AD ADSP-21369BBPZ-2A

a
SHARC® Processors
ADSP-21367/ADSP-21368/ADSP-21369
SUMMARY
Code compatible with all other members of the SHARC family
The ADSP-21367/ADSP-21368/ADSP-21369 are available
with a 333 MHz core instruction rate with unique audiocentric peripherals such as the digital audio interface, S/PDIF
transceiver, serial ports, 8-channel asynchronous sample
rate converter, precision clock generators, and more. For
complete ordering information, see Ordering Guide on
Page 56.
High performance 32-bit/40-bit floating point processor
optimized for high performance audio processing
Single-instruction, multiple-data (SIMD) computational
architecture
On-chip memory—2M bit of on-chip SRAM and 6M bit of onchip mask programmable ROM
JTAG TEST & EMULATION
CORE PROCESSOR
4 BLOCK OF
ON-CHIP MEMORY
INSTRUCTION
CACHE
32 × 48-BIT
TIMER
FLAGS4-15
2M BIT RAM
6M BIT ROM
PWM
DAG2
8 × 4 × 32
ADDR
PROGRAM
SEQUENCER
DATA
EXTERNAL PORT
32
PM DATA BUS
64
IOP REGISTER (MEMORY MAPPED)
CONTROL, STATUS, & DATA BUFFERS
SPDIF (Rx/Tx)
SERIAL PORTS (8)
SPI PORT (2)
INPUT DATA PORT/
PDAP
TWO WIRE
INTERFACE
DAI PINS
CONTROL
24
DMA
CONTROLLER
DPI PINS
DPI ROUTING UNIT
S
SRC (8 CHANNELS)
18
ADDRESS
IOD(32)
34 CHANNELS
PRECISION CLOCK
GENERATORS (4)
GPIO FLAGS/
IRQ/TIMEXP
IOA(24)
PX REGISTER
DAI ROUTING UNIT
4
PROCESSING
ELEMENT
(PEY)
8
SHARED MEMORY
INTERFACE
DM DATA BUS 64
PROCESSING
ELEMENT
(PEX)
3
ASYNCHRONOUS
MEMORY INTERFACE
32
DM ADDRESS BUS
DATA
7
SDRAM
CONTROLLER
PM ADDRESS BUS
32
CONTROL PINS
DAG1
8 × 4 × 32
MEMORY-TOMEMORY DMA (2)
UART (2)
TIMERS (3)
DIGITAL PERIPHERAL INTERFACE
DIGITAL AUDIO INTERFACE
I/O PROCESSOR
20
14
Figure 1. Functional Block Diagram
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Rev. A
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©2006 Analog Devices, Inc. All rights reserved.
ADSP-21367/ADSP-21368/ADSP-21369
KEY FEATURES—PROCESSOR CORE
At 333 MHz (3 ns) core instruction rate, the processors perform 2 GFLOPS/666 MMACS
2M bit on-chip, SRAM (0.75M bit in blocks 0 and 1, and
0.25M bit in blocks 2 and 3) for simultaneous access by the
core processor and DMA
6M bit on-chip, mask-programmable ROM (3M bit in block 0
and 3M bit in block 1)
Dual data address generators (DAGs) with modulo and bitreverse addressing
Zero-overhead looping with single-cycle loop setup, providing efficient program sequencing
Single-instruction, multiple-data (SIMD) architecture
provides:
Two computational processing elements
Concurrent execution
Code compatibility with other SHARC family members at
the assembly level
Parallelism in buses and computational units allows: single
cycle executions (with or without SIMD) of a multiply
operation, an ALU operation, a dual memory read or
write, and an instruction fetch
Transfers between memory and core at a sustained
6.4G bytes/s bandwidth at 333 MHz core instruction rate
INPUT/OUTPUT FEATURES
Digital audio interface (DAI) includes eight serial ports, four
precision clock generators, an input data port, an S/PDIF
transceiver, an 8-channel asynchronous sample rate converter, and a signal routing unit
Digital peripheral interface (DPI) includes three timers, two
UARTs, two SPI ports, and a two wire interface port
Outputs of PCG's C and D can be driven on to DPI pins
Eight dual data line serial ports that operate at up to
50M bits/s on each data line—each has a clock, frame sync,
and two data lines that can be configured as either a
receiver or transmitter pair
TDM support for telecommunications interfaces including
128 TDM channel support for newer telephony interfaces
such as H.100/H.110
Up to 16 TDM stream support, each with 128 channels per
frame
Companding selection on a per channel basis in TDM mode
Input data port, configurable as eight channels of serial data
or seven channels of serial data and up to a 20-bit wide
parallel data channel
Signal routing unit provides configurable and flexible connections between all DAI/DPI components
2 muxed flag/IRQ lines
1 muxed flag/timer expired line /MS pin
1 muxed flag/IRQ /MS pin
DEDICATED AUDIO COMPONENTS
DMA controller supports:
34 zero-overhead DMA channels for transfers between
internal memory and a variety of peripherals
32-bit DMA transfers at peripheral clock speed, in parallel
with full-speed processor execution
32-bit wide external port provides glueless connection to
both synchronous (SDRAM) and asynchronous memory
devices
Programmable wait state options: 2 SCLK to 31 SCLK cycles
Delay-line DMA engine maintains circular buffers in external memory with tap/offset-based reads
SDRAM accesses at 133 MHz and asynchronous accesses at
66 MHz
Shared-memory support allows multiple DSPs to automatically arbitrate for the bus and gluelessly access a
common memory device
Shared memory interface (ADSP-21368 only) support
provides:
Glueless connection for scalable DSP multiprocessing
architecture
Distributed on-chip bus arbitration for parallel bus
Connect of up to four ADSP-21368 processors and global
memory
Four memory select lines allow multiple external memory
devices
Rev. A |
S/PDIF-compatible digital audio receiver/transmitter supports EIAJ CP-340 (CP-1201), IEC-958, AES/EBU standards
Left-justified, I2S, or right-justified serial data input with
16-, 18-, 20- or 24-bit word widths (transmitter)
Four independent asynchronous sample rate converters
(SRC). Each converter has separate serial input and output
ports, a de-emphasis filter providing up to –140 dB SNR
performance, stereo sample rate converter (SRC) and supports left-justified, I2S, TDM, and right-justified modes and
24, 20, 18, and 16 audio data word lengths
Pulse-width modulation provides:
16 PWM outputs configured as four groups of four outputs
supports center-aligned or edge-aligned PWM waveforms
ROM-based security features include:
JTAG access to memory permitted with a 64-bit key
Protected memory regions that can be assigned to limit
access under program control to sensitive code
PLL has a wide variety of software and hardware multiplier/divider ratios
Dual voltage: 3.3 V I/O, 1.2 V or 1.3 V core
Available in 256-ball SBGA and 208-lead MQFP packages (see
Ordering Guide on Page 56)
Page 2 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
TABLE OF CONTENTS
Summary ................................................................1
Key Features—Processor Core ..................................2
Input/Output Features ............................................2
Dedicated Audio Components ..................................2
General Description ..................................................4
Core Architecture ..................................................4
Memory Architecture .............................................5
External Memory ...................................................5
Input/Output Features ............................................7
System Design .......................................................9
Development Tools .............................................. 10
Additional Information ......................................... 11
Pin Function Descriptions ........................................ 12
Data Modes ........................................................ 15
Boot Modes ........................................................ 15
Core Instruction Rate to CLKIN Ratio Modes ............. 15
Specifications ......................................................... 16
Operating Conditions ........................................... 16
Electrical Characteristics ........................................ 17
Package Information ............................................ 18
Maximum Power Dissipation ................................. 18
Absolute Maximum Ratings ................................... 18
ESD Sensitivity .................................................... 18
Timing Specifications ........................................... 19
Output Drive Currents .......................................... 47
Test Conditions ................................................... 47
Capacitive Loading ............................................... 47
Thermal Characteristics ........................................ 48
256-Ball SBGA Pinout .............................................. 49
208-Lead MQFP Pinout ............................................ 52
Package Dimensions ................................................ 54
Surface-Mount Design .......................................... 55
Ordering Guide ...................................................... 56
Rev. A |
Page 3 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
GENERAL DESCRIPTION
The ADSP-21367/ADSP-21368/ADSP-21369 SHARC processors are members of the SIMD SHARC family of DSPs that
feature Analog Devices’ Super Harvard Architecture. These processors are source code-compatible with the ADSP-2126x and
ADSP-2116x DSPs as well as with first generation ADSP-2106x
SHARC processors in SISD (single-instruction, single-data)
mode. The processors are 32-bit/40-bit floating point processors
optimized for high performance automotive audio applications
with its large on-chip SRAM, and mask-programmable ROM,
multiple internal buses to eliminate I/O bottlenecks, and an
innovative digital audio interface (DAI).
As shown in the functional block diagram on Page 1, the
processors use two computational units to deliver a significant
performance increase over the previous SHARC processors on a
range of DSP algorithms. Fabricated in a state-of-the-art, high
speed, CMOS process, the ADSP-21367/ADSP-21368/
ADSP-21369 processors achieve an instruction cycle time of up
to 3.0 ns at 333 MHz. With its SIMD computational hardware,
the processors can perform two GFLOPS running at 333 MHz.
Table 1 shows performance benchmarks for these devices.
Table 1. Processor Benchmarks (at 333 MHz)
Benchmark Algorithm
1024 Point Complex FFT (Radix 4, with reversal)
FIR Filter (per tap)1
IIR Filter (per biquad)1
Matrix Multiply (pipelined)
[3×3] × [3×1]
[4×4] × [4×1]
Divide (y/×)
Inverse Square Root
1
Speed
(at 333 MHz)
27.9 μs
1.5 ns
6.0 ns
13.5 ns
23.9 ns
10.5 ns
16.3 ns
Assumes two files in multichannel SIMD mode.
The ADSP-21367/ADSP-21368/ADSP-21369 continues
SHARC’s industry-leading standards of integration for DSPs,
combining a high performance 32-bit DSP core with integrated,
on-chip system features.
• On-chip mask-programmable ROM (6M bit)
• JTAG test access port
The block diagram of the ADSP-21368 on Page 1 also illustrates
the following architectural features:
• DMA controller
• Eight full-duplex serial ports
• Digital audio interface that includes four precision clock
generators (PCG), an input data port (IDP), an S/PDIF
receiver/transmitter, eight channels asynchronous sample
rate converters, eight serial ports, eight serial interfaces, a
16-bit parallel input port (PDAP), a flexible signal routing
unit (DAI SRU).
• Digital peripheral interface that includes three timers, an
I2C® interface, two UARTs, two serial peripheral interfaces
(SPI), and a flexible signal routing unit (DPI SRU).
CORE ARCHITECTURE
The ADSP-21367/ADSP-21368/ADSP-21369 are code compatible at the assembly level with the ADSP-2126x, ADSP-21160,
and ADSP-21161, and with the first generation ADSP-2106x
SHARC processors. The ADSP-21367/ADSP-21368/
ADSP-21369 share architectural features with the ADSP-2126x
and ADSP-2116x SIMD SHARC processors, as detailed in the
following sections.
SIMD Computational Engine
The processors contain two computational processing elements
that operate as a single-instruction, multiple-data (SIMD)
engine. The processing elements are referred to as PEX and PEY
and each contains an ALU, multiplier, shifter, and register file.
PEX is always active, and PEY may be enabled by setting the
PEYEN mode bit in the MODE1 register. When this mode is
enabled, the same instruction is executed in both processing elements, but each processing element operates on different data.
This architecture is efficient at executing math intensive DSP
algorithms.
• Data address generators (DAG1, DAG2)
Entering SIMD mode also has an effect on the way data is transferred between memory and the processing elements. When in
SIMD mode, twice the data bandwidth is required to sustain
computational operation in the processing elements. Because of
this requirement, entering SIMD mode also doubles the bandwidth between memory and the processing elements. When
using the DAGs to transfer data in SIMD mode, two data values
are transferred with each access of memory or the register file.
• Program sequencer with instruction cache
Independent, Parallel Computation Units
• PM and DM buses capable of supporting four 32-bit data
transfers between memory and the core at every core processor cycle
Within each processing element is a set of computational units.
The computational units consist of an arithmetic/logic unit
(ALU), multiplier, and shifter. These units perform all operations in a single cycle. The three units within each processing
element are arranged in parallel, maximizing computational
throughput. Single multifunction instructions execute parallel
ALU and multiplier operations. In SIMD mode, the parallel
The block diagram of the ADSP-21368 on Page 1, illustrates the
following architectural features:
• Two processing elements, each of which comprises an
ALU, multiplier, shifter, and data register file
• Three programmable interval timers with PWM generation, PWM capture/pulse width measurement, and
external event counter capabilities
• On-chip SRAM (2M bit)
Rev. A |
Page 4 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
MEMORY ARCHITECTURE
ALU and multiplier operations occur in both processing elements. These computation units support IEEE 32-bit singleprecision floating-point, 40-bit extended precision floatingpoint, and 32-bit fixed-point data formats.
The ADSP-21367/ADSP-21368/ADSP-21369 processors add
the following architectural features to the SIMD SHARC
family core.
Data Register File
On-Chip Memory
A general-purpose data register file is contained in each processing element. The register files transfer data between the
computation units and the data buses, and store intermediate
results. These 10-port, 32-register (16 primary, 16 secondary)
register files, combined with the ADSP-2136x enhanced Harvard architecture, allow unconstrained data flow between
computation units and internal memory. The registers in PEX
are referred to as R0–R15 and in PEY as S0–S15.
Single-Cycle Fetch of Instruction and Four Operands
The ADSP-21367/ADSP-21368/ADSP-21369 feature an
enhanced Harvard architecture in which the data memory
(DM) bus transfers data and the program memory (PM) bus
transfers both instructions and data (see Figure 1 on Page 1).
With separate program and data memory buses and on-chip
instruction cache, the processors can simultaneously fetch four
operands (two over each data bus) and one instruction (from
the cache), all in a single cycle.
Instruction Cache
The processors include an on-chip instruction cache that
enables three-bus operation for fetching an instruction and four
data values. The cache is selective—only the instructions whose
fetches conflict with PM bus data accesses are cached. This
cache allows full-speed execution of core, looped operations
such as digital filter multiply-accumulates, and FFT butterfly
processing.
Data Address Generators with Zero-Overhead Hardware
Circular Buffer Support
The ADSP-21367/ADSP-21368/ADSP-21369 have two data
address generators (DAGs). The DAGs are used for indirect
addressing and implementing circular data buffers in hardware.
Circular buffers allow efficient programming of delay lines and
other data structures required in digital signal processing, and
are commonly used in digital filters and Fourier transforms.
The two DAGs contain sufficient registers to allow the creation
of up to 32 circular buffers (16 primary register sets, 16 secondary). The DAGs automatically handle address pointer
wraparound, reduce overhead, increase performance, and simplify implementation. Circular buffers can start and end at any
memory location.
Flexible Instruction Set
The 48-bit instruction word accommodates a variety of parallel
operations, for concise programming. For example, the
ADSP-21367/ADSP-21368/ADSP-21369 can conditionally execute a multiply, an add, and a subtract in both processing
elements while branching and fetching up to four 32-bit values
from memory—all in a single instruction.
Rev. A |
The processors contain two megabits of internal RAM and six
megabits of internal mask-programmable ROM. Each block can
be configured for different combinations of code and data storage (see Table 2 on Page 6). Each memory block supports
single-cycle, independent accesses by the core processor and I/O
processor. The memory architecture, in combination with its
separate on-chip buses, allow two data transfers from the core
and one from the I/O processor, in a single cycle.
The SRAM can be configured as a maximum of 64K words of
32-bit data, 128K words of 16-bit data, 42K words of 48-bit
instructions (or 40-bit data), or combinations of different word
sizes up to two megabits. All of the memory can be accessed as
16-bit, 32-bit, 48-bit, or 64-bit words. A 16-bit floating-point
storage format is supported that effectively doubles the amount
of data that may be stored on-chip. Conversion between the
32-bit floating-point and 16-bit floating-point formats is performed in a single instruction. While each memory block can
store combinations of code and data, accesses are most efficient
when one block stores data using the DM bus for transfers, and
the other block stores instructions and data using the PM bus
for transfers.
Using the DM bus and PM buses, with one bus dedicated to
each memory block, assures single-cycle execution with two
data transfers. In this case, the instruction must be available in
the cache.
EXTERNAL MEMORY
The external port provides a high performance, glueless interface to a wide variety of industry-standard memory devices. The
32-bit wide bus may be used to interface to synchronous and/or
asynchronous memory devices through the use of its separate
internal memory controllers. The first is an SDRAM controller
for connection of industry-standard synchronous DRAM
devices and DIMMs (Dual Inline Memory Module), while the
second is an asynchronous memory controller intended to
interface to a variety of memory devices. Four memory select
pins enable up to four separate devices to coexist, supporting
any desired combination of synchronous and asynchronous
device types. NonSDRAM external memory address space is
shown in Table 3.
SDRAM Controller
The SDRAM controller provides an interface of up to four separate banks of industry-standard SDRAM devices or DIMMs, at
speeds up to fSCLK. Fully compliant with the SDRAM standard,
each bank has its own memory select line (MS0–MS3), and can
be configured to contain between 16M bytes and 128M bytes of
memory. SDRAM external memory address space is shown in
Table 4.
Page 5 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
Table 2. Internal Memory Space 1
IOP Registers 0x0000 0000–0x0003 FFFF
1
Long Word (64 Bits)
Extended Precision Normal or
Instruction Word (48 Bits)
Normal Word (32 Bits)
Short Word (16 Bits)
BLOCK 0 ROM (Reserved)
0x0004 0000–0x0004 BFFF
BLOCK 0 ROM (Reserved)
0x0008 0000–0x0008 FFFF
BLOCK 0 ROM (Reserved)
0x0008 0000–0x0009 7FFF
BLOCK 0 ROM (Reserved)
0x0010 0000–0x0012 FFFF
Reserved
0x0004 F000–0x0004 FFFF
Reserved
0x0009 4000–0x0009 FFFF
Reserved
0x0009 E000–0x0009 FFFF
Reserved
0x0013 C000–0x0013 FFFF
BLOCK 0 SRAM
0x0004 C000–0x0004 EFFF
BLOCK 0 SRAM
0x0009 0000–0x0009 3FFF
BLOCK 0 SRAM
0x0009 8000–0x0009 DFFF
BLOCK 0 SRAM
0x0013 0000–0x0013 BFFF
BLOCK 1 ROM (Reserved)
0x0005 0000–0x0005 BFFF
BLOCK 1 ROM (Reserved)
0x000A 0000–0x000A FFFF
BLOCK 1 ROM (Reserved)
0x000A 0000–0x000B 7FFF
BLOCK 1 ROM (Reserved)
0x0014 0000–0x0016 FFFF
Reserved
0x0005 F000–0x0005 FFFF
Reserved
0x000B 4000–0x000B FFFF
Reserved
0x000B E000–0x000B FFFF
Reserved
0x0017 C000–0x0017 FFFF
BLOCK 1 SRAM
0x0005 C000–0x0005 EFFF
BLOCK 1 SRAM
0x000B 0000–0x000B 3FFF
BLOCK 1 SRAM
0x000B 8000–0x000B DFFF
BLOCK 1 SRAM
0x0017 0000–0x0017 BFFF
BLOCK 2 SRAM
0x0006 0000–0x0006 0FFF
BLOCK 2 SRAM
0x000C 0000–0x000C 1554
BLOCK 2 SRAM
0x000C 0000–0x000C 1FFF
BLOCK 2 SRAM
0x0018 0000–0x0018 3FFF
Reserved
0x0006 1000– 0x0006 FFFF
Reserved
0x000C 1555–0x000C 3FFF
Reserved
0x000C 2000–0x000D FFFF
Reserved
0x0018 4000–0x001B FFFF
BLOCK 3 SRAM
0x0007 0000–0x0007 0FFF
BLOCK 3 SRAM
0x000E 0000–0x000E 1554
BLOCK 3 SRAM
0x000E 0000–0x000E 1FFF
BLOCK 3 SRAM
0x001C 0000–0x001C 3FFF
Reserved
0x0007 1000–0x0007 FFFF
Reserved
0x000E 1555–0x000F FFFF
Reserved
0x000E 2000–0x000F FFFF
Reserved
0x001C 4000–0x001F FFFF
The ADSP-21368 and ADSP-21369 processors include a customer-definable ROM block. Please contact your Analog Devices sales representative for additional details.
The controller maintains all of the memory banks as a contiguous address space so that the processor sees this as a single
address space, even if different size devices are used in the
different banks.
Table 4. External Memory for SDRAM Addresses
A set of programmable timing parameters is available to configure the SDRAM banks to support slower memory devices. The
memory banks can be configured as either 32 bits wide for maximum performance and bandwidth or 16 bits wide for
minimum device count and lower system cost.
The SDRAM controller address, data, clock, and control pins
can drive loads up to 30 pF. For larger memory systems, the
SDRAM controller external buffer timing should be selected
and external buffering should be provided so that the load on
the SDRAM controller pins does not exceed 30 pF.
Table 3. External Memory for NonSDRAM Addresses
Bank
Size in
Words
Address Range
Bank 0
14M
0x0020 0000 – 0x00FF FFFF
Bank 1
16M
0x0400 0000 – 0x04FF FFFF
Bank 2
16M
0x0800 0000 – 0x08FF FFFF
Bank 3
16M
0x0C00 0000 – 0x0CFF FFFF
Rev. A |
Bank
Size in
Words
Address Range
Bank 0
62M
0x0020 0000 – 0x03FF FFFF
Bank 1
64M
0x0400 0000 – 0x07FF FFFF
Bank 2
64M
0x0800 0000 – 0x0BFF FFFF
Bank 3
64M
0x0C00 0000 – 0x0FFF FFFF
Asynchronous Controller
The asynchronous memory controller provides a configurable
interface for up to four separate banks of memory or I/O
devices. Each bank can be independently programmed with different timing parameters, enabling connection to a wide variety
of memory devices including SRAM, ROM, flash, and EPROM,
as well as I/O devices that interface with standard memory control lines. Bank 0 occupies a 14M word window and banks 1, 2,
and 3 occupy a 16M word window in the processor’s address
space but, if not fully populated, these windows are not made
contiguous by the memory controller logic. The banks can also
be configured as 8-bit, 16-bit, or 32-bit wide buses for ease of
interfacing to a range of memories and I/O devices tailored
either to high performance or to low cost and power.
Page 6 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
The asynchronous memory controller is capable of a maximum
throughput of 264M bytes/s using a 66 MHz external bus speed.
Other features include 8-bit to 32-bit and 16-bit to 32-bit packing and unpacking, booting from bank select 1, and support for
delay line DMA.
the SPI interface, two for the external port, and two for
memory-to-memory transfers. Programs can be downloaded to
the processors using DMA transfers. Other DMA features
include interrupt generation upon completion of DMA transfers, and DMA chaining for automatic linked DMA transfers.
Shared External Memory
Delay Line DMA
The ADSP-21368 processor supports connecting to common
shared external memory with other ADSP-21368 processors to
create shared external bus processor systems. This support
includes:
The ADSP-21367/ADSP-21368/ADSP-21369 processors provide delay line DMA functionality. This allows processor reads
and writes to external delay line buffers (in external memory,
SRAM, or SDRAM) with limited core interaction.
• Distributed, on-chip arbitration for the shared external bus
Digital Audio and Digital Peripheral Interfaces (DAI/DPI)
• Fixed and rotating priority bus arbitration
The digital audio and digital periphal interfaces (DAI and DPI)
provide the ability to connect various peripherals to any of the
DSP’s DAI or DPI pins (DAI_P20–1 and DPI_P14–1).
• Bus time-out logic
• Bus lock
Multiple processors can share the external bus with no additional arbitration logic. Arbitration logic is included on-chip to
allow the connection of up to four processors.
Bus arbitration is accomplished through the BR1-4 signals and
the priority scheme for bus arbitration is determined by the setting of the RPBA pin. Table 5 on Page 12 provides descriptions
of the pins used in multiprocessor systems.
INPUT/OUTPUT FEATURES
The I/O processor provides 34 channels of DMA, as well as an
extensive set of peripherals. These include a 20-pin digital audio
interface which controls:
• Eight serial ports
• S/PDIF receiver/transmitter
• Four precision clock generators
• Four stereo sample rate converters
The SRUs are matrix routing units (or group of multiplexers)
that enable the peripherals provided by the DAI and DPI to be
interconnected under software control. This allows easy use of
the associated peripherals for a much wider variety of applications by using a larger set of algorithms than is possible with
nonconfigurable signal paths.
The DAI and DPI also include eight serial ports, an S/PDIF
receiver/transmitter, four precision clock generators (PCG),
eight channels of synchronous sample rate converters, and an
input data port (IDP). The IDP provides an additional input
path to the processor core, configurable as either eight channels
of I2S serial data or as seven channels plus a single 20-bit wide
synchronous parallel data acquisition port. Each data channel
has its own DMA channel that is independent from the processor’s serial ports.
For complete information on using the DAI and DPI, see the
ADSP-21368 SHARC Processor Hardware Reference.
• Internal data port/parallel data acquisition port
The processors also contain a 14-pin digital peripheral interface
which controls:
Serial Ports
The processors feature eight synchronous serial ports (SPORTs)
that provide an inexpensive interface to a wide variety of digital
and mixed-signal peripheral devices such as Analog Devices’
AD183x family of audio codecs, ADCs, and DACs. The serial
ports are made up of two data lines, a clock, and frame sync. The
data lines can be programmed to either transmit or receive and
each data line has a dedicated DMA channel.
• Three general-purpose timers
• Two serial peripheral interfaces
• Two universal asynchronous receiver/transmitters
(UARTs)
• A two-wire interface (I2C-compatible)
DMA Controller
The processor’s on-chip DMA controller allows data transfers
without processor intervention. The DMA controller operates
independently and invisibly to the processor core, allowing
DMA operations to occur while the core is simultaneously executing its program instructions. DMA transfers can occur
between the processor’s internal memory and its serial ports, the
SPI-compatible (serial peripheral interface) ports, the IDP
(input data port), the parallel data acquisition port (PDAP), or
the UART. Thirty-four channels of DMA are available on the
ADSP-21367/ADSP-21368/ADSP-21369—16 via the serial
ports, eight via the input data port, four for the UARTs, two for
Rev. A |
Programs make these connections using the signal routing units
(SRU1 and SRU2), shown in Figure 1.
Serial ports are enabled via 16 programmable and simultaneous
receive or transmit pins that support up to 32 transmit or 32
receive channels of audio data when all eight SPORTS are
enabled, or eight full duplex TDM streams of 128 channels
per frame.
The serial ports operate at a maximum data rate of 50M bits/s.
Serial port data can be automatically transferred to and from
on-chip memory via dedicated DMA channels. Each of the
serial ports can work in conjunction with another serial port to
provide TDM support. One SPORT provides two transmit signals while the other SPORT provides the two receive signals.
The frame sync and clock are shared.
Page 7 of 56 |
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ADSP-21367/ADSP-21368/ADSP-21369
Serial ports operate in five modes:
Digital Peripheral Interface (DPI)
• Standard DSP serial mode
The digital peripheral interface provides connections to two
serial peripheral interface ports (SPI), two universal asynchronous receiver-transmitters (UARTs), a two-wire interface
(TWI), 12 flags, and three general-purpose timers.
2
• Multichannel (TDM) mode with support for packed I S
mode
• I2S mode
• Packed I2S mode
Serial Peripheral (Compatible) Interface
• Left-justified sample pair mode
The processors contain two serial peripheral interface ports
(SPIs). The SPI is an industry-standard synchronous serial link,
enabling the SPI-compatible port to communicate with other
SPI-compatible devices. The SPI consists of two data pins, one
device select pin, and one clock pin. It is a full-duplex synchronous serial interface, supporting both master and slave modes.
The SPI port can operate in a multimaster environment by
interfacing with up to four other SPI-compatible devices, either
acting as a master or slave device. The ADSP-21367/
ADSP-21368/ADSP-21369 SPI-compatible peripheral implementation also features programmable baud rate and clock
phase and polarities. The SPI-compatible port uses open drain
drivers to support a multimaster configuration and to avoid
data contention.
Left-justified sample pair mode is a mode where in each frame
sync cycle two samples of data are transmitted/received—one
sample on the high segment of the frame sync, the other on the
low segment of the frame sync. Programs have control over various attributes of this mode.
Each of the serial ports supports the left-justified sample pair
and I2S protocols (I2S is an industry-standard interface commonly used by audio codecs, ADCs, and DACs such as the
Analog Devices AD183x family), with two data pins, allowing
four left-justified sample pair or I2S channels (using two stereo
devices) per serial port, with a maximum of up to 32 I2S channels. The serial ports permit little-endian or big-endian
transmission formats and word lengths selectable from 3 bits to
32 bits. For the left-justified sample pair and I2S modes, dataword lengths are selectable between 8 bits and 32 bits. Serial
ports offer selectable synchronization and transmit modes as
well as optional μ-law or A-law companding selection on a per
channel basis. Serial port clocks and frame syncs can be internally or externally generated.
The serial ports also contain frame sync error detection logic
where the serial ports detect frame syncs that arrive early (for
example, frame syncs that arrive while the transmission/reception of the previous word is occurring). All the serial ports also
share one dedicated error interrupt.
UART Port
The processors provide a full-duplex universal asynchronous
receiver/transmitter (UART) port, which is fully compatible
with PC-standard UARTs. The UART port provides a simplified UART interface to other peripherals or hosts, supporting
full-duplex, DMA-supported, asynchronous transfers of serial
data. The UART also has multiprocessor communication capability using 9-bit address detection. This allows it to be used in
multidrop networks through the RS-485 data interface standard. The UART port also includes support for five data bits to
eight data bits, one stop bit or two stop bits, and none, even, or
odd parity. The UART port supports two modes of operation:
S/PDIF-Compatible Digital Audio Receiver/Transmitter
and Synchronous/Asynchronous Sample Rate Converter
• 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.
The S/PDIF receiver/transmitter has no separate DMA channels. It receives audio data in serial format and converts it into a
biphase encoded signal. The serial data input to the
receiver/transmitter can be formatted as left-justified, I2S, or
right-justified with word widths of 16, 18, 20, or 24 bits.
The serial data, clock, and frame sync inputs to the S/PDIF
receiver/transmitter are routed through the signal routing unit
(SRU). They can come from a variety of sources such as the
SPORTs, external pins, the precision clock generators (PCGs),
or the sample rate converters (SRC) and are controlled by the
SRU control registers.
The sample rate converter (SRC) contains four SRC blocks and
is the same core as that used in the AD1896 192 kHz stereo
asynchronous sample rate converter and provides up to 128 dB
SNR. The SRC block is used to perform synchronous or asynchronous sample rate conversion across independent stereo
channels, without using internal processor resources. The four
SRC blocks can also be configured to operate together to convert multichannel audio data without phase mismatches.
Finally, the SRC can be used to clean up audio data from jittery
clock sources such as the S/PDIF receiver.
Rev. A |
• 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. The 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.
The 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.
• 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.
Where the 16-bit UART_Divisor comes from the DLH register
(most significant eight bits) and DLL register (least significant
eight bits).
Page 8 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
In conjunction with the general-purpose timer functions, autobaud detection is supported.
Timers
The ADSP-21367/ADSP-21368/ADSP-21369 have a total of
four timers: a core timer that can generate periodic software
interrupts and three general-purpose timers that can generate
periodic interrupts and be independently set to operate in one
of three modes:
• Pulse waveform generation mode
• Pulse width count/capture mode
• External event watchdog mode
midpoint of the PWM period. In this mode, it is possible to produce asymmetrical PWM patterns that produce lower harmonic
distortion in three-phase PWM inverters.
ROM-Based Security
The ADSP-21367/ADSP-21368/ADSP-21369 have a ROM security feature that provides hardware support for securing user
software code by preventing unauthorized reading from the
internal code when enabled. When using this feature, the processor does not boot-load any external code, executing
exclusively from internal SRAM/ROM. Additionally, the processor is not freely accessible via the JTAG port. Instead, a
unique 64-bit key, which must be scanned in through the JTAG
or test access port will be assigned to each customer. The device
will ignore a wrong key. Emulation features and external boot
modes are only available after the correct key is scanned.
The core timer can be configured to use FLAG3 as a timer
expired signal, and each general purpose timer has one bidirectional pin and four registers that implement its mode of
operation: a 6-bit configuration register, a 32-bit count register,
a 32-bit period register, and a 32-bit pulse width register. A single control and status register enables or disables all three
general-purpose timers independently.
The following sections provide an introduction to system design
options and power supply issues.
Two-Wire Interface Port (TWI)
Program Booting
The TWI is a bidirectional 2-wire, serial bus used to move 8-bit
data while maintaining compliance with the I2C bus protocol.
The TWI master incorporates the following features:
The internal memory of the processors can be booted up at system power-up from an 8-bit EPROM via the external port, an
SPI master or slave, or an internal boot. Booting is determined
by the boot configuration (BOOT_CFG1–0) pins (see Table 7
on Page 15). Selection of the boot source is controlled via the
SPI as either a master or slave device, or it can immediately
begin executing from ROM.
• Simultaneous master and slave operation on multiple
device systems with support for multimaster data
arbitration
• Digital filtering and timed event processing
SYSTEM DESIGN
Power Supplies
• 7-bit and 10-bit addressing
• 100K bits/s and 400K bits/s data rates
• Low interrupt rate
Pulse-Width Modulation
The PWM module is a flexible, programmable, PWM waveform
generator that can be programmed to generate the required
switching patterns for various applications related to motor and
engine control or audio power control. The PWM generator can
generate either center-aligned or edge-aligned PWM waveforms. In addition, it can generate complementary signals on
two outputs in paired mode or independent signals in nonpaired mode (applicable to a single group of four PWM
waveforms).
The entire PWM module has four groups of four PWM outputs
each. Therefore, this module generates 16 PWM outputs in
total. Each PWM group produces two pairs of PWM signals on
the four PWM outputs.
The PWM generator is capable of operating in two distinct
modes while generating center-aligned PWM waveforms: single
update mode or double update mode. In single update mode the
duty cycle values are programmable only once per PWM period.
This results in PWM patterns that are symmetrical about the
midpoint of the PWM period. In double update mode, a second
updating of the PWM registers is implemented at the
Rev. A |
The processors have separate power supply connections for the
internal (VDDINT), external (VDDEXT), and analog (AVDD/AVSS)
power supplies. The internal and analog supplies must meet the
1.3 V requirement for the 333 MHz device and 1.2 V for the
266 MHz device. The external supply must meet the 3.3 V
requirement. All external supply pins must be connected to the
same power supply.
Note that the analog supply pin (AVDD) powers the processor’s
internal clock generator PLL. To produce a stable clock, it is recommended that PCB designs use an external filter circuit for the
AVDD pin. Place the filter components as close as possible to the
AVDD/AVSS pins. For an example circuit, see Figure 2. (A recommended ferrite chip is the muRata BLM18AG102SN1D). To
reduce noise coupling, the PCB should use a parallel pair of
power and ground planes for VDDINT and GND. Use wide traces
to connect the bypass capacitors to the analog power (AVDD) and
ground (AVSS) pins. Note that the AVDD and AVSS pins specified in
Figure 2 are inputs to the processor and not the analog ground
plane on the board—the AVSS pin should connect directly to digital ground (GND) at the chip.
Page 9 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
100nF
10nF
1nF
ADSP-213xx
AVDD
VDDINT
HI-Z FERRITE
BEAD CHIP
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:
AVSS
• View mixed C/C++ and assembly code (interleaved source
and object information)
LOCATE ALL COMPONENTS
CLOSE TO AVDD AND AVSS PINS
• Insert breakpoints
• Set conditional breakpoints on registers, memory,
and stacks
Figure 2. Analog Power (AVDD) Filter Circuit
Target Board JTAG Emulator Connector
• Trace instruction execution
Analog Devices DSP Tools product line of JTAG emulators uses
the IEEE 1149.1 JTAG test access port of the ADSP-21367/
ADSP-21368/ADSP-21369 processors to monitor and control
the target board processor during emulation. Analog Devices
DSP Tools product line of JTAG emulators provides emulation
at full processor speed, allowing inspection and modification of
memory, registers, and processor stacks. The processor’s JTAG
interface ensures that the emulator will not affect target system
loading or timing.
• Perform linear or statistical profiling of program execution
For complete information on Analog Devices’ SHARC DSP
Tools product line of JTAG emulator operation, see the appropriate “Emulator Hardware User’s Guide.”
• Fill, dump, and graphically plot the contents of memory
• Perform source level debugging
• Create custom debugger windows
The VisualDSP++ IDDE lets programmers define and manage
DSP software development. Its dialog boxes and property pages
let programmers configure and manage all of the SHARC 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
DEVELOPMENT TOOLS
The processors are supported with 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
SHARC processors also fully emulates the ADSP-21367/ADSP21368/ADSP-21369.
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 DSP assembly. The SHARC 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
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
Rev. A |
• 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.
VisualDSP++ Component Software Engineering (VCSE) is
Analog Devices’ technology for creating, using, and reusing
software components (independent modules of substantial
functionality) to quickly and reliably assemble software
applications. The user can download components from the
Web, drop them into the application, and publish component
archives from within VisualDSP++. VCSE supports component
implementation in C/C++ or assembly language.
Page 10 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
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 a
drag of the mouse and examine runtime stack and heap usage.
The expert linker is fully compatible with the existing linker definition file (LDF), allowing the developer to move between the
graphical and textual environments.
In addition to the software and hardware development tools
available from Analog Devices, third parties provide a wide
range of tools supporting the SHARC processor family. Hardware tools include SHARC processor PC plug-in cards. Thirdparty software tools include DSP libraries, real-time operating
systems, and block diagram design tools.
Designing an Emulator-Compatible DSP Board (Target)
in-circuit programming of the on-board flash device to store
user-specific boot code, enabling the board to run as a standalone unit without being connected to the PC.
With a full version of VisualDSP++ installed (sold separately),
engineers can develop software for the EZ-KIT Lite or any
custom-defined system. Connecting one of Analog Devices
JTAG emulators to the EZ-KIT Lite board enables high speed,
non-intrusive emulation.
ADDITIONAL INFORMATION
This data sheet provides a general overview of the
ADSP-21367/ADSP-21368/ADSP-21369 architecture and functionality. For detailed information on the ADSP-2136x family
core architecture and instruction set, refer to the ADSP-21368
SHARC Processor Hardware Reference and the ADSP2136x/ADSP-2137x SHARC Processor Programming Reference.
The Analog Devices family of emulators are tools that every
DSP 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 DSP. 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. 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 DSP 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 DSP’s JTAG port to the emulator.
For details on target board design issues including mechanical
layout, single processor connections, signal buffering, signal termination, and emulator pod logic, see the EE-68: Analog Devices
JTAG Emulation Technical Reference on the Analog Devices
website (www.analog.com)—use site search on “EE-68.” This
document is updated regularly to keep pace with improvements
to emulator support.
Evaluation Kit
Analog Devices offers a range of EZ-KIT Lite® evaluation platforms to use as a cost effective method to learn more about
developing or prototyping applications with Analog Devices
processors, platforms, and software tools. Each EZ-KIT Lite
includes an evaluation board along with an evaluation suite of
the VisualDSP++ development and debugging environment
with the C/C++ compiler, assembler, and linker. Also included
are sample application programs, power supply, and a USB
cable. All evaluation versions of the software tools are limited
for use only with the EZ-KIT Lite product.
The USB controller on the EZ-KIT Lite board connects the
board to the USB port of the user’s PC, enabling the
VisualDSP++ evaluation suite to emulate the on-board processor in-circuit. This permits the customer to download, execute,
and debug programs for the EZ-KIT Lite system. It also allows
Rev. A |
Page 11 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
PIN FUNCTION DESCRIPTIONS
The following symbols appear in the Type column of Table 5:
A = asynchronous, G = ground, I = input, O = output,
O/T = output three-state, P = power supply, S = synchronous,
(A/D) = active drive, (O/D) = open drain, (pd) = pull-down
resistor, (pu) = pull-up resistor.
Table 5. Pin List
State During/
After Reset
(ID = 00x)
Description
Name
Type
ADDR23–0
O/T (pu)1
Pulled high/
driven low
External Address. The processors output addresses for external memory and peripherals on these pins.
DATA31–0
I/O (pu)1
Pulled high/
pulled high
External Data. Data pins can be multiplexed to support external memory interface
data (I/O), the PDAP (I), FLAGS (I/O), and PWM (O). After reset, all DATA pins are in EMIF
mode and FLAG(0-3) pins are in FLAGS mode (default). When configured using the
IDP_PDAP_CTL register, IDP Channel 0 scans the DATA31–8 pins for parallel input data.
DAI _P20–1
I/O with programmable pu2
Pulled high/
pulled high
Digital Audio Interface. These pins provide the physical interface to the DAI SRU. The
DAI SRU configuration registers define the combination of on-chip audiocentric peripheral inputs or outputs connected to the pin, and to the pin’s output enable. The
configuration registers then determines the exact behavior of the pin. Any input or
output signal present in the DAI SRU may be routed to any of these pins. The DAI SRU
provides the connection from the serial ports (8), the SRC module, the S/PDIF module,
input data ports (2), and the precision clock generators (4), to the DAI_P20–1 pins. Pullups can be disabled via the DAI_PIN_PULLUP register.
DPI _P14–1
I/O with programmable pu2
Pulled high/
pulled high
Digital Peripheral Interface. These pins provide the physical interface to the DPI SRU.
The DPI SRU configuration registers define the combination of on-chip peripheral
inputs or outputs connected to the pin and to the pin’s output enable. The configuration
registers of these peripherals then determines the exact behavior of the pin. Any input
or output signal present in the DPI SRU may be routed to any of these pins. The DPI SRU
provides the connection from the timers (3), SPIs (2), UARTs (2), flags (12) TWI (1), and
general-purpose I/O (9) to the DPI_P14–1 pins. The TWI output is an open-drain
output—so the pins used for I2C data and clock should be connected to logic level 0.
Pull-ups can be disabled via the DPI_PIN_PULLUP register.
ACK
I (pu)1
RD
O/T (pu)1
Pulled high/
driven high
External Port Read Enable. RD is asserted whenever the processors read a word from
external memory.
WR
O/T (pu)1
Pulled high/
driven high
External Port Write Enable. WR is asserted when the processors write a word to
external memory.
SDRAS
O/T (pu)1
Pulled high/
driven high
SDRAM Row Address Strobe. Connect to SDRAM’s RAS pin. In conjunction with other
SDRAM command pins, defines the operation for the SDRAM to perform.
SDCAS
O/T (pu)1
Pulled high/
driven high
SDRAM Column Address Select. Connect to SDRAM’s CAS pin. In conjunction with
other SDRAM command pins, defines the operation for the SDRAM to perform.
SDWE
O/T (pu)1
Pulled high/
driven high
SDRAM Write Enable. Connect to SDRAM’s WE or W buffer pin.
Memory Acknowledge. External devices can deassert ACK (low) to add wait states to
an external memory access. ACK is used by I/O devices, memory controllers, or other
peripherals to hold off completion of an external memory access.
Rev. A |
Page 12 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
Table 5. Pin List
State During/
After Reset
(ID = 00x)
Description
Name
Type
SDCKE
O/T (pu)1
Pulled high/
driven high
SDRAM Clock Enable. Connect to SDRAM’s CKE pin. Enables and disables the CLK
signal. For details, see the data sheet supplied with the SDRAM device.
SDA10
O/T (pu)1
Pulled high/
driven low
SDRAM A10 Pin. Enables applications to refresh an SDRAM in parallel with nonSDRAM accesses. This pin replaces the DSP’s A10 pin only during SDRAM accesses.
SDCLK0
O/T
High-Z/driving
SDRAM Clock Output 0.
SDCLK1
O/T
MS0–1
O/T (pu)1
Pulled high/
driven high
Memory Select Lines 0–1. These lines are asserted (low) as chip selects for the corresponding banks of external memory. The MS3-0 lines are decoded memory address lines
that change at the same time as the other address lines. When no external memory
access is occurring, the MS3-0 lines are inactive; they are active, however, when a conditional memory access instruction is executed, whether or not the condition is true.
The MS1 pin can be used in EPORT/FLASH boot mode. See the hardware reference for
more information.
FLAG[0]/IRQ0
I/O
High-Z/high-Z
FLAG0/Interrupt Request 0.
FLAG[1]/IRQ1
I/O
High-Z/high-Z
FLAG1/Interrupt Request 1.
FLAG[2]/IRQ2/
MS2
I/O with programmable pu
(for MS mode)
High-Z/high-Z
FLAG2/Interrupt Request 2/Memory Select 2.
FLAG[3]/TIMEXP/
MS3
I/O with programmable pu
(for MS mode)
High-Z/high-Z
FLAG3/Timer Expired/Memory Select 3.
TDI
I (pu)
Test Data Input (JTAG). Provides serial data for the boundary scan logic.
TDO
O/T
Test Data Output (JTAG). Serial scan output of the boundary scan path.
TMS
I (pu)
Test Mode Select (JTAG). Used to control the test state machine.
TCK
I
Test Clock (JTAG). Provides a clock for JTAG boundary scan. TCK must be asserted
(pulsed low) after power-up, or held low for proper operation of the processor
TRST
I (pu)
Test Reset (JTAG). Resets the test state machine. TRST must be asserted (pulsed low)
after power-up or held low for proper operation of the processor.
EMU
O/T (pu)
Emulation Status. Must be connected to the ADSP-21367/ADSP-21368/ADSP-21369
Analog Devices DSP Tools product line of JTAG emulator target board connectors only.
CLK_CFG1–0
I
Core/CLKIN Ratio Control. These pins set the start-up clock frequency. See Table 8 for
a description of the clock configuration modes.
Note that the operating frequency can be changed by programming the PLL multiplier
and divider in the PMCTL register at any time after the core comes out of reset.
BOOT_CFG1–0
I
Boot Configuration Select. These pins select the boot mode for the processor. The
BOOT_CFG pins must be valid before reset is asserted. See Table 7 for a description of
the boot modes.
SDRAM Clock Output 1. Additional clock for SDRAM devices. For systems with multiple
SDRAM devices, handles the increased clock load requirements, eliminating need of
off-chip clock buffers. Either SDCLK1 or both SDCLKx pins can be three-stated.
Rev. A |
Page 13 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
Table 5. Pin List
1
2
State During/
After Reset
(ID = 00x)
Name
Type
Description
RESET
I
Processor Reset. Resets the processor to a known state. Upon deassertion, there is a
4096 CLKIN cycle latency for the PLL to lock. After this time, the core begins program
execution from the hardware reset vector address. The RESET input must be asserted
(low) at power-up.
XTAL
O
Crystal Oscillator Terminal. Used in conjunction with CLKIN to drive an external
crystal.
CLKIN
I
Local Clock In. Used with XTAL. CLKIN is the processor’s clock input. It configures the
processors to use either its internal clock generator or an external clock source. Connecting the necessary components to CLKIN and XTAL enables the internal clock
generator. Connecting the external clock to CLKIN while leaving XTAL unconnected
configures the processor to use an external clock such as an external clock oscillator.
CLKIN may not be halted, changed, or operated below the specified frequency.
RESETOUT/
CLKOUT
O/T
Driven low/
driven high
Reset Out/Local Clock Out. Reset out provide a 4096 cycle delay that allows the PLL
to lock. This pin can also be configured as a CLKOUT signal to clock synchronous peripherals and memory. The functionality can be switched between the PLL output clock and
reset out by setting Bit 12 of the PMCTL register. The default is reset out.
BR4–1
I/O (pu)1
Pulled high/
pulled high
External Bus Request. Used by the ADSP-21368 processor to arbitrate for bus mastership. A processor only drives its own BRx line (corresponding to the value of its ID2-0
inputs) and monitors all others. In a system with less than four processors, the unused
BRx pins should be tied high; the processor’s own BRx line must not be tied high or low
because it is an output.
ID2–0
I (pd)
Processor ID. Determines which bus request (BR4–1) is used by the ADSP-21368 processor. ID = 001 corresponds to BR1, ID = 010 corresponds to BR2, and so on. Use
ID = 000 or 001 in single-processor systems. These lines are a system configuration
selection that should be hardwired or only changed at reset. ID = 101,110, and 111 are
reserved.
RPBA
I (pu)1
Rotating Priority Bus Arbitration Select. When RPBA is high, rotating priority for the
ADSP-21368 external bus arbitration is selected. When RPBA is low, fixed priority is
selected. This signal is a system configuration selection which must be set to the same
value on every processor in the system.
The pull-up is always enabled on the ADSP-21367 and ADSP-21369 processors. The pull-up on the ADSP-21368 processor is only enabled on the processor with ID2–0 = 00x
Pull-up can be enabled/disabled, value of pull-up cannot be programmed.
Rev. A |
Page 14 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
DATA MODES
The upper 32 data pins of the external memory interface are
muxed (using bits in the SYSCTL register) to support the external memory interface data (input/output), the PDAP (input
only), the FLAGS (input/output), and the PWM channels (output). Table 6 provides the pin settings.
Table 6. Function of Data Pins
DATA PIN MODE
000
001
010
011
100
101
110
111
1
DATA31–16
DATA15–8
DATA7–0
EPDATA32–0
FLAGS/PWM15–01
FLAGS/PWM15–01
FLAGS/PWM15–01
PDAP (DATA + CTRL)
PDAP (DATA + CTRL)
EPDATA15–0
FLAGS15–8
EPDATA7–0
FLAGS15–0
EPDATA7–0
FLAGS7–0
Reserved
Three-state all pins
These signals can be FLAGS or PWM or a mix of both. However, they can be selected only in groups of four. Their function is determined by the control signals
FLAGS/PWM_SEL. For more information, see the ADSP-21368 SHARC Processor Hardware Reference.
BOOT MODES
Table 7. Boot Mode Selection
BOOT_CFG1–0
00
01
10
Booting Mode
SPI Slave Boot
SPI Master Boot
EPROM/FLASH Boot
CORE INSTRUCTION RATE TO CLKIN RATIO MODES
For details on processor timing, see Timing Specifications and
Figure 4 on Page 19.
Table 8. Core Instruction Rate/CLKIN Ratio Selection
CLK_CFG1–0
00
01
10
Core to CLKIN Ratio
6:1
32:1
16:1
Rev. A |
Page 15 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
SPECIFICATIONS
OPERATING CONDITIONS
333 MHz
266 MHz
Parameter1
Description
Min
Max
Min
Max
Unit
VDDINT
Internal (Core) Supply Voltage
1.235
1.365
1.14
1.26
V
AVDD
Analog (PLL) Supply Voltage
1.235
1.365
1.14
1.26
V
VDDEXT
External (I/O) Supply Voltage
3.13
3.47
3.13
3.47
V
VIH
High Level Input Voltage @ VDDEXT = max
2.0
VDDEXT + 0.5
2.0
VDDEXT + 0.5
V
VIL2
Low Level Input Voltage @ VDDEXT = min
–0.5
+0.8
–0.5
+0.8
V
High Level Input Voltage @ VDDEXT = max
1.74
VDDEXT + 0.5
1.74
VDDEXT + 0.5
V
VIL_CLKIN
Low Level Input Voltage @ VDDEXT = min
–0.5
+1.19
–0.5
+1.19
V
TJ
Junction Temperature
208-Lead MQFP @ TAMBIENT 0°C to +70°C
256-Ball SBGA @ TAMBIENT 0°C to +70°C
256-Ball SBGA @ TAMBIENT –40°C to +85°C
0
+120
0
–40
+110
+125
°C
°C
°C
2
VIH_CLKIN3
3
1
Specifications subject to change without notice.
Applies to input and bidirectional pins: DATAx, ACK, RPBA, BRx, IDx, FLAGx, DAI_Px, DPI_Px, BOOT_CFGx, CLK_CFGx, RESET, TCK, TMS, TDI, TRST.
3
Applies to input pin CLKIN.
2
Rev. A |
Page 16 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
ELECTRICAL CHARACTERISTICS
Parameter1
Description
Test Conditions
VOH2
High Level Output Voltage
@ VDDEXT = min, IOH = –1.0 mA3
2
Typ
Max
2.4
Unit
V
3
Low Level Output Voltage
@ VDDEXT = min, IOL = 1.0 mA
0.4
V
4, 5
High Level Input Current
@ VDDEXT = max, VIN = VDDEXT max
10
μA
4, 6, 7
VOL
IIH
IIL
Min
Low Level Input Current
@ VDDEXT = max, VIN = 0 V
10
μA
6
High Level Input Current Pull-down
@ VDDEXT = max, VIN = 0 V
250
μA
5
Low Level Input Current Pull-up
@ VDDEXT = max, VIN = 0 V
200
μA
8, 9
Three-State Leakage Current
@ VDDEXT = max, VIN = VDDEXT max
10
μA
8, 10
Three-State Leakage Current
@ VDDEXT = max, VIN = 0 V
10
μA
Three-State Leakage Current Pull-up
@ VDDEXT = max, VIN = 0 V
200
μA
IDD-INTYP
Supply Current (Internal)
tCCLK = 3.75 ns, VDDINT = 1.2 V, 25°C
tCCLK = 3.00 ns, VDDINT = 1.3 V, 25°C
AIDD12
Supply Current (Analog)
AVDD = max
10
mA
Input Capacitance
fIN = 1 MHz, TCASE = 25°C, VIN = 1.3 V
4.7
pF
IIHPD
IILPU
IOZH
IOZL
IOZLPU
9
11
13, 14
CIN
1
700
900
mA
mA
Specifications subject to change without notice.
Applies to output and bidirectional pins: ADDRx, DATAx, RD, WR, MSx, BRx, FLAGx, DAI_Px, DPI_Px, SDRAS, SDCAS, SDWE, SDCKE, SDA10, SDCLKx, EMU, TDO,
CLKOUT.
3
See Output Drive Currents on Page 47 for typical drive current capabilities.
4
Applies to input pins without internal pull-ups: BOOT_CFGx, CLK_CFGx, CLKIN, RESET, TCK.
5
Applies to input pins with internal pull-ups: ACK, RPBA, TMS, TDI, TRST.
6
Applies to input pins with internal pull-downs: IDx.
7
Applies to input pins with internal pull-ups disabled: ACK, RPBA.
8
Applies to three-statable pins without internal pull-ups: FLAGx, SDCLKx, TDO.
9
Applies to three-statable pins with internal pull-ups: ADDRx, DATAx, RD, WR, MSx, BRx, DAI_Px, DPI_Px, SDRAS, SDCAS, SDWE, SDCKE, SDA10, EMU.
10
Applies to three-statable pins with internal pull-ups disabled: ADDRx, DATAx, RD, WR, MSx, BRx, DAI_Px, DPI_Px, SDRAS, SDCAS, SDWE, SDCKE, SDA10
11
See Engineer-to-Engineer Note 299 for further information.
12
Characterized, but not tested.
13
Applies to all signal pins.
14
Guaranteed, but not tested.
2
Rev. A |
Page 17 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
PACKAGE INFORMATION
MAXIMUM POWER DISSIPATION
The information presented in Figure 3 provides details about
the package branding for the ADSP-21367/ADSP-21368/
ADSP-21369 processors. For a complete listing of product availability, see Ordering Guide on Page 56.
See Engineer-to-Engineer Note (EE-299) for detailed thermal
and power information regarding maximum power dissipation.
For information on package thermal specifications, see Thermal
Characteristics on Page 48.
ABSOLUTE MAXIMUM RATINGS
Stresses greater than those listed in Table 10 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.
a
ADSP-2136x
tppZ-cc
vvvvvv.x n.n
yyww country_of_origin
S
Table 10. Absolute Maximum Ratings
Figure 3. Typical Package Brand
Parameter
Internal (Core) Supply Voltage (VDDINT)
Analog (PLL) Supply Voltage (AVDD)
External (I/O) Supply Voltage (VDDEXT)
Input Voltage
Output Voltage Swing
Load Capacitance
Storage Temperature Range
Junction Temperature Under Bias
Table 9. Package Brand Information
Brand Key
t
pp
Z
cc
vvvvvv.x
n.n
yyww
Field Description
Temperature Range
Package Type
Lead Free Option (optional)
See Ordering Guide
Assembly Lot Code
Silicon Revision
Date Code
ESD SENSITIVITY
CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily
accumulate on the human body and test equipment and can discharge without detection. Although
the ADSP-21367/ADSP-21368/ADSP-21369 feature proprietary ESD protection circuitry, permanent
damage may occur on devices subjected to high energy electrostatic discharges. Therefore, proper
ESD precautions are recommended to avoid performance degradation or loss of functionality.
Rev. A |
Page 18 of 56 |
August 2006
Rating
–0.3 V to +1.5 V
–0.3 V to +1.5 V
–0.3 V to +4.6 V
–0.5 V to +3.8 V
–0.5 V to VDDEXT + 0.5 V
200 pF
–65°C to +150°C
125°C
ADSP-21367/ADSP-21368/ADSP-21369
TIMING SPECIFICATIONS
The processor’s internal clock (a multiple of CLKIN) provides
the clock signal for timing internal memory, processor core, and
serial ports. During reset, program the ratio between the processor’s internal clock frequency and external (CLKIN) clock
frequency with the CLK_CFG1–0 pins (see Table 8 on Page 15).
To determine switching frequencies for the serial ports, divide
down the internal clock, using the programmable divider control of each port (DIVx for the serial ports).
Table 11. ADSP-21367/ADSP-21368/ADSP-21369
CLKOUT and CCLK Clock Generation Operation
Timing
Requirements
CLKIN
CCLK
Calculation
1/tCK
1/tCCLK
Table 12. Clock Periods
The processor’s internal clock switches at higher frequencies
than the system input clock (CLKIN). To generate the internal
clock, the processor uses an internal phase-locked loop (PLL).
This PLL-based clocking minimizes the skew between the system clock (CLKIN) signal and the processor’s internal clock.
Figure 4 shows core to CLKIN ratios of 6:1, 16:1, and 32:1 with
external oscillator or crystal. Note that more ratios are possible
and can be set through software using the power management
control register (PMCTL). For more information, see the
ADSP-2136x/ADSP-2137x SHARC Processor Programming
Reference.
Description
Input Clock
Core Clock
Timing
Requirements
tCK
tCCLK
tPCLK
tSCLK
tSDCLK
tSPICLK
1
Note the definitions of various clock periods shown in Table 12
which are a function of CLKIN and the appropriate ratio control shown in Table 11.
Description1
CLKIN Clock Period
(Processor) Core Clock Period
(Peripheral) Clock Period = 2 × tCCLK
Serial Port Clock Period = (tPCLK) × SR
SDRAM Clock Period = (tCCLK) × SDR
SPI Clock Period = (tPCLK) × SPIR
where:
SR = serial port-to-core clock ratio (wide range, determined by SPORT CLKDIV
bits in DIVx register)
SPIR = SPI-to-Core Clock Ratio (wide range, determined by SPIBAUD register
setting)
SPICLK = SPI Clock
SDR = SDRAM-to-Core Clock Ratio (values determined by bits 20–18 of the
PMCTL register)
CCLK
(CORE CLOCK)
PLLICLK
CLKIN
XTAL
XTAL
OSC
INDIV
÷1, 2
DIVEN
÷2, 4, 8, 16
PLLM
÷2
÷ 2, 2.5,
3, 3.5, 4
CLK_CFG [1:0]
(6:1, 16:1, 32:1)
CLKOUT
OR
RSTOUT
RESET
DELAY
Figure 4. Core Clock and System Clock Relationship to CLKIN
Rev. A |
Page 19 of 56 |
August 2006
PCLK
(PERIPHERAL CLOCK)
SDCLK
(SDRAM CLOCK)
ADSP-21367/ADSP-21368/ADSP-21369
Use the exact timing information given. Do not attempt to
derive parameters from the addition or subtraction of others.
While addition or subtraction would yield meaningful results
for an individual device, the values given in this data sheet
reflect statistical variations and worst cases. Consequently, it is
not meaningful to add parameters to derive longer times. See
Figure 39 on Page 47 under Test Conditions for voltage reference levels.
Switching Characteristics specify how the processor changes its
signals. Circuitry external to the processor must be designed for
compatibility with these signal characteristics. Switching characteristics describe what the processor will do in a given
circumstance. Use switching characteristics to ensure that any
timing requirement of a device connected to the processor (such
as memory) is satisfied.
Timing Requirements apply to signals that are controlled by circuitry external to the processor, such as the data input for a read
operation. Timing requirements guarantee that the processor
operates correctly with other devices.
Rev. A |
Page 20 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
Power-Up Sequencing
The timing requirements for processor startup are given in
Table 13.
Table 13. Power-Up Sequencing Timing Requirements (Processor Startup)
Parameter
Timing Requirements
tRSTVDD
tIVDDEVDD
tCLKVDD1
tCLKRST
tPLLRST
Min
RESET Low Before VDDINT/VDDEXT On
VDDINT On Before VDDEXT
CLKIN Valid After VDDINT/VDDEXT Valid
CLKIN Valid Before RESET Deasserted
PLL Control Setup Before RESET Deasserted
0
–50
0
102
20
Switching Characteristic
Core Reset Deasserted After RESET Deasserted
tCORERST
Max
+200
+200
Unit
ns
ms
ms
μs
μs
4096tCK + 2 tCCLK 3, 4
1
Valid VDDINT/VDDEXT assumes that the supplies are fully ramped to their 1.2 volt rails and 3.3 volt rails. Voltage ramp rates can vary from microseconds to hundreds of milliseconds
depending on the design of the power supply subsystem.
2
Assumes a stable CLKIN signal, after meeting worst-case startup timing of crystal oscillators. Refer to your crystal oscillator manufacturer’s data sheet for start-up time. Assume
a 25 ms maximum oscillator start-up time if using the XTAL pin and internal oscillator circuit in conjunction with an external crystal.
3
Applies after the power-up sequence is complete. Subsequent resets require RESET to be held low a minimum of four CLKIN cycles in order to properly initialize and propagate
default states at all I/O pins.
4
The 4096 cycle count depends on tsrst specification in Table 15. If setup time is not met, 1 additional CLKIN cycle may be added to the core reset time, resulting in 4097 cycles
maximum.
RESET
tRSTVDD
VDDINT
tIVDDEVDD
VDDEXT
tCLKVDD
CLKIN
tCLKRST
CLK_CFG1-0
tCORERST
tPLLRST
RSTOUT
Figure 5. Power-Up Sequencing
Rev. A |
Page 21 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
Clock Input
Table 14. Clock Input
Parameter
Timing Requirements
tCK
CLKIN Period
tCKL
CLKIN Width Low
tCKH
CLKIN Width High
tCKRF
CLKIN Rise/Fall (0.4 V to 2.0 V)
tCCLK3
CCLK Period
CLKIN Jitter Tolerance
tCKJ4, 5
Min
181
81
81
3.01
–250
1
Applies only for CLK_CFG1–0 = 00 and default values for PLL control bits in PMCTL.
Applies only for CLK_CFG1–0 = 10 and default values for PLL control bits in PMCTL.
3
Any changes to PLL control bits in the PMCTL register must meet core clock timing specification tCCLK.
4
Actual input jitter should be combined with ac specifications for accurate timing analysis.
5
Jitter specification is maximum peak-to-peak time interval error (TIE) jitter.
2
tCK
CLKIN
tCKH
tCKL
Figure 6. Clock Input
Clock Signals
The processors can use an external clock or a crystal. See the
CLKIN pin description in Table 5. Programs can configure the
processor to use its internal clock generator by connecting the
necessary components to CLKIN and XTAL. Figure 7 shows the
component connections used for a crystal operating in fundamental mode. Note that the clock rate is achieved using a
20.81 MHz crystal and a PLL multiplier ratio 16:1
(CCLK:CLKIN achieves a clock speed of 333 MHz). To achieve
the full core clock rate, programs need to configure the multiplier bits in the PMCTL register.
ADSP-2136x
CLKIN
R1
1M⍀ (TYPICAL)
XTAL
R2
47⍀ (TYPICAL)
C1
22pF
Y1
C2
22pF
24.576MHz
R2 SHOULD BE CHOSEN TO LIMIT CRYSTAL DRIVE POWER.
REFER TO CRYSTAL MANUFACTURER’S SPECIFICATIONS
Figure 7. 333 MHz Operation (Fundamental Mode Crystal)
Rev. A |
Page 22 of 56 |
August 2006
333 MHz
Max
1002
452
452
3
10
+250
Unit
ns
ns
ns
ns
ns
ps
ADSP-21367/ADSP-21368/ADSP-21369
Reset
Table 15. Reset
Parameter
Timing Requirements
tWRST1
RESET Pulse Width Low
tSRST
RESET Setup Before CLKIN Low
1
Min
Max
Unit
4tCK
8
ns
ns
Applies after the power-up sequence is complete. At power-up, the processor’s internal phase-locked loop requires no more than 100 μs while RESET is low, assuming stable
VDD and CLKIN (not including startup time of external clock oscillator).
CLKIN
tSRST
tWRST
RESET
Figure 8. Reset
Interrupts
The following timing specification applies to the FLAG0,
FLAG1, and FLAG2 pins when they are configured as IRQ0,
IRQ1, and IRQ2 interrupts.
Table 16. Interrupts
Parameter
Timing Requirement
tIPW
IRQx Pulse Width
Min
2 × tPCLK +2
DAI_P20-1
DPI_14-1
FLAG2 -0
(IRQ2-0)
tIPW
Figure 9. Interrupts
Rev. A |
Page 23 of 56 |
August 2006
Max
Unit
ns
ADSP-21367/ADSP-21368/ADSP-21369
Core Timer
The following timing specification applies to FLAG3 when it is
configured as the core timer (CTIMER).
Table 17. Core Timer
Parameter
Switching Characteristic
tWCTIM
CTIMER Pulse Width
Min
Max
4 × tPCLK – 1
Unit
ns
tWCTIM
FLAG3
(CTIMER)
Figure 10. Core Timer
Timer PWM_OUT Cycle Timing
The following timing specification applies to Timer0, Timer1,
and Timer2 in PWM_OUT (pulse-width modulation) mode.
Timer signals are routed to the DPI_P14–1 pins through the
DPI SRU. Therefore, the timing specifications provided below
are valid at the DPI_P14–1 pins.
Table 18. Timer PWM_OUT Timing
Parameter
Switching Characteristic
tPWMO
Timer Pulse Width Output
Min
Max
Unit
2 × tPCLK – 2
2 × (231 – 1) × tPCLK
ns
tPWMO
DPI_P14-1
(TIMER2 -0)
Figure 11. Timer PWM_OUT Timing
Rev. A |
Page 24 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
Timer WDTH_CAP Timing
The following timing specification applies to Timer0, Timer1,
and Timer2 in WDTH_CAP (pulse width count and capture)
mode. Timer signals are routed to the DPI_P14–1 pins through
the DPI SRU. Therefore, the timing specification provided
below are valid at the DPI_P14–1 pins.
Table 19. Timer Width Capture Timing
Parameter
Switching Characteristic
tPWI
Timer Pulse Width
Min
Max
Unit
2 × tPCLK
2 × (231 – 1) × tPCLK
ns
tPWI
DPI_P14- 1
(TIMER2 -0)
Figure 12. Timer Width Capture Timing
Pin to Pin Direct Routing (DAI and DPI)
For direct pin connections only (for example, DAI_PB01_I to
DAI_PB02_O).
Table 20. DAI Pin to Pin Routing
Parameter
Timing Requirement
tDPIO
Delay DAI Pin Input Valid to DAI Output Valid
Min
Max
Unit
1.5
10
ns
DAI_Pn
DPI_Pn
DAI_pm
DPI_Pm
tDPIO
Figure 13. DAI Pin to Pin Direct Routing
Rev. A |
Page 25 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
Precision Clock Generator (Direct Pin Routing)
This timing is only valid when the SRU is configured such that
the precision clock generator (PCG) takes its inputs directly
from the DAI pins (via pin buffers) and sends its outputs
directly to the DAI pins. For the other cases, where the PCG’s
inputs and outputs are not directly routed to/from DAI pins (via
pin buffers) there is no timing data available. All timing parameters and switching characteristics apply to external DAI pins
(DAI_P01 – DAI_P20).
Table 21. Precision Clock Generator (Direct Pin Routing)
Parameter
Min
Max
Unit
Timing Requirements
tPCGIP
Input Clock Period
24
ns
tSTRIG
PCG Trigger Setup Before Falling
4.5
ns
Edge of PCG Input Clock
tHTRIG
PCG Trigger Hold After Falling
3
ns
Edge of PCG Input Clock
Switching Characteristics
tDPCGIO
PCG Output Clock and Frame Sync Active Edge
Delay After PCG Input Clock
2.5
10
ns
tDTRIGCLK
PCG Output Clock Delay After PCG Trigger
2.5 + ((2.5 + D) × tPCGIP)
10 + ((2.5 + D) × tPCGIP)
ns
tDTRIGFS
PCG Frame Sync Delay After PCG Trigger
2.5 + ((2.5 + D – PH) × tPCGIP)
10 + ((2.5 + D – PH) × tPCGIP)
ns
tPCGOW1
Output Clock Period
2 × tPCGIP – 1
ns
D = FSxDIV, PH = FSxPHASE. For more information, see the ADSP-2136x SHARC Processor Hardware Reference for the ADSP-21368 Processor,
“Precision Clock Generators” chapter.
1
In normal mode.
tSTRIG
tHTRIG
DAI_Pn
DPI_Pn
PCG_TRIGx_I
tPCGIP
DAI_Pm
DPI_Pm
PCG_EXTx_I
(CLKIN)
tDPCGIO
DAI_Py
DPI_Py
PCG_CLKx_O
tDTRIGCLK
DAI_Pz
DPI_Pz
PCG_FSx_O
tDPCGIO
tDTRIGFS
Figure 14. Precision Clock Generator (Direct Pin Routing)
Rev. A |
Page 26 of 56 |
August 2006
tPCGOW
ADSP-21367/ADSP-21368/ADSP-21369
Flags
The timing specifications provided below apply to the FLAG3–0
and DPI_P14–1 pins, and the serial peripheral interface (SPI).
See Table 5 on Page 12 for more information on flag use.
Table 22. Flags
Parameter
Timing Requirement
FLAG3–0 IN Pulse Width
tFIPW
Switching Characteristic
tFOPW
FLAG3–0 OUT Pulse Width
Min
ns
2 × tPCLK – 1.5
ns
tFIPW
DPI_P14-1
(FLAG3- 0OUT)
(DATA31-0)
tFOPW
Figure 15. Flags
Rev. A |
Page 27 of 56 |
Unit
2 × tPCLK + 3
DPI_P14-1
(FLAG3-0IN)
(DATA31-0)
Max
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
SDRAM Interface Timing (133 MHz SDCLK)
The 133 MHz access speed is for a single processor. When multiple ADSP-21368 processors are connected in a shared memory
system, the access speed is 100 MHz.
Table 23. SDRAM Interface Timing1
Parameter
Timing Requirements
DATA Setup Before SDCLK
tSSDAT
tHSDAT
DATA Hold After SDCLK
Switching Characteristics
tSDCLK
SDCLK Period
tSDCLKH
SDCLK Width High
tSDCLKL
SDCLK Width Low
Command, ADDR, Data Delay After SDCLK2
tDCAD
tHCAD
Command, ADDR, Data Hold After SDCLK2
tDSDAT
Data Disable After SDCLK
tENSDAT
Data Enable After SDCLK
Min
Max
0.58
1.23
ns
ns
7.5
3.65
3.65
ns
ns
ns
ns
ns
ns
ns
4.8
1.5
5.3
1.6
1
For FCCLK = 333 MHz (SDCLK ratio = 1:2.5).
2
Command pins include: SDCAS, SDRAS, SDWE, MSx, SDA10, SDCKE.
tSDCLK
tSDCLKH
SDCLK
tSSDAT
tSDCLKL
tHSDAT
DATA (IN)
tDCAD
tENSDAT
tDCAD
CMND ADDR
(OUT)
tHCAD
Figure 16. SDRAM Interface Timing
Rev. A |
Page 28 of 56 |
tDSDAT
tHCAD
DATA(OUT)
August 2006
Unit
ADSP-21367/ADSP-21368/ADSP-21369
SDRAM Interface Enable/Disable Timing (133 MHz SDCLK)
Table 24. SDRAM Interface Enable/Disable Timing1
Parameter
Switching Characteristics
tDSDC
Command Disable After CLKIN Rise
tENSDC
Command Enable After CLKIN Rise
tDSDCC
SDCLK Disable After CLKIN Rise
tENSDCC
SDCLK Enable After CLKIN Rise
tDSDCA
Address Disable After CLKIN Rise
tENSDCA
Address Enable After CLKIN Rise
1
Min
ns
ns
ns
ns
ns
ns
8.5
2 × tPCLK – 4
COMMAND
SDCLK
ADDR
tENSDC
tENSDCC
tENSDCA
Figure 17. SDRAM Interface Enable/Disable Timing
Rev. A |
2 × tPCLK + 1
3.8
tDSDC
tDSDCC
tDSDCA
COMMAND
SDCLK
ADDR
Unit
4.0
For FCCLK = 333 MHz (SDCLK ratio = 1:2.5).
CLKIN
Max
Page 29 of 56 |
August 2006
9.2
4 × tPCLK
ADSP-21367/ADSP-21368/ADSP-21369
Memory Read—Bus Master
Use these specifications for asynchronous interfacing to memories. These specifications apply when the processors are the bus
master accessing external memory space in asynchronous access
mode. Note that timing for ACK, DATA, RD, WR, and strobe
timing parameters only apply to asynchronous access mode.
Table 25. Memory Read—Bus Master
Parameter
Timing Requirements
tDAD
Address, Selects Delay to Data Valid1, 2
tDRLD
RD Low to Data Valid1
tSDS
Data Setup to RD High
tHDRH
Data Hold from RD High3, 4
tDAAK
ACK Delay from Address, Selects2, 5
tDSAK
ACK Delay from RD Low4
Min
Max
Unit
W+tSDCLK –5.12
W– 2.9
tSDCLK –9.5+ W
ns
ns
ns
ns
ns
W – 7.0
ns
2.2
0
Switching Characteristics
tDRHA
Address Selects Hold After RD High
RH + 0.38
tDARL
Address Selects to RD Low2
tSDCLK –3.3
tRW
RD Pulse Width
W – 1.2
tRWR
RD High to WR, RD Low
HI +tSDCLK – 0.8
W = (number of wait states specified in AMICTLx register) × tSDCLK.
HI =RHC + IC (RHC = number of read hold cycles specified in AMICTLx register) × tSDCLK
IC = (number of idle cycles specified in AMICTLx register) × tSDCLK.
H = (number of hold cycles specified in AMICTLx register) × tSDCLK.
ns
ns
ns
ns
1
Data delay/setup: system must meet tDAD, tDRLD, or tSDS.
The falling edge of MSx is referenced.
3
Note that timing for ACK, DATA, RD, WR, and strobe timing parameters only apply to asynchronous access mode.
4
Data hold: User must meet tHDA or tHDRH in asynchronous access mode. See Test Conditions on Page 47 for the calculation of hold times given capacitive and dc loads.
5
ACK Delay/Setup: User must meet tDAAK, or tDSAK, for deassertion of ACK (low). For asynchronous assertion of ACK (high) user must meet tDAAK or tDSAK.
2
ADDRESS
MSx
RD
tDRHA
tDARL
tRW
tDRLD
tSDS
tDAD
tHDRH
DATA
tDSAK
tDAAK
tRWR
ACK
WR
Figure 18. Memory Read—Bus Master
Rev. A |
Page 30 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
Memory Write—Bus Master
Use these specifications for asynchronous interfacing to memories. These specifications apply when the processors are the bus
master accessing external memory space in asynchronous access
mode. Note that timing for ACK, DATA, RD, WR, and strobe
timing parameters only apply to asynchronous access mode.
Table 26. Memory Write—Bus Master
Parameter
Timing Requirements
tDAAK
ACK Delay from Address, Selects1, 2
tDSAK
ACK Delay from WR Low 1, 3
Switching Characteristics
tDAWH
Address, Selects to WR Deasserted2
Address, Selects to WR Low2
tDAWL
tWW
WR Pulse Width
tDDWH
Data Setup Before WR High
tDWHA
Address Hold After WR Deasserted
tDWHD
Data Hold After WR Deasserted
tWWR
WR High to WR, RD Low
Data Disable Before RD Low
tDDWR
tWDE
WR Low to Data Enabled
W = (number of wait states specified in AMICTLx register) × tSDCLK.
H = (number of hold cycles specified in AMICTLx register) x tSDCLK.
Min
Max
Unit
tSDCLK – 9.7 + W
W – 4.9
ns
ns
tSDCLK – 3.1+ W
tSDCLK – 2.7
W – 1.3
tSDCLK – 3.0+ W
H + 0.15
H + 0.02
tSDCLK – 1.5+ H
2tSDCLK – 4.11
tSDCLK – 3.5
ns
ns
ns
ns
ns
ns
ns
ns
ns
1
ACK Delay/Setup: System must meet tDAAK, or tDSAK, for deassertion of ACK (low). For asynchronous assertion of ACK (high) user must meet tDAAK or tDSAK.
The falling edge of MSx is referenced.
3
Note that timing for ACK, DATA, RD, WR, and strobe timing parameters only applies to asynchronous access mode.
2
ADDRESS
MSx
tDAWH
tDAWL
tDWHA
tWW
WR
tWWR
tWDE
tDDWR
tDDWH
DATA
tDSAK
tDWHD
tDAAK
ACK
RD
Figure 19. Memory Write—Bus Master
Rev. A |
Page 31 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
Asynchronous Memory Interface (AMI) Enable/Disable
Use these specifications for passing bus mastership between
ADSP-21368 processors (BRx).
Table 27. AMI Enable/Disable
Parameter
Switching Characteristics
tENAMIAC
Address/Control Enable After Clock Rise
tENAMID
Data Enable After Clock Rise
tDISAMIAC
Address/Control Disable After Clock Rise
tDISAMID
Data Disable After Clock Rise
Min
ADDR, WR, RD,
MS1-0, DATA
tENAMIAC
tENAMID
ADDR, WR, RD,
MS1-0, DATA
Figure 20. AMI Enable/Disable
Rev. A |
Unit
8.7
0
ns
ns
ns
ns
4
tSCLK + 4
tDISAMIAC
tDISAMID
CLKIN
Max
Page 32 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
Shared Memory Bus Request
Use these specifications for passing bus mastership between
ADSP-21368 processors (BRx).
Table 28. Multiprocessor Bus Request
Parameter
Timing Requirements
tSBRI
BRx, Setup Before CLKIN High
tHBRI
BRx, Hold After CLKIN High
Switching Characteristics
tDBRO
BRx Delay After CLKIN High
BRx Hold After CLKIN High
tHBRO
Min
Max
9
0.5
ns
ns
9
1.0
CLKIN
tDBRO
tHBRO
BRX (OUT)
tSBRI
BR X (IN)
Figure 21. Shared Memory Bus Request
Rev. A |
Page 33 of 56 |
August 2006
Unit
tHBRI
ns
ns
ADSP-21367/ADSP-21368/ADSP-21369
Serial Ports
To determine whether communication is possible between two
devices at clock speed n, the following specifications must be
confirmed: 1) frame sync delay and frame sync setup and hold,
2) data delay and data setup and hold, and 3) SCLK width.
Serial port signals (SCLK, FS, data channel A, data channel B)
are routed to the DAI_P20–1 pins using the SRU. Therefore, the
timing specifications provided below are valid at the
DAI_P20–1 pins.
Table 29. Serial Ports—External Clock
Parameter
Timing Requirements
tSFSE1
FS Setup Before SCLK
(Externally Generated FS in Either Transmit or Receive Mode)
tHFSE1
FS Hold After SCLK
(Externally Generated FS in Either Transmit or Receive Mode)
1
tSDRE
Receive Data Setup Before Receive SCLK
tHDRE1
Receive Data Hold After SCLK
tSCLKW
SCLK Width
tSCLK
SCLK Period
Switching Characteristics
tDFSE2
FS Delay After SCLK
(Internally Generated FS in Either Transmit or Receive Mode)
FS Hold After SCLK
tHOFSE2
(Internally Generated FS in Either Transmit or Receive Mode)
tDDTE2
Transmit Data Delay After Transmit SCLK
2
Transmit Data Hold After Transmit SCLK
tHDTE
Min
Max
Unit
2.5
ns
2.5
2.5
2.5
10
20
ns
ns
ns
ns
ns
9.5
ns
9.6
ns
ns
ns
2
2
1
Referenced to sample edge.
2
Referenced to drive edge.
Table 30. Serial Ports—Internal Clock
Parameter
Timing Requirements
tSFSI1
FS Setup Before SCLK
(Externally Generated FS in Either Transmit or Receive Mode)
1
tHFSI
FS Hold After SCLK
(Externally Generated FS in Either Transmit or Receive Mode)
1
Receive Data Setup Before SCLK
tSDRI
tHDRI1
Receive Data Hold After SCLK
Switching Characteristics
tDFSI2
FS Delay After SCLK (Internally Generated FS in Transmit Mode)
tHOFSI2
FS Hold After SCLK (Internally Generated FS in Transmit Mode)
tDFSIR2
FS Delay After SCLK (Internally Generated FS in Receive Mode)
2
FS Hold After SCLK (Internally Generated FS in Receive Mode)
tHOFSIR
tDDTI2
Transmit Data Delay After SCLK
tHDTI2
Transmit Data Hold After SCLK
3
tSCLKIW
Transmit or Receive SCLK Width
1
Referenced to the sample edge.
2
Referenced to drive edge.
3
Minimum SPORT divisor register value.
Rev. A |
Page 34 of 56 |
August 2006
Min
Max
Unit
7
ns
2.5
7
2.5
ns
ns
ns
4
–1.0
9
–1.0
3
–1.0
2 × tPCLK – 1.5
2 × tPCLK
ns
ns
ns
ns
ns
ns
ns
ADSP-21367/ADSP-21368/ADSP-21369
Table 31. Serial Ports—Enable and Three-State
Parameter
Switching Characteristics
tDDTEN1
Data Enable from External Transmit SCLK
Data Disable from External Transmit SCLK
tDDTTE1
tDDTIN1
Data Enable from Internal Transmit SCLK
1
Min
Max
Unit
10
ns
ns
ns
Max
Unit
7.75
ns
ns
2
–1
Referenced to drive edge.
Table 32. Serial Ports—External Late Frame Sync
Parameter
Switching Characteristics
tDDTLFSE1
Data Delay from Late External Transmit FS or External Receive
FS with MCE = 1, MFD = 0
tDDTENFS1
Data Enable for MCE = 1, MFD = 0
1
Min
0.5
The tDDTLFSE and tDDTENFS parameters apply to left-justified sample pair as well as DSP serial mode, and MCE = 1, MFD = 0.
EXTERNAL RECEIVE FS WITH MCE = 1, MFD = 0
DAI_P20-1
(SCLK)
DRIVE
SAMPLE
DRIVE
tSFSE/I
tHFSE/I
DAI_P20- 1
(FS)
tDDTE/I
tDDTENFS
tHDTE/I
DAI_P20-1
(DATA CHANNEL A/B)
1ST BIT
2ND BIT
tDDTLFSE
LATE EXTERNAL TRANSMIT FS
DAI_P20- 1
(SCLK)
DRIVE
SAMPLE
DRIVE
tSFSE/I
tHFSE/I
DAI_P20-1
(FS)
tDDTE/I
tDDTENFS
tHDTE/I
DAI_P20- 1
(DATA CHANNEL A/B)
1ST BIT
2ND BIT
tDDTLFSE
NOTE: SERIAL PORT SIGNALS (SCLK, FS, DATA CHANNEL A/B) ARE ROUTED TO THE DAI_P20- 1 PINS
USING THE SRU. THE TIMING SPECIFICATIONS PROVIDED HERE ARE VALID AT THE DAI_P20-1 PINS.
Figure 22. External Late Frame Sync1
1
This figure reflects changes made to support left-justified sample pair mode.
Rev. A |
Page 35 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
DATA RECEIVE—INTERNAL CLOCK
DRIVE EDGE
DATA RECEIVE—EXTERNAL CLOCK
SAMPLE EDGE
DRIVE EDGE
SAMPLE EDGE
tSCLKIW
tSCLKW
DAI_P20-1
(SCLK)
DAI_P20- 1
(SCLK)
tDFSIR
tDFSE
tHFSI
tSFSI
tHOFSIR
DAI_P20-1
(FS)
tHFSE
tSFSE
tHOFSE
DAI_P20-1
(FS)
tSDRI
tHDRI
DAI_P20-1
(DATA CHANNEL A/B)
tSDRE
tHDRE
DAI_P20-1
(DATA CHANNEL A/B)
NOTE: EITHER THE RISING EDGE OR FALLING EDGE OF SCLK (EXTERNAL), SCLK (INTERNAL) CAN BE USED AS THE ACTIVE SAMPLING EDGE.
DATA TRANSMIT—INTERNAL CLOCK
DRIVE EDGE
DATA TRANSMIT—EXTERNAL CLOCK
SAMPLE EDGE
DRIVE EDGE
SAMPLE EDGE
tSCLKIW
tSCLKW
DAI_P20-1
(SCLK)
DAI_P20-1
(SCLK)
tDFSI
tDFSE
tHOFSI
tHFSI
tSFSI
DAI_P20- 1
(FS)
tHOFSE
tSFSE
tHFSE
DAI_P20-1
(FS)
tHDTI
tDDTI
tDDTE
tHDTE
DAI_P20-1
(DATA CHANNEL A/B)
DAI_P20- 1
(DATA CHANNEL A/B)
NOTE: EITHER THE RISING EDGE OR FALLING EDGE OF SCLK (EXTERNAL), SCLK (INTERNAL) CAN BE USED AS THE ACTIVE SAMPLING EDGE.
DRIVE EDGE
DRIVE EDGE
SCLK
DAI_P20-1
SCLK (EXT)
tDDTEN
tDDTTE
DAI_P20- 1
(DATA CHANNEL A/B)
DRIVE EDGE
DAI_P20-1
SCLK (INT)
tDDTIN
DAI_P20- 1
(DATA CHANNEL A/B)
Figure 23. Serial Ports
Rev. A |
Page 36 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
Input Data Port
The timing requirements for the IDP are given in Table 33. IDP
signals (SCLK, FS, SDATA) are routed to the DAI_P20–1 pins
using the SRU. Therefore, the timing specifications provided
below are valid at the DAI_P20–1 pins.
Table 33. IDP
Parameter
Timing Requirements
tSISFS1
FS Setup Before SCLK Rising Edge
1
tSIHFS
FS Hold After SCLK Rising Edge
SDATA Setup Before SCLK Rising Edge
tSISD1
tSIHD1
SDATA Hold After SCLK Rising Edge
tIDPCLKW
Clock Width
tIDPCLK
Clock Period
1
Min
3.8
2.5
2.5
2.5
9
24
Max
Unit
ns
ns
ns
ns
ns
ns
DATA, SCLK, FS can come from any of the DAI pins. SCLK and FS can also come via PCG or SPORTs. PCG’s input can be either CLKIN or any of the DAI pins.
SAMPLE EDGE
tIDPCLK
tIDPCLKW
DAI_P20-1
(SCLK)
tSISFS
tSIHFS
DAI_P20-1
(FS)
tSISD
tSIHD
DAI_P20-1
(SDATA)
Figure 24. IDP Master Timing
Rev. A |
Page 37 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
Reference. Note that the most significant 16 bits of external
PDAP data can be provided through the DATA31–16 pins. The
remaining four bits can only be sourced through DAI_P4–1.
The timing below is valid at the DATA31–16 pins.
Parallel Data Acquisition Port (PDAP)
The timing requirements for the PDAP are provided in
Table 34. PDAP is the parallel mode operation of Channel 0 of
the IDP. For details on the operation of the IDP, see the IDP
chapter of the ADSP-21368 SHARC Processor Hardware
Table 34. Parallel Data Acquisition Port (PDAP)
Parameter
Timing Requirements
tSPCLKEN1
PDAP_CLKEN Setup Before PDAP_CLK Sample Edge
1
tHPCLKEN
PDAP_CLKEN Hold After PDAP_CLK Sample Edge
PDAP_DAT Setup Before SCLK PDAP_CLK Sample Edge
tPDSD1
tPDHD1
PDAP_DAT Hold After SCLK PDAP_CLK Sample Edge
tPDCLKW
Clock Width
tPDCLK
Clock Period
Switching Characteristics
tPDHLDD
Delay of PDAP Strobe After Last PDAP_CLK Capture Edge for a Word
PDAP Strobe Pulse Width
tPDSTRB
1
Min
Max
Unit
2.5
2.5
3.85
2.5
7.0
24
ns
ns
ns
ns
ns
ns
2 × tPCLK + 3
2 × tPCLK – 1
ns
ns
Source pins of DATA are ADDR7–0, DATA7–0, or DAI pins. Source pins for SCLK and FS are: 1) DAI pins, 2) CLKIN through PCG, or 3) DAI pins through PCG.
SAMPLE EDGE
t PDCLK
t PDCLKW
DAI_P20 -1
(PDAP_CLK)
t SPCLKEN
t HPCLKEN
DAI_P20- 1
(PDAP_CLKEN)
t PDSD
t PDHD
DATA
DAI_P20-1
(PDAP_STROBE)
tPDSTRB
t PDHLDD
Figure 25. PDAP Timing
Rev. A |
Page 38 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
Pulse-Width Modulation Generators
Table 35. PWM Timing
Parameter
Switching Characteristics
tPWMW
PWM Output Pulse Width
tPWMP
PWM Output Period
Min
Max
Unit
tPCLK – 2
2 × tPCLK – 1.5
(216 – 2) × tPCLK – 2
(216 – 1) × tPCLK – 1.5
ns
ns
tPWMW
PWM
OUTPUTS
tPWMP
Figure 26. PWM Timing
Sample Rate Converter—Serial Input Port
The SRC input signals (SCLK, FS, and SDATA) are routed from
the DAI_P20–1 pins using the SRU. Therefore, the timing specifications provided in Table 36 are valid at the DAI_P20–1 pins.
Table 36. SRC, Serial Input Port
Parameter
Timing Requirements
tSRCSFS1
FS Setup Before SCLK Rising Edge
tSRCHFS1
FS Hold After SCLK Rising Edge
tSRCSD1
SDATA Setup Before SCLK Rising Edge
tSRCHD1
SDATA Hold After SCLK Rising Edge
tSRCCLKW
Clock Width
Clock Period
tSRCCLK
1
Min
4
5.5
4
5.5
9
24
Max
Unit
ns
ns
ns
ns
ns
ns
DATA, SCLK, FS can come from any of the DAI pins. SCLK and FS can also come via PCG or SPORTs. PCG’s input can be either CLKIN or any of the DAI pins.
SAMPLE EDGE
tSRCCLK
DAI_P20-1
(SCLK)
tSRCCLKW
tSRCSFS
tSRCHFS
DAI_P20-1
(FS)
tSRCSD
tSRCHD
DAI_P20- 1
(SDATA)
Figure 27. SRC Serial Input Port Timing
Rev. A |
Page 39 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
and delay specification with regard to SCLK. Note that SCLK
rising edge is the sampling edge and the falling edge is the
drive edge.
Sample Rate Converter—Serial Output Port
For the serial output port, the frame-sync is an input and it
should meet setup and hold times with regard to SCLK on the
output port. The serial data output, SDATA, has a hold time
Table 37. SRC, Serial Output Port
Parameter
Timing Requirements
FS Setup Before SCLK Rising Edge
tSRCSFS1
tSRCHFS1
FS Hold After SCLK Rising Edge
tSRCCLKW
Clock Width
tSRCCLK
Clock Period
Switching Characteristics
tSRCTDD1
Transmit Data Delay After SCLK Falling Edge
1
Transmit Data Hold After SCLK Falling Edge
tSRCTDH
1
Min
Max
4
5.5
9
24
ns
ns
ns
ns
8.9
1
Unit
ns
ns
DATA, SCLK, and FS can come from any of the DAI pins. SCLK and FS can also come via PCG or SPORTs. PCG’s input can be either CLKIN or any of the DAI pins.
SAMPLE EDGE
tSRCCLK
tSRCCLKW
DAI_P20-1
(SCLK)
tSRCSFS
tSRCHFS
DAI_P20-1
(FS)
tSRCTDD
DAI_P20-1
(SDATA)
tSRCTDH
Figure 28. SRC Serial Output Port Timing
Rev. A |
Page 40 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
SPDIF Transmitter
SPDIF Transmitter—Serial Input Waveforms
Serial data input to the SPDIF transmitter can be formatted as
left justified, I2S, or right justified with word widths of 16, 18, 20,
or 24 bits. The following sections provide timing for the
transmitter.
Figure 29 shows the right-justified mode. LRCLK is HI for the
left channel and LO for the right channel. Data is valid on the
rising edge of SCLK. The MSB is delayed 12-bit clock periods
(in 20-bit output mode) or 16-bit clock periods (in 16-bit output
mode) from an LRCLK transition, so that when there are 64
SCLK periods per LRCLK period, the LSB of the data is rightjustified to the next LRCLK transition.
DAI_P20- 1
LRCLK
RIGHT CHANNEL
LEFT CHANNEL
DAI_P20- 1
SCLK
DAI_P20- 1
SDATA
LSB
MSB
MSB-1
MSB-2
LSB+2 LSB+1
LSB
MSB
MSB-1
MSB-2
LSB+2
LSB+1
LSB
Figure 29. Right-Justified Mode
Figure 30 shows the default I2S-justified mode. LRCLK is LO for
the left channel and HI for the right channel. Data is valid on the
rising edge of SCLK. The MSB is left-justified to an LRCLK
transition but with a single SCLK period delay.
RIGHT CHANNEL
DAI_P20-1
LRCLK
LEFT CHANNEL
DAI_P20-1
SCLK
DAI_P20-1
SDATA
MSB
MSB-1
MSB-2
LSB+2 LSB+1
LSB
MSB
MSB-1
MSB-2
LSB+2
LSB+1
LSB
MSB
Figure 30. I2S-Justified Mode
Figure 31 shows the left-justified mode. LRCLK is HI for the left
channel and LO for the right channel. Data is valid on the rising
edge of SCLK. The MSB is left-justified to an LRCLK transition
with no MSB delay.
DAI_P20 -1
LRCLK
RIGHT CHANNEL
LEFT CHANNEL
DAI_P20 -1
SCLK
DAI_P20 -1
SDATA
MSB
MSB-1
MSB-2
LSB+2
LSB+1
LSB
MSB
MSB-1
MSB-2
Figure 31. Left-Justified Mode
Rev. A |
Page 41 of 56 |
August 2006
LS B+2
LSB+1
LSB
MSB
MSB+1
ADSP-21367/ADSP-21368/ADSP-21369
SPDIF Transmitter Input Data Timing
The timing requirements for the input port are given in
Table 38. Input signals (SCLK, FS, SDATA) are routed to the
DAI_P20–1 pins using the SRU. Therefore, the timing specifications provided below are valid at the DAI_P20–1 pins.
Table 38. SPDIF Transmitter Input Data Timing
Parameter
Timing Requirements
tSISFS1
FS Setup Before SCLK Rising Edge
tSIHFS1
FS Hold After SCLK Rising Edge
tSISD1
SData Setup Before SCLK Rising Edge
tSIHD1
SData Hold After SCLK Rising Edge
Clock Width
tSISCLKW
tSISCLK
Clock Period
tSITXCLKW
Transmit Clock Width
tSITXCLK
Transmit Clock Period
1
Min
Max
3
3
3
3
36
80
9
20
Unit
ns
ns
ns
ns
ns
ns
ns
ns
DATA, SCLK, and FS can come from any of the DAI pins. SCLK and FS can also come via PCG or SPORTs. PCG’s input can be either CLKIN or any of the DAI pins.
SAMPLE EDGE
tSITXCLKW
tSITXCLK
DAI_P20-1
(TXCLK)
tSISCLKW
DAI_P20-1
(SCLK)
tSIHFS
tSISFS
DAI_P20-1
(FS)
tSISD
tSIHD
DAI_P20-1
(SDATA)
Figure 32. SPDIF Transmitter Input Timing
Oversampling Clock (TxCLK) Switching Characteristics
The SPDIF transmitter has an oversampling clock. This TxCLK
input is divided down to generate the biphase clock.
Table 39. Oversampling Clock (TxCLK) Switching Characteristics
Parameter
TxCLK Frequency for TxCLK = 768 × FS
TxCLK Frequency for TxCLK = 512 × FS
TxCLK Frequency for TxCLK = 384 × FS
TxCLK Frequency for TxCLK = 256 × FS
Frame Rate
Min
Rev. A |
Page 42 of 56 |
August 2006
Max
147.5
98.4
73.8
49.2
192.0
Unit
MHz
MHz
MHz
MHz
kHz
ADSP-21367/ADSP-21368/ADSP-21369
SPDIF Receiver
The following section describes timing as it relates to the SPDIF
receiver.
Internal Digital PLL Mode
In the internal digital phase-locked loop mode the internal PLL
(digital PLL) generates the 512 × FS clock.
Table 40. SPDIF Receiver Internal Digital PLL Mode Timing
Parameter
Switching Characteristics
LRCLK Delay After SCLK
tDFSI
tHOFSI
LRCLK Hold After SCLK
tDDTI
Transmit Data Delay After SCLK
tHDTI
Transmit Data Hold After SCLK
tSCLKIW1
Transmit SCLK Width
1
Min
Max
Unit
5
ns
ns
ns
ns
ns
–2
5
–2
40
SCLK frequency is 64 × FS where FS = the frequency of LRCLK.
DRIVE EDGE
SAMPLE EDGE
tSCLKIW
DAI_P20-1
(SCLK)
tDFSI
tHOFSI
DAI_P20-1
(FS)
tHDTI
tDDTI
DAI_P20-1
(DATA CHANNEL A/B)
Figure 33. SPDIF Receiver Internal Digital PLL Mode Timing
Rev. A |
Page 43 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
SPI Interface—Master
The processors contain two SPI ports. The primary has dedicated pins and the secondary is available through the DPI. The
timing provided in Table 41 and Table 42 on Page 45 applies
to both.
Table 41. SPI Interface Protocol—Master Switching and Timing Specifications
Parameter
Timing Requirements
tSSPIDM
Data Input Valid to SPICLK Edge (Data Input Setup Time)
tHSPIDM
SPICLK Last Sampling Edge to Data Input Not Valid
Switching Characteristics
tSPICLKM
Serial Clock Cycle
tSPICHM
Serial Clock High Period
tSPICLM
Serial Clock Low Period
tDDSPIDM
SPICLK Edge to Data Out Valid (Data Out Delay Time)
tHDSPIDM
SPICLK Edge to Data Out Not Valid (Data Out Hold Time)
FLAG3–0IN (SPI Device Select) Low to First SPICLK Edge
tSDSCIM
tHDSM
Last SPICLK Edge to FLAG3–0IN High
tSPITDM
Sequential Transfer Delay
Min
Max
8.2
2
ns
ns
8 × TPCLK – 2
4 × tPCLK – 2
4 × tPCLK – 2
ns
ns
ns
ns
ns
ns
ns
ns
2.5
2
4 × tPCLK – 2
4 × tPCLK – 2
4 × tPCLK – 1
FLAG3-0
(OUTPUT)
t SDSCIM
t SPICHM
t SPICLM
t SPICL M
t SPICHM
t SPI CLKM
t HDSM
t SPIT DM
SPICLK
(CP = 0)
(OUTPUT)
SPICLK
(CP = 1)
(OUTPUT)
t HDSPIDM
t D DSPIDM
MOSI
(OUTPUT)
MSB
LSB
t SSPIDM
CPHASE = 1
t SSPIDM
MISO
(INPUT)
MSB
VALID
LSB
VALID
t DDSPIDM
MOSI
(OUTPUT)
CPHASE = 0
MISO
(INPUT)
tHSPIDM
t HSPIDM
t HDSPIDM
MSB
t SSPIDM
LSB
t HSPIDM
MSB
VALID
LSB
VALID
Figure 34. SPI Master Timing
Rev. A |
Page 44 of 56 |
August 2006
Unit
ADSP-21367/ADSP-21368/ADSP-21369
SPI Interface—Slave
Table 42. SPI Interface Protocol—Slave Switching and Timing Specifications
Parameter
Timing Requirements
tSPICLKS
tSPICHS
tSPICLS
tSDSCO
Min
Serial Clock Cycle
Serial Clock High Period
Serial Clock Low Period
SPIDS Assertion to First SPICLK Edge
CPHASE = 0
CPHASE = 1
tHDS
Last SPICLK Edge to SPIDS Not Asserted, CPHASE = 0
tSSPIDS
Data Input Valid to SPICLK Edge (Data Input Setup Time)
tHSPIDS
SPICLK Last Sampling Edge to Data Input Not Valid
tSDPPW
SPIDS Deassertion Pulse Width (CPHASE = 0)
Switching Characteristics
tDSOE
SPIDS Assertion to Data Out Active
tDSDHI
SPIDS Deassertion to Data High Impedance
tDDSPIDS
SPICLK Edge to Data Out Valid (Data Out Delay Time)
tHDSPIDS
SPICLK Edge to Data Out Not Valid (Data Out Hold Time)
tDSOV
SPIDS Assertion to Data Out Valid (CPHASE = 0)
Max
4 × tPCLK – 2
2 × tPCLK – 2
2 × tPCLK – 2
ns
ns
ns
2 × tPCLK
2 × tPCLK
2 × tPCLK
2
2
2 × tPCLK
ns
ns
ns
ns
ns
ns
0
0
6.8
6.8
9.5
2 × tPCLK
5 × tPCLK
SPIDS
(INPUT)
tSPICHS
tSPICLS
tS P I C L K S
tHDS
SPICLK
(CP = 0)
(INPUT)
tSPICLS
tS D S C O
SPICLK
(CP = 1)
(INPUT)
tS D P P W
tSPICHS
tDSD HI
tDDSPIDS
tDSOE
tD D S P I D S
MISO
(OUTPUT)
t H D S P ID S
MSB
LSB
t H S P ID S
tSSPIDS
CPHASE = 1
tSSPIDS
MOSI
(INPUT)
MSB VALID
LSB VALID
tDSOV
MISO
(OUTPUT)
LSB
MSB
CPHASE = 0
MOSI
(INPUT)
t H D S P ID S
tDDSPIDS
tDSOE
t H S P ID S
tSSPIDS
MSB VALID
LSB VALID
Figure 35. SPI Slave Timing
Rev. A |
Page 45 of 56 |
August 2006
Unit
tDSDHI
ns
ns
ns
ns
ns
ADSP-21367/ADSP-21368/ADSP-21369
JTAG Test Access Port and Emulation
Table 43. JTAG Test Access Port and Emulation
Parameter
Timing Requirements
tTCK
TCK Period
tSTAP
TDI, TMS Setup Before TCK High
tHTAP
TDI, TMS Hold After TCK High
tSSYS1
System Inputs Setup Before TCK High
1
tHSYS
System Inputs Hold After TCK High
tTRSTW
TRST Pulse Width
Switching Characteristics
tDTDO
TDO Delay from TCK Low
2
tDSYS
System Outputs Delay After TCK Low
1
2
Min
Max
tCK
5
6
7
18
4tCK
ns
ns
ns
ns
ns
ns
7
tCK ÷ 2 + 7
System Inputs = AD15–0, SPIDS, CLK_CFG1–0, RESET, BOOT_CFG1–0, MISO, MOSI, SPICLK, DAI_Px, FLAG3–0.
System Outputs = MISO, MOSI, SPICLK, DAI_Px, AD15–0, RD, WR, FLAG3–0, CLKOUT, EMU.
tTCK
TCK
tSTAP
tHTAP
TMS
TDI
tDTDO
TDO
tSSYS
tHSYS
SYSTEM
INPUTS
tDSYS
SYSTEM
OUTPUTS
Figure 36. IEEE 1149.1 JTAG Test Access Port
Rev. A |
Page 46 of 56 |
August 2006
Unit
ns
ns
ADSP-21367/ADSP-21368/ADSP-21369
OUTPUT DRIVE CURRENTS
Figure 37 shows typical I-V characteristics for the output drivers of the ADSP-21367/ADSP-21368/ADSP-21369. The curves
represent the current drive capability of the output drivers as a
function of output voltage.
INPUT
1.5V
OR
OUTPUT
1.5V
Figure 39. Voltage Reference Levels for AC Measurements
40
CAPACITIVE LOADING
VOH
3.3V, 25°C
20
3.47V, -45°C
10
3.11V, 125°C
0
-10
Output delays and holds are based on standard capacitive loads:
30 pF on all pins (see Figure 38). Figure 42 shows graphically
how output delays and holds vary with load capacitance. The
graphs of Figure 40, Figure 41, and Figure 42 may not be linear
outside the ranges shown for Typical Output Delay vs. Load
Capacitance and Typical Output Rise Time (20% to 80%,
V = Min) vs. Load Capacitance.
3.11V, 125°C
-20
3.3V, 25°C
12
VOL
-30
3.47V, -45°C
-40
0
0.5
1.0
1.5
2.0
2.5
SWEEP (VDDEXT ) VOLTAGE (V)
3.0
10
3.5
Figure 37. Typical Drive at Junction temperature
TEST CONDITIONS
The ac signal specifications (timing parameters) appear in
Table 15 on Page 23 through Table 43 on Page 46. These include
output disable time, output enable time, and capacitive loading.
The timing specifications for the SHARC apply for the voltage
reference levels in Figure 39.
y = 0.0467x + 1.6323
RISE AND FALL TIMES (ns)
SOURCE (VDDEXT) CURRENT (mA)
30
RISE
FALL
8
6
4
y = 0.045x + 1.524
2
0
0
Timing is measured on signals when they cross the 1.5 V level as
described in Figure 39. All delays (in nanoseconds) are measured between the point that the first signal reaches 1.5 V and
the point that the second signal reaches 1.5 V.
50
100
150
200
250
LOAD CAPACITANCE (pF)
Figure 40. Typical Output Rise/Fall Time (20% to 80%,
VDDEXT = Max)
12
IOL
RISE
50⍀
TO
OUTPUT
PIN
1.5V
+
30pF
IOH
RISE AND FALL TIMES (ns)
10
y = 0.049x + 1.5105
FALL
8
6
y = 0.0482x + 1.4604
4
2
0
0
Figure 38. Equivalent Device Loading for AC Measurements
(Includes All Fixtures)
50
100
150
200
LOAD CAPACITANCE (pF)
Figure 41. Typical Output Rise/Fall Time (20% to 80%,
VDDEXT = Min)
Rev. A |
Page 47 of 56 |
August 2006
250
ADSP-21367/ADSP-21368/ADSP-21369
Values of θJB are provided for package comparison and PCB
design considerations. Note that the thermal characteristics values provided in Table 44 and Table 45 are modeled values.
10
OUTPUT DELAY OR HOLD (ns)
8
Table 44. Thermal Characteristics for 256-Ball SBGA
Y = 0.0488x - 1.5923
6
Parameter
θJA
θJMA
θJMA
θJC
θJB
ΨJT
ΨJMT
ΨJMT
4
2
0
-2
-4
0
50
100
150
200
LOAD CAPACITANCE (pF)
Airflow = 0 m/s
Airflow = 1 m/s
Airflow = 2 m/s
Typical
12.5
10.6
9.9
0.7
5.3
0.3
0.3
0.3
Unit
°C/W
°C/W
°C/W
°C/W
°C/W
°C/W
°C/W
°C/W
Table 45. Thermal Characteristics for 208-Lead MQFP
Figure 42. Typical Output Delay or Hold vs. Load Capacitance
(at Junction Temperature)
THERMAL CHARACTERISTICS
The ADSP-21367/ADSP-21368/ADSP-21369 processors are
rated for performance over the temperature range specified in
Operating Conditions on Page 16.
Table 44 and Table 45 airflow measurements comply with
JEDEC standards JESD51-2 and JESD51-6 and the junction-toboard measurement complies with JESD51-8. Test board design
complies with JEDEC standard JESD51-9 (SBGA) and
JESD51-7 (MQFP). The junction-to-case measurement complies with MIL-STD-883. All measurements use a 2S2P JEDEC
test board.
Parameter
θJA
θJMA
θJMA
θJC
ΨJT
ΨJMT
ΨJMT
To determine the junction temperature of the device while on
the application PCB, use:
T J = T TOP + ( Ψ JT × P D )
where:
TJ = junction temperature (°C)
TTOP = case temperature (°C) measured at the top center of the
package
ΨJT = junction-to-top (of package) characterization parameter
is the typical value from Table 44 and Table 45.
PD = power dissipation (see EE Note EE-299)
Values of θJA are provided for package comparison and PCB
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 (°C)
Values of θJC are provided for package comparison and PCB
design considerations when an external heat sink is required.
This is only applicable when a heat sink is used.
Rev. A |
Condition
Airflow = 0 m/s
Airflow = 1 m/s
Airflow = 2 m/s
Page 48 of 56 |
August 2006
Condition
Airflow = 0 m/s
Airflow = 1 m/s
Airflow = 2 m/s
Airflow = 0 m/s
Airflow = 1 m/s
Airflow = 2 m/s
Typical
25.0
22.5
21.6
9.6
0.7
0.8
0.9
Unit
°C/W
°C/W
°C/W
°C/W
°C/W
°C/W
°C/W
ADSP-21367/ADSP-21368/ADSP-21369
256-BALL SBGA PINOUT
Table 46. 256-Ball SBGA Pin Assignment (Numerically by Ball Number)
Ball No.
A01
A02
A03
A04
A05
A06
A07
A08
A09
A10
A11
A12
A13
A14
A15
A16
A17
A18
A19
A20
E01
E02
E03
E04
E17
E18
E19
E20
J01
J02
J03
J04
Signal
NC
TDI
TMS
CLK_CFG0
CLK_CFG1
EMU
DAI4
DAI1
DPI14
DPI12
DPI10
DPI9
DPI7
DPI6
DPI3
DPI2
CLKOUT
DATA31
NC
NC
DAI11
DAI8
VDDINT
VDDINT
GND
GND
DATA25
DATA23
DAI19
DAI18
GND
GND
Ball No.
B01
B02
B03
B04
B05
B06
B07
B08
B09
B10
B11
B12
B13
B14
B15
B16
B17
B18
B19
B20
F01
F02
F03
F04
F17
F18
F19
F20
K01
K02
K03
K04
Signal
DAI5
SDCLK1
TRST
TCK
BOOT_CFG_0
BOOT_CFG_1
TDO
DAI3
DAI2
DPI13
DPI11
DPI8
DPI5
DPI4
DPI1
RESET
DATA30
DATA29
DATA28
NC
DAI14
DAI12
GND
GND
VDDEXT
GND
GND/ID21
DATA21
FLAG0
DAI20
GND
VDDEXT
Rev. A |
Ball No.
C01
C02
C03
C04
C05
C06
C07
C08
C09
C10
C11
C12
C13
C14
C15
C16
C17
C18
C19
C20
G01
G02
G03
G04
G17
G18
G19
G20
L01
L02
L03
L04
Page 49 of 56 |
Signal
DAI9
DAI7
GND
VDDEXT
GND
GND
VDDINT
GND
GND
VDDINT
GND
GND
VDDINT
GND
GND
VDDINT
VDDINT
VDDINT
DATA27
NC/RPBA1
DAI15
DAI13
GND
VDDEXT
VDDINT
VDDINT
DATA22
DATA20
FLAG2
FLAG1
VDDINT
VDDINT
August 2006
Ball No.
D01
D02
D03
D04
D05
D06
D07
D08
D09
D10
D11
D12
D13
D14
D15
D16
D17
D18
D19
D20
H01
H02
H03
H04
H17
H18
H19
H20
M01
M02
M03
M04
Signal
DAI10
DAI6
GND
VDDEXT
GND
VDDEXT
VDDINT
GND
VDDEXT
VDDINT
GND
VDDEXT
VDDINT
GND
VDDEXT
GND
VDDEXT
GND
DATA26
DATA24
DAI17
DAI16
VDDINT
VDDINT
VDDEXT
GND
DATA19
DATA18
ACK
FLAG3
GND
GND
ADSP-21367/ADSP-21368/ADSP-21369
Table 46. 256-Ball SBGA Pin Assignment (Numerically by Ball Number) (Continued)
Ball No.
J17
J18
J19
J20
N01
N02
N03
N04
N17
N18
N19
N20
U01
U02
U03
U04
U05
U06
U07
U08
U09
U10
U11
U12
U13
U14
U15
U16
U17
U18
U19
U20
1
Signal
GND
GND
GND/ID11
DATA17
RD
SDCLK0
GND
VDDEXT
GND
GND
DATA11
DATA10
MS0
MS1
VDDINT
GND
VDDEXT
GND
VDDEXT
VDDINT
VDDEXT
GND
VDDEXT
VDDINT
VDDEXT
VDDEXT
VDDINT
VDDEXT
VDDINT
VDDINT
DATA0
DATA2
Ball No.
K17
K18
K19
K20
P01
P02
P03
P04
P17
P18
P19
P20
V01
V02
V03
V04
V05
V06
V07
V08
V09
V10
V11
V12
V13
V14
V15
V16
V17
V18
V19
V20
Signal
VDDINT
VDDINT
GND/ID01
DATA16
SDA10
WR
VDDINT
VDDINT
VDDINT
VDDINT
DATA8
DATA9
ADDR22
ADDR23
VDDINT
GND
GND
GND
GND
VDDINT
GND
GND
GND
VDDINT
VDDEXT
GND
VDDINT
GND
GND
GND
DATA1
DATA3
Ball No.
L17
L18
L19
L20
R01
R02
R03
R04
R17
R18
R19
R20
W01
W02
W03
W04
W05
W06
W07
W08
W09
W10
W11
W12
W13
W14
W15
W16
W17
W18
W19
W20
Signal
VDDINT
VDDINT
DATA15
DATA14
SDWE
SDRAS
GND
GND
VDDEXT
GND
DATA6
DATA7
GND
ADDR21
ADDR19
ADDR20
ADDR17
ADDR16
ADDR15
ADDR14
AVDD
AVSS
ADDR13
ADDR12
ADDR10
ADDR8
ADDR5
ADDR4
ADDR1
ADDR2
ADDR0
NC
Applies to ADSP-21368 models only.
Rev. A |
Page 50 of 56 |
August 2006
Ball No.
M17
M18
M19
M20
T01
T02
T03
T04
T17
T18
T19
T20
Y01
Y02
Y03
Y04
Y05
Y06
Y07
Y08
Y09
Y10
Y11
Y12
Y13
Y14
Y15
Y16
Y17
Y18
Y19
Y20
Signal
VDDEXT
GND
DATA12
DATA13
SDCKE
SDCAS
GND
VDDEXT
GND
GND
DATA5
DATA4
GND
NC
NC
ADDR18
NC/BR11
NC/BR21
XTAL2
CLKIN
NC
NC
NC/BR31
NC/BR41
ADDR11
ADDR9
ADDR7
ADDR6
ADDR3
GND
GND
NC
ADSP-21367/ADSP-21368/ADSP-21369
Figure 43 shows the bottom view of the SBGA ball configuration. Figure 44 shows the top view of the SBGA ball
configuration.
2
1
4
6
3
5
8
7
10
9
12
11
14
13
16
15
18
17
20
19
A
B
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
C
D
E
F
G
H
J
1
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
BOTTOM
VIEW
TOP
VIEW
K
L
M
N
P
R
T
U
V
W
Y
KEY
VDDINT
I/O SIGNALS
VDDEXT
GND
AVDD
AVSS
NO CONNECT
KEY
VDDINT
I/O SIGNALS
VDDEXT
GND
AVDD
AVSS
Figure 44. 256-Ball SBGA Ball Configuration (Top View)
NO CONNECT
Figure 43. 256-Ball SBGA Ball Configuration (Bottom View)
Rev. A |
Page 51 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
208-LEAD MQFP PINOUT
Table 47. 208-Lead MQFP Pin Assignment (Numerically by Lead Number)
Pin No.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
Signal
VDD
DATA28
DATA27
GND
VDDEXT
DATA26
DATA25
DATA24
DATA23
GND
VDD
DATA22
DATA21
DATA20
VDDEXT
GND
DATA19
DATA18
VDD
GND
DATA17
VDD
GND
VDD
GND
DATA16
DATA15
DATA14
DATA13
DATA12
VDDEXT
GND
VDD
GND
DATA11
DATA10
DATA9
DATA8
DATA7
DATA6
VDDEXT
GND
VDD
DATA4
Pin No.
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
Signal
VDD
GND
VDDEXT
ADDR0
ADDR2
ADDR1
ADDR4
ADDR3
ADDR5
GND
VDD
GND
VDDEXT
ADDR6
ADDR7
ADDR8
ADDR9
ADDR10
GND
VDD
GND
VDDEXT
ADDR11
ADDR12
ADDR13
GND
VDD
AVSS
AVDD
GND
CLKIN
XTAL2
VDDEXT
GND
VDD
ADDR14
GND
VDDEXT
ADDR15
ADDR16
ADDR17
ADDR18
GND
VDDEXT
Rev. A |
Pin No.
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
Page 52 of 56 |
Signal
VDD
GND
VDDEXT
SDCAS
SDRAS
SDCKE
SDWE
WR
SDA10
GND
VDDEXT
SDCLK0
GND
VDD
RD
ACK
FLAG3
FLAG2
FLAG1
FLAG0
DAI20
GND
VDD
GND
VDDEXT
DAI19
DAI18
DAI17
DAI16
DAI15
DAI14
DAI13
DAI12
VDD
VDDEXT
GND
VDD
GND
DAI11
DAI10
DAI8
DAI9
DAI6
DAI7
August 2006
Pin No.
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
Signal
VDD
VDD
GND
VDD
VDD
VDD
TDI
TRST
TCK
GND
VDD
TMS
CLK_CFG0
BOOT_CFG0
CLK_CFG1
EMU
BOOT_CFG1
TDO
DAI4
DAI2
DAI3
DAI1
VDDEXT
GND
VDD
GND
DPI14
DPI13
DPI12
DPI11
DPI10
DPI9
DPI8
DPI7
VDDEXT
GND
VDD
GND
DPI6
DPI5
DPI4
DPI3
DPI1
DPI2
ADSP-21367/ADSP-21368/ADSP-21369
Table 47. 208-Lead MQFP Pin Assignment (Numerically by Lead Number) (Continued)
Pin No.
45
46
47
48
49
50
51
52
Signal
DATA5
DATA2
DATA3
DATA0
DATA1
VDDEXT
GND
VDD
Pin No.
97
98
99
100
101
102
103
104
Signal
ADDR19
ADDR20
ADDR21
ADDR23
ADDR22
MS1
MS0
VDD
Rev. A |
Pin No.
149
150
151
152
153
154
155
156
Page 53 of 56 |
Signal
DAI5
VDDEXT
GND
VDD
GND
VDD
GND
VDD
August 2006
Pin No.
201
202
203
204
205
206
207
208
Signal
CLKOUT
RESET
VDDEXT
GND
DATA30
DATA31
DATA29
VDD
ADSP-21367/ADSP-21368/ADSP-21369
PACKAGE DIMENSIONS
The ADSP-21367/ADSP-21368/ADSP-21369 processors are
available in 256-ball lead-free and leaded SBGA, and 208-lead
lead-free MQFP packages.
0.75
0.60
0.45
30.85
30.60 SQ
30.35
4.10
MAX
208
157
1
156
SEATING
PLANE
PIN 1 INDICATOR
28.20
28.00 SQ
27.80
TOP VIEW
(PINS DOWN)
3.60
3.40
3.20
0.50
0.25
VIEW A
53
0.50
BSC
(LEAD PITCH)
0.08 MAX (LEAD
COPLANARITY)
VIEW A
ROTATED 90° CCW
105
104
52
0.20
0.09
0.27
0.17
(LEAD WIDTH)
NOTES:
1. THE ACTUAL POSITION OF EACH LEAD IS WITHIN 0.08 FROM ITS IDEAL
POSITION WHEN MEASURED IN THE LATERAL DIRECTION.
2. CENTER DIMENSIONS ARE NOMINAL.
3. DIMENSIONS ARE IN MILLIMETERS AND COMPLY WITH JEDEC STANDARD
MS-029, FA-1.
Figure 45. 208-Lead MQFP (S-208-2)
Rev. A |
Page 54 of 56 |
August 2006
ADSP-21367/ADSP-21368/ADSP-21369
A1 CORNER
INDEX AREA
20 18 16 14 12 10 8
6 4
2
19 17 15 13 11 9 7
5
3
1
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
A1 BALL
INDICATOR
BOTTOM
VIEW
27.00
BSC SQ
TOP VIEW
24.13
REF SQ
DETAIL A
1.27
NOM
1.00
0.80
0.60
0.70
0.60
0.50
1.70 MAX
DETAIL A
0.10
MIN
0.20
COPLANARITY
SEATING
PLANE
DIMENSIONS ARE IN MILLIMETERS AND COMPLY
WITH JEDEC STANDARDS MO-192-BAL-2.
BALL
DIAMETER
0.90
0.75
0.60
0.25 MIN 4⫻
Figure 46. 256-Ball SBGA, Thermally Enhanced (BP-256)
SURFACE-MOUNT DESIGN
Table 48 is provided as an aide to PCB design. For industrystandard design recommendations, refer to IPC-7351, Generic
Requirements for Surface-Mount Design and Land Pattern
Standard.
Table 48. SBGA Data for Use with Surface-Mount Design
Package
256-Lead Ball Grid Array SBGA
(BP-256)
Ball Attach Type
Solder Mask Defined (SMD)
Rev. A |
Page 55 of 56 |
Solder Mask Opening
0.63
August 2006
Ball Pad Size
0.73
ADSP-21367/ADSP-21368/ADSP-21369
ORDERING GUIDE
Part Number
ADSP-21367KSZ-1A2, 3
3
ROM
Operating
Voltage
Package
Internal/External Description
Package
Option
2M bit
6M bit
1.2 V/3.3 V
208-Lead MQFP
S-208-2
Temperature
Range 1
Instruction On-Chip
Rate
SRAM
0°C to +70°C
266 MHz
0°C to +70°C
333 MHz
2M bit
6M bit
1.3 V/3.3 V
256-Ball SBGA
BP-256
ADSP-21367KBPZ-2A2, 3
0°C to +70°C
333 MHz
2M bit
6M bit
1.3 V/3.3 V
256-Ball SBGA
BP-256
ADSP-21367BBP-2A
–40°C to +85°C
333 MHz
2M bit
6M bit
1.3 V/3.3 V
256-Ball SBGA
BP-256
–40°C to +85°C
333 MHz
2M bit
6M bit
1.3 V/3.3 V
256-Ball SBGA
BP-256
0°C to +70°C
333 MHz
2M bit
6M bit
1.3 V/3.3 V
256-Ball SBGA
BP-256
ADSP-21367KBP-2A
ADSP-21367BBPZ-2A
2
ADSP-21368KBP-2A
ADSP-21368KBPZ-2A
2
ADSP-21368BBP-2A
ADSP-21368BBPZ-2A
2
ADSP-21369KSZ-1A2
ADSP-21369KBP-2A
ADSP-21369KBPZ-2A
2
ADSP-21369BBP-2A
ADSP-21369BBPZ-2A
2
0°C to +70°C
333 MHz
2M bit
6M bit
1.3 V/3.3 V
256-Ball SBGA
BP-256
–40°C to +85°C
333 MHz
2M bit
6M bit
1.3 V/3.3 V
256-Ball SBGA
BP-256
–40°C to +85°C
333 MHz
2M bit
6M bit
1.3 V/3.3 V
256-Ball SBGA
BP-256
0°C to +70°C
266 MHz
2M bit
6M bit
1.2 V/3.3 V
208-Lead MQFP
S-208-2
0°C to +70°C
333 MHz
2M bit
6M bit
1.3 V/3.3 V
256-Ball SBGA
BP-256
0°C to +70°C
333 MHz
2M bit
6M bit
1.3 V/3.3 V
256-Ball SBGA
BP-256
–40°C to +85°C
333 MHz
2M bit
6M bit
1.3 V/3.3 V
256-Ball SBGA
BP-256
–40°C to +85°C
333 MHz
2M bit
6M bit
1.3 V/3.3 V
256-Ball SBGA
BP-256
1
Referenced temperature is ambient temperature.
2
Z = Pb-free part.
3
Available with a wide variety of audio algorithm combinations sold as part of a chipset and bundled with necessary software. For a complete list, visit our website at
www.analog.com/SHARC.
©2006 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D05267-0-8/06(A)
Rev. A |
Page 56 of 56 |
August 2006