 of 60 |
February 2008
3. 0
3.5
4.0
ADSP-BF539/ADSP-BF539F
100
0
80
-10
VD D EX T = 2.75V
VD D EX T = 3. 3 V
VD D EX T = 3. 6 V
-20
SOURCE CURRENT (mA)
SOURCE CURRENT (mA)
60
VD D EX T = 3. 0 V
40
VOH
20
0
-20
-40
V OL
-30
-40
VOL
-50
-60
-70
-60
-80
-80
0
0.5
1.0
1. 5
2.0
2.5
3.0
0
150
VD D EX T = 3.0V
VD D EX T = 3.3V
VD D EX T = 3.6V
SOURCE CURRENT (mA)
50
VOH
0
-50
V OL
-100
-150
0
0. 5
1.0
1.5
2.0
2.5
3. 0
3.5
4.0
SOURCE VOLTAGE (V)
Figure 37. Drive Current D (High VDDEXT)
0
-10
SOURCE CURRENT (mA)
VD DE XT = 2.75V
-20
-30
V OL
-40
-50
-60
0
0.5
1.0
1.5
2.0
1.0
1.5
2.0
2.5
Figure 39. Drive Current E (High VDDEXT)
Figure 36. Drive Current D (Low VDDEXT)
100
0. 5
SOURCE VOLTAGE (V)
SOURCE VOLTAGE (V)
2.5
3.0
SOURCE VOLTAGE (V)
Figure 38. Drive Current E (Low VDDEXT)
Rev. A |
Page 51 of 60 |
February 2008
3. 0
3.5
4.0
ADSP-BF539/ADSP-BF539F
t DECAY = ( C L ΔV ) ⁄ I L
POWER DISSIPATION
Many operating conditions can affect power dissipation. System
designers should refer to Estimating Power for ADSPBF538/ADSP-BF539 Blackfin Processors (EE-298) on the Analog
Devices, Inc. website (www.analog.com)—use site search on
“EE-298.” This document provides detailed information for
optimizing your design for lowest power.
See the ADSP-BF539/BF539F Blackfin Processor Hardware Reference Manual for definitions of the various operating modes
and for instructions on how to minimize system power.
TEST CONDITIONS
All timing parameters appearing in this data sheet were measured under the conditions described in this section. Figure 40
shows the measurement point for ac measurements (except output enable/disable). The measurement point VMEAS is 1.5 V for
VDDEXT (nominal) = 3.3 V.
INPUT
OR
OUTPUT
VMEAS
The time tDECAY is calculated with test loads CL and IL, and with
ΔV equal to 0.5 V for VDDEXT (nominal) = 3.3 V.
The time tDIS+_MEASURED is the interval from when the reference
signal switches, to when the output voltage decays ΔV from the
measured output high or output low voltage.
Example System Hold Time Calculation
To determine the data output hold time in a particular system,
first calculate tDECAY using the equation given above. Choose ΔV
to be the difference between the ADSP-BF539/ADSP-BF539F
processor output voltage and the input threshold for the device
requiring the hold time. CL is the total bus capacitance (per data
line), and IL is the total leakage or three-state current (per data
line). The hold time will be tDECAY plus the various output disable times as specified in the Timing Specifications on Page 29
(for example tDSDAT for an SDRAM write cycle as shown in
Table 21 on Page 35).
VMEAS
REFERENCE
SIGNAL
Figure 40. Voltage Reference Levels for AC
Measurements (Except Output Enable/Disable)
tDIS_MEASURED
t DIS
Output Enable Time Measurement
Output pins are considered to be enabled when they have made
a transition from a high impedance state to the point when they
start driving.
The output enable time tENA is the interval from the point when
a reference signal reaches a high or low voltage level to the point
when the output starts driving as shown on the right side of Figure 41, “Output Enable/Disable,” on Page 52.
The time tENA_MEASURED is the interval, from when the reference
signal switches, to when the output voltage reaches VTRIP(high)
or VTRIP(low). VTRIP(high) is 2.0 V and VTRIP(low) is 1.0 V for
VDDEXT (nominal) = 3.3 V. Time tTRIP is the interval from when
the output starts driving to when the output reaches the
VTRIP(high) or VTRIP(low) trip voltage.
t ENA_MEASURED
tENA
VOH
(MEASURED)
VOL
(MEASURED)
VOH(MEASURED)
VTRIP(HIGH)
VOH (MEASURED) 2 DV
VTRIP(LOW)
VOL(MEASURED)
VOL (MEASURED) + DV
tDECAY
t TRIP
OUTPUT STOPS DRIVING
OUTPUT STARTS DRIVING
HIGH IMPEDANCE STATE
Figure 41. Output Enable/Disable
50⍀
TO
OUTPUT
PIN
Time tENA is calculated as shown in the equation:
VLOAD
30pF
t ENA = t ENA_MEASURED – t TRIP
If multiple pins (such as the data bus) are enabled, the measurement value is that of the first pin to start driving.
Figure 42. Equivalent Device Loading for AC Measurements
(Includes All Fixtures)
Output Disable Time Measurement
Output pins are considered to be disabled when they stop driving, go into a high impedance state, and start to decay from their
output high or low voltage. The output disable time tDIS is the
difference between tDIS_MEASURED and tDECAY as shown on the left
side of Figure 41.
t DIS = t DIS_MEASURED – t DECAY
The time for the voltage on the bus to decay by ΔV is dependent
on the capacitive load CL and the load current IL. This decay
time can be approximated by the equation:
Rev. A |
Page 52 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
Capacitive Loading
RISE AND FALL TIME ns (10% to 90%)
14
12
12
RISE AND FALL TIME ns (10% to 90%)
Output delays and holds are based on standard capacitive loads:
30 pF on all pins (see Figure 42). VLOAD is 1.5 V for VDDEXT
(nominal) = 3.3 V. Figure 43 on Page 53 through Figure 52 on
Page 54 show how output rise and fall times vary with capacitance. The delay and hold specifications given should be derated by a factor derived from these figures. The graphs in these
figures may not be linear outside the ranges shown.
RISE TIME
8
FALL TIME
6
4
2
RISE TIME
10
0
FALL TIME
8
0
50
100
150
LOAD CAPACITANCE (pF)
200
250
Figure 45. Typical Rise and Fall Times (10% to 90%) vs. Load Capacitance for
Driver B at VDDEXT = 2.7 V (MIN)
6
4
10
0
0
50
100
150
LOAD CAPACITANCE (pF)
200
250
Figure 43. Typical Rise and Fall Times (10% to 90%) vs. Load Capacitance for
Driver A at VDDEXT = 2.7 V (MIN)
12
RISE AND FALL TIME ns (10% to 90%)
2
RISE AND FALL TIME ns (10% to 90%)
10
10
9
8
RISE TIME
7
6
FALL TIME
5
4
3
2
1
RISE TIME
0
8
0
50
FALL TIME
100
150
LOAD CAPACITANCE (pF)
200
250
6
Figure 46. Typical Rise and Fall Times (10% to 90%) vs. Load Capacitance for
Driver B at VDDEXT = 3.65 V (MAX)
4
2
0
50
100
150
LOAD CAPACITANCE (pF)
200
250
Figure 44. Typical Rise and Fall Times (10% to 90%) vs. Load Capacitance for
Driver A at VDDEXT = 3.65 V (MAX)
RISE AND FALL TIME ns (10% to 90%)
0
30
25
RISE TIME
20
15
FALL TIME
10
5
0
0
50
100
150
LOAD CAPACITANCE (pF)
200
250
Figure 47. Typical Rise and Fall Times (10% to 90%) vs. Load Capacitance for
Driver C at VDDEXT = 2.7 V (MIN)
Rev. A |
Page 53 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
132
18
16
RISE TIME
128
14
FALL TIME ns (10% to 90%)
RISE AND FALL TIME ns (10% to 90%)
20
12
FALL TIME
10
8
6
4
2
124
FALL TIME
120
116
112
0
0
50
100
150
LOAD CAPACITANCE (pF)
200
250
108
0
50
Figure 48. Typical Rise and Fall Times (10% to 90%) vs. Load Capacitance for
Driver C at VDDEXT = 3.65 V (MAX)
100
150
LOAD CAPACITANCE (pF)
200
250
Figure 51. Typical Fall Time (10% to 90%) vs. Load Capacitance for Driver E
at VDDEXT = 2.7 V (MIN)
16
124
14
RISE TIME
12
120
10
FALL TIME ns (10% to 90%)
RISE AND FALL TIME ns (10% to 90%)
18
FALL TIME
8
6
4
2
0
0
50
100
150
LOAD CAPACITANCE (pF)
200
250
Figure 49. Typical Rise and Fall Times (10% to 90%) vs. Load Capacitance for
Driver D at VDDEXT = 2.7 V (MIN)
FALL TIME
112
108
104
100
0
12
RISE TIME
10
8
FALL TIME
6
4
2
0
50
100
150
LOAD CAPACITANCE (pF)
200
250
Figure 52. Typical Fall Time (10% to 90%) vs. Load Capacitance for Driver E
at VDDEXT = 3.65 V (MAX)
14
RISE AND FALL TIME ns (10% to 90%)
116
0
50
100
150
LOAD CAPACITANCE (pF)
200
250
Figure 50. Typical Rise and Fall Times (10% to 90%) vs. Load Capacitance for
Driver D at VDDEXT = 3.65 V (MAX)
Rev. A |
Page 54 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
THERMAL CHARACTERISTICS
To determine the junction temperature on the application
printed circuit board use
T J = T CASE + ( Ψ JT × P D )
where
TJ = Junction temperature (ⴗC)
TCASE = Case temperature (ⴗC) measured by customer at top
center of package.
ΨJT = From Table 36 or Table 37
PD = Power dissipation (see Power Dissipation on Page 52 for
the method to calculate PD)
Values of θJA are provided for package comparison and printed
circuit board design considerations. θJA can be used for a first
order approximation of TJ by the equation:
T J = T A + ( θ JA × P D )
where:
TA = Ambient temperature (ⴗC)
Values of θJC are provided for package comparison and printed
circuit board design considerations when an external heatsink is
required.
Values of θJB are provided for package comparison and printed
circuit board design considerations.
In Table 36 and Table 37, airflow measurements comply with
JEDEC standards JESD51-2 and JESD51-6, and the junction-toboard measurement complies with JESD51-8. The junction-tocase measurement complies with MIL-STD-883 (Method
1012.1). All measurements use a 2S2P JEDEC test board.
Table 36. Thermal Characteristics BC-316 Without Flash
Parameter
Condition
Typical
Unit
θJA
0 linear m/s air flow
21.6
ⴗC/W
θJMA
1 linear m/s air flow
18.8
ⴗC/W
θJMA
2 linear m/s air flow
θJC
18.1
ⴗC/W
5.36
ⴗC/W
ΨJT
0 linear m/s air flow
0.13
ⴗC/W
ΨJT
1 linear m/s air flow
0.25
ⴗC/W
ΨJT
2 linear m/s air flow
0.25
ⴗC/W
Table 37. Thermal Characteristics BC-316 With Flash
Parameter
Condition
Typical
Unit
θJA
0 linear m/s air flow
20.9
ⴗC/W
θJMA
1 linear m/s air flow
18.1
ⴗC/W
θJMA
2 linear m/s air flow
θJC
17.4
ⴗC/W
5.01
ⴗC/W
ΨJT
0 linear m/s air flow
0.12
ⴗC/W
ΨJT
1 linear m/s air flow
0.24
ⴗC/W
ΨJT
2 linear m/s air flow
0.24
ⴗC/W
Rev. A |
Page 55 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
316-BALL CSP_BGA BALL ASSIGNMENT
Figure 53 lists the top view of the CSP_BGA ball assignment.
Figure 54 lists the bottom view of the CSP_BGA ball
assignment.
Table 38 on Page 57 lists the CSP_BGA ball assignment by ball
number. Table 39 on Page 58 lists the CSP_BGA ball assignment by signal.
A1 BALL
A1 BALL
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
VDDINT
GND
VDDRTC
Y
NC
20 19 18 17 16 15 14 13 12 11 10 9 8 7 6
GND
VDDRTC
VDDINT
I/O
VROUTx
VDDEXT
Note: H18 and Y14 are NC for ADSP-BF539
and I/O (FCE and FRESET) for ADSP-BF539F
VDDEXT
I/O
5
4
3
2
1
NC
VROUTx
Note: H18 and Y14 are NC for ADSP-BF539
and I/O (FCE and FRESET) for ADSP-BF539F
Figure 53. 316-Ball CSP_BGA Ball Assignment (Top View)
Figure 54. 316-Ball CSP_BGA Ball Assignment (Bottom View)
Rev. A |
Page 56 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
Table 38. 316-Ball CSP_BGA Ball Assignment (Numerically by Ball Number)
Ball No.
A1
A2
A3
A4
A5
A6
A7
A8
A9
A10
A11
A12
A13
A14
A15
A16
A17
A18
A19
A20
B1
B2
B3
B4
B5
B6
B7
B8
B9
B10
B11
B12
B13
B14
B15
B16
B17
B18
B19
B20
C1
C2
C3
C4
C5
C6
Signal
GND
PF10
PF11
PPI_CLK
PPI0
PPI2
PF15
PF13
VDDRTC
RTXO
RTXI
GND
CLKIN
XTAL
MLF
MXO
MXI
MRXON
VROUT1
GND
PF8
GND
PF9
PF3
PPI1
PPI3
PF14
PF12
SCL0
SDA0
CANRX
CANTX
NMI
RESET
MXEVDD
MXEGND
MTXON
GND
GND
VROUT0
PF6
PF7
GND
GND
RX1
TX1
Ball No.
C7
C8
C9
C10
C11
C12
C13
C14
C15
C16
C17
C18
C19
C20
D1
D2
D3
D7
D8
D9
D10
D11
D12
D13
D14
D18
D19
D20
E1
E2
E3
E7
E8
E9
E10
E11
E12
E13
E14
E18
E19
E20
F1
F2
F3
F7
Signal
SPI2SEL1
SPI2SS
MOSI2
MISO2
SCK2
MPIVDD
SPI1SEL1
MISO1
SPI1SS
MOSI1
SCK1
GND
MMCLK
SCKE
PF4
PF5
DT1SEC
GND
GND
GND
GND
GND
GND
GND
GND
GND
MBCLK
SMS
PF1
PF2
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
MTX
ARDY
PF0
MISO0
GND
GND
Ball No.
F8
F9
F10
F11
F12
F13
F14
F18
F19
F20
G1
G2
G3
G7
G8
G9
G10
G11
G12
G13
G14
G18
G19
G20
H1
H2
H3
H7
H8
H9
H10
H11
H12
H13
H14
H18
H19
H20
J1
J2
J3
J7
J8
J9
J10
J11
Signal
GND
GND
GND
GND
GND
GND
GND
DT3PRI
MRX
MFS
SCK0
MOSI0
DT0SEC
GND
GND
GND
GND
GND
GND
GND
GND
BR
CLKOUT
SRAS
DT1PRI
TSCLK1
DR1SEC
GND
GND
GND
GND
GND
GND
GND
GND
FCE
SCAS
SWE
TFS1
DR1PRI
DR0SEC
GND
GND
GND
GND
GND
Rev. A |
Ball No.
J12
J13
J14
J18
J19
J20
K1
K2
K3
K7
K8
K9
K10
K11
K12
K13
K14
K18
K19
K20
L1
L2
L3
L7
L8
L9
L10
L11
L12
L13
L14
L18
L19
L20
M1
M2
M3
M7
M8
M9
M10
M11
M12
M13
M14
M18
Signal
GND
GND
GND
AMS0
AMS2
SA10
RFS1
TMR2
GP
GND
GND
GND
GND
GND
GND
GND
GND
AMS3
AMS1
AOE
RSCLK1
TMR1
GND
GND
GND
GND
GND
GND
GND
GND
GND
TSCLK3
ARE
AWE
DT0PRI
TMR0
GND
VDDEXT
GND
GND
GND
GND
GND
GND
VDDINT
TFS3
Page 57 of 60 |
Ball No.
M19
M20
N1
N2
N3
N7
N8
N9
N10
N11
N12
N13
N14
N18
N19
N20
P1
P2
P3
P7
P8
P9
P10
P11
P12
P13
P14
P18
P19
P20
R1
R2
R3
R7
R8
R9
R10
R11
R12
R13
R14
R18
R19
R20
T1
T2
February 2008
Signal
ABE0
ABE1
TFS0
DR0PRI
GND
VDDEXT
GND
GND
GND
GND
GND
GND
VDDINT
DT3SEC
ADDR1
ADDR2
TSCLK0
RFS0
GND
VDDEXT
GND
GND
GND
GND
GND
GND
VDDINT
DR3SEC
ADDR3
ADDR4
TX0
RSCLK0
GND
VDDEXT
GND
GND
GND
GND
GND
GND
VDDINT
DR3PRI
ADDR5
ADDR6
RX0
EMU
Ball No.
T3
T7
T8
T9
T10
T11
T12
T13
T14
T18
T19
T20
U1
U2
U3
U7
U8
U9
U10
U11
U12
U13
U14
U18
U19
U20
V1
V2
V3
V4
V5
V6
V7
V8
V9
V10
V11
V12
V13
V14
V15
V16
V17
V18
V19
V20
Signal
GND
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDINT
VDDINT
VDDINT
RFS3
ADDR7
ADDR8
TRST
TMS
GND
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDINT
VDDINT
VDDINT
RSCLK3
ADDR9
ADDR10
TDI
GND
GND
BMODE1
BMODE0
GND
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDINT
DR2SEC
BG
BGH
DT2SEC
GND
GND
ADDR11
ADDR12
Ball No.
W1
W2
W3
W4
W5
W6
W7
W8
W9
W10
W11
W12
W13
W14
W15
W16
W17
W18
W19
W20
Y1
Y2
Y3
Y4
Y5
Y6
Y7
Y8
Y9
Y10
Y11
Y12
Y13
Y14
Y15
Y16
Y17
Y18
Y19
Y20
Signal
TCK
GND
DATA15
DATA13
DATA11
DATA9
DATA7
DATA5
DATA3
DATA1
RSCLK2
DR2PRI
DT2PRI
RX2
TX2
ADDR18
ADDR15
ADDR13
GND
ADDR14
GND
TDO
DATA14
DATA12
DATA10
DATA8
DATA6
DATA4
DATA2
DATA0
RFS2
TSCLK2
TFS2
FRESET
SCL1
SDA1
ADDR19
ADDR17
ADDR16
GND
ADSP-BF539/ADSP-BF539F
Table 39. 316-Ball CSP_BGA Ball Assignment (Alphabetically by Signal)
Signal
ABE0
ABE1
ADDR1
ADDR2
ADDR3
ADDR4
ADDR5
ADDR6
ADDR7
ADDR8
ADDR9
ADDR10
ADDR11
ADDR12
ADDR13
ADDR14
ADDR15
ADDR16
ADDR17
ADDR18
ADDR19
AMS0
AMS1
AMS2
AMS3
AOE
ARDY
ARE
AWE
BG
BGH
BMODE0
BMODE1
BR
CANRX
CANTX
CLKIN
CLKOUT
DATA0
DATA1
DATA2
DATA3
DATA4
DATA5
DATA6
DATA7
Ball No.
M19
M20
N19
N20
P19
P20
R19
R20
T19
T20
U19
U20
V19
V20
W18
W20
W17
Y19
Y18
W16
Y17
J18
K19
J19
K18
K20
E20
L19
L20
V14
V15
V5
V4
G18
B11
B12
A13
G19
Y10
W10
Y9
W9
Y8
W8
Y7
W7
Signal
DATA8
DATA9
DATA10
DATA11
DATA12
DATA13
DATA14
DATA15
DR0PRI
DR0SEC
DR1PRI
DR1SEC
DR2PRI
DR2SEC
DR3PRI
DR3SEC
DT0PRI
DT0SEC
DT1PRI
DT1SEC
DT2PRI
DT2SEC
DT3PRI
DT3SEC
EMU
FCE
FRESET
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
Ball No.
Y6
W6
Y5
W5
Y4
W4
Y3
W3
N2
J3
J2
H3
W12
V13
R18
P18
M1
G3
H1
D3
W13
V16
F18
N18
T2
H18
Y14
A1
A12
A20
B2
B18
B19
C3
C4
C18
D7
D8
D9
D10
D11
D12
D13
D14
D18
E3
Signal
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
Ball No.
E7
E8
E9
F8
F9
F10
F11
F12
F13
F14
G7
G8
G9
E10
E11
E12
E13
E14
E18
F3
F7
G10
G11
G12
G13
G14
H7
H8
H9
H10
H11
H12
H13
H14
J7
J8
J9
J10
J11
J12
J13
J14
K7
K8
K9
K10
Rev. A |
Signal
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
Ball No.
K11
K12
K13
L13
L14
M3
M8
M9
M10
M11
M12
M13
N3
K14
L3
L7
L8
L9
L10
L11
L12
N8
N9
N10
N11
N12
N13
P3
P8
P9
P10
P11
P12
P13
R3
R8
R9
R10
R11
R12
R13
T3
U3
V2
V3
V6
Page 58 of 60 |
Signal
GND
GND
GND
GND
GND
GND
GP
MBCLK
MFS
MISO0
MISO1
MISO2
MLF
MMCLK
MOSI0
MOSI1
MOSI2
MPIVDD
MRXON
MRX
MTX
MTXON
MXEGND
MXEVDD
MXI
MXO
NMI
PF0
PF1
PF2
PF3
PF4
PF5
PF6
PF7
PF8
PF9
PF10
PF11
PF12
PF13
PF14
PF15
PPI_CLK
PPI0
PPI1
February 2008
Ball No.
V17
V18
W2
W19
Y1
Y20
K3
D19
F20
F2
C14
C10
A15
C19
G2
C16
C9
C12
A18
F19
E19
B17
B16
B15
A17
A16
B13
F1
E1
E2
B4
D1
D2
C1
C2
B1
B3
A2
A3
B8
A8
B7
A7
A4
A5
B5
Signal Ball No.
PPI2
A6
PPI3
B6
B14
RESET
RFS0
P2
RFS1
K1
RFS2
Y11
RFS3
T18
RSCLK0 R2
RSCLK1 L1
RSCLK2 W11
RSCLK3 U18
RTXI
A11
RTXO
A10
RX0
T1
RX1
C5
RX2
W14
SA10
J20
H19
SCAS
SCK0
G1
SCK1
C17
SCK2
C11
SCKE
C20
SCL0
B9
SCL1
Y15
SDA0
B10
SDA1
Y16
SMS
D20
SPI1SEL1 C13
SPI1SS C15
SPI2SEL1 C7
SPI2SS C8
G20
SRAS
H20
SWE
TCK
W1
TDI
V1
TDO
Y2
TFS0
N1
TFS1
J1
TFS2
Y13
TFS3
M18
TMR0
M2
TMR1
L2
TMR2
K2
TMS
U2
U1
TRST
TSCLK0 P1
Signal
TSCLK1
TSCLK2
TSCLK3
TX0
TX1
TX2
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDEXT
VDDINT
VDDINT
VDDINT
VDDINT
VDDINT
VDDINT
VDDINT
VDDINT
VDDINT
VDDINT
VDDINT
VDDRTC
VROUT0
VROUT1
XTAL
Ball No.
H2
Y12
L18
R1
C6
W15
T8
T9
T10
T11
U7
U8
U9
U10
U11
V7
M7
N7
P7
R7
T7
V8
V9
V10
V11
M14
N14
P14
R14
T12
T13
T14
U12
U13
U14
V12
A9
B20
A19
A14
ADSP-BF539/ADSP-BF539F
OUTLINE DIMENSIONS
Dimensions in the outline dimensions figures are shown in
millimeters.
15.20 BSC SQ
17.00 BSC SQ
A1 BALL
0.80 BSC BALL PITCH
A1 BALL INDICATOR
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1
BOTTOM VIEW
TOP VIEW
0.30 MIN
0.12 MAX
COPLANARITY
1.70
MAX
SIDE VIEW
0.50
BALL DIAMETER 0.45
0.40
DETAIL A
SEATING PLANE
DETAIL A
NOTES:
1. ALL DIMENSIONS ARE IN MILLIMETERS.
2. COMPLIANT TO JEDEC REGISTERED OUTLINE MO-205, VARIATION AM,
WITH THE EXCEPTION OF BALL DIAMETER.
3. CENTER DIMENSIONS ARE NOMINAL.
Figure 55. 316-Ball Chip Scale Package Ball Grid Array [CSP_BGA](BC-316)
Rev. A |
Page 59 of 60 |
February 2008
ADSP-BF539/ADSP-BF539F
SURFACE-MOUNT DESIGN
Table 40 is provided as an aid to PCB design. For industrystandard design recommendations, refer to IPC-7351,
Generic Requirements for Surface Mount Design and Land Pattern Standard.
Table 40. BGA Data for Use with Surface-Mount Design
Package
Ball Attach Type
316-Ball Chip Scale Package Ball Grid Array [CSP_BGA](BC-316) Solder Mask Defined
Solder Mask Opening
0.40 mm diameter
Ball Pad Size
0.50 mm diameter
ORDERING GUIDE
Package Instruction
Option Rate (Max)
Operating Voltage
(Nominal)
316-Ball Chip Scale Package
Ball Grid Array [CSP_BGA]
BC-316
533 MHz
1.25 V internal/ 3.3 V I/O
–40C to +85C
316-Ball Chip Scale Package
Ball Grid Array [CSP_BGA]
BC-316
533 MHz
1.25 V internal/ 3.3 V I/O
–40C to +85C
316-Ball Chip Scale Package
Ball Grid Array [CSP_BGA]
BC-316
533 MHz
1.25 V internal/ 3.3 V I/O
Model1
Temperature
Range2
ADSP-BF539BBCZ-5A3
–40C to +85C
ADSP-BF539BBCZ-5F43
ADSP-BF539BBCZ-5F83
Package Description
1
A similar part is available for use in specific automotive applications. Contact your local ADI sales office for the ADBF539W Automotive Data Sheet which highlights any
specification changes and ordering information.
2
Referenced temperature is ambient temperature.
3
Z = RoHS compliant part.
©2008 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D06699-0-2/08(A)
Rev. A |
Page 60 of 60 |
February 2008