AD ADSP-21020BG-100

a
FEATURES
Superscalar IEEE Floating-Point Processor
Off-Chip Harvard Architecture Maximizes Signal
Processing Performance
30 ns, 33.3 MIPS Instruction Rate, Single-Cycle
Execution
100 MFLOPS Peak, 66 MFLOPS Sustained Performance
1024-Point Complex FFT Benchmark: 0.58 ms
Divide (y/x): 180 ns
Inverse Square Root (1/√x): 270 ns
32-Bit Single-Precision and 40-Bit Extended-Precision
IEEE Floating-Point Data Formats
32-Bit Fixed-Point Formats, Integer and Fractional,
with 80-Bit Accumulators
IEEE Exception Handling with Interrupt on Exception
Three Independent Computation Units: Multiplier,
ALU, and Barrel Shifter
Dual Data Address Generators with Indirect, Immediate, Modulo, and Bit Reverse Addressing Modes
Two Off-Chip Memory Transfers in Parallel with
Instruction Fetch and Single-Cycle Multiply & ALU
Operations
Multiply with Add & Subtract for FFT Butterfly
Computation
Efficient Program Sequencing with Zero-Overhead
Looping: Single-Cycle Loop Setup
Single-Cycle Register File Context Switch
15 (or 25) ns External RAM Access Time for Zero-WaitState, 30 (or 40) ns Instruction Execution
IEEE JTAG Standard 1149.1 Test Access Port and
On-Chip Emulation Circuitry
223-Pin PGA Package (Ceramic)
GENERAL DESCRIPTION
32/40-Bit IEEE Floating-Point
DSP Microprocessor
ADSP-21020
FUNCTIONAL BLOCK DIAGRAM
DATA ADDRESS
GENERATORS
DAG 1
The ADSP-21020 features:
•
Independent Parallel Computation Units
The arithmetic/logic unit (ALU), multiplier and shifter
perform single-cycle instructions. The units are architecturally
arranged in parallel, maximizing computational throughput. A
single multifunction instruction executes parallel ALU and
PROGRAM
SEQUENCER
JTAG TEST
& EMULATION
PROGRAM MEMORY ADDRESS
DATA MEMORY ADDRESS
PROGRAM MEMORY DATA
DATA MEMORY DATA
REGISTER FILE
EXTERNAL
ADDRESS
BUSES
EXTERNAL
DATA
BUSES
TIMER
ARITHMETIC UNITS
ALU
MULTIPLIER
SHIFTER
multiplier operations. These computation units support IEEE
32-bit single-precision floating-point, extended precision
40-bit floating-point, and 32-bit fixed-point data formats.
•
Data Register File
•
Single-Cycle Fetch of Instruction and Two Operands
•
Memory Interface
The ADSP-21020 is the first member of Analog Devices’ family
of single-chip IEEE floating-point processors optimized for
digital signal processing applications. Its architecture is similar
to that of Analog Devices’ ADSP-2100 family of fixed-point
DSP processors.
Fabricated in a high-speed, low-power CMOS process, the
ADSP-21020 has a 30 ns instruction cycle time. With a highperformance on-chip instruction cache, the ADSP-21020 can
execute every instruction in a single cycle.
DAG 2
INSTRUCTION
CACHE
A general-purpose data register file is used for transferring
data between the computation units and the data buses, and
for storing intermediate results. This 10-port (16-register)
register file, combined with the ADSP-21020’s Harvard
architecture, allows unconstrained data flow between
computation units and off-chip memory.
The ADSP-21020 uses a modified Harvard architecture in
which data memory stores data and program memory stores
both instructions and data. Because of its separate program
and data memory buses and on-chip instruction cache, the
processor can simultaneously fetch an operand from data
memory, an operand from program memory, and an
instruction from the cache, all in a single cycle.
Addressing of external memory devices by the ADSP-21020 is
facilitated by on-chip decoding of high-order address lines to
generate memory bank select signals. Separate control lines
are also generated for simplified addressing of page-mode
DRAM.
The ADSP-21020 provides programmable memory wait
states, and external memory acknowledge controls allow
interfacing to peripheral devices with variable access times.
REV. C
Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices for its
use, nor for any infringements of patents or other rights of third parties
which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Analog Devices.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 617/329-4700
Fax: 617/326-8703
ADSP-21020
•
•
•
Instruction Cache
The ADSP-21020 includes a high performance instruction
cache that enables three-bus operation for fetching an
instruction and two data values. The cache is selective—only
the instructions whose fetches conflict with program memory
data accesses are cached. This allows full-speed execution
of core, looped operations such as digital filter multiplyaccumulates and FFT butterfly processing.
•
C Source Level Debugger
•
Numerical C Compiler
•
ADSP-21020 EZ-LAB® Evaluation Board
•
ADSP-21020 EZ-ICE® Emulator
Hardware Circular Buffers
The ADSP-21020 provides hardware to implement circular
buffers in memory, which are common in digital filters and
Fourier transform implementations. It handles address
pointer wraparound, reducing overhead (thereby increasing
performance) and simplifying implementation. Circular
buffers can start and end at any location.
Flexible Instruction Set
The ADSP-21020’s 48-bit instruction word accommodates a
variety of parallel operations, for concise programming. For
example, the ADSP-21020 can conditionally execute a
multiply, an add, a subtract and a branch in a single
instruction.
DEVELOPMENT SYSTEM
The ADSP-21020 is supported with a complete set of software
and hardware development tools. The ADSP-21000 Family
Development System includes development software, an
evaluation board and an in-circuit emulator.
•
Assembler
Creates relocatable, COFF (Common Object File Format)
object files from ADSP-21xxx assembly source code. It
accepts standard C preprocessor directives for conditional
assembly and macro processing. The algebraic syntax of the
ADSP-21xxx assembly language facilitates coding and
debugging of DSP algorithms.
•
Linker/Librarian
•
Simulator
•
•
The Linker processes separately assembled object files and
library files to create a single executable program. It assigns
memory locations to code and to data in accordance with a
user-defined architecture file that describes the memory and
I/O configuration of the target system. The Librarian allows
you to group frequently used object files into a single library
file that can be linked with your main program.
The Simulator performs interactive, instruction-level
simulation of ADSP-21xxx code within the hardware
configuration described by a system architecture file. It flags
illegal operations and supports full symbolic disassembly. It
provides an easy-to-use, window oriented, graphical user
interface that is identical to the one used by the ADSP-21020
EZ-ICE Emulator. Commands are accessed from pull-down
menus with a mouse.
PROM Splitter
Formats an executable file into files that can be used with an
industry-standard PROM programmer.
C Compiler and Runtime Library
The C Compiler complies with ANSI specifications. It takes
advantage of the ADSP-21020’s high-level language architectural features and incorporates optimizing algorithms to speed
up the execution of code. It includes an extensive runtime
library with over 100 standard and DSP-specific functions.
A full-featured C source level debugger that works with the
simulator or EZ-ICE emulator to allow debugging of
assembler source, C source, or mixed assembler and C.
Supports ANSI Standard (X3J11.1) Numerical C as defined
by the Numeric C Extensions Group. The compiler accepts C
source input containing Numerical C extensions for array
selection, vector math operations, complex data types,
circular pointers, and variably dimensioned arrays, and
outputs ADSP-21xxx assembly language source code.
The EZ-LAB Evaluation Board is a general-purpose, standalone ADSP-21020 system that includes 32K words of
program memory and 32K words of data memory as well as
analog I/O. A PC RS-232 download path enables the user to
download and run programs directly on the EZ-LAB. In
addition, it may be used in conjunction with the EZ-ICE
Emulator to provide a powerful software debug environment.
This in-circuit emulator provides the system designer with a
PC-based development environment that allows nonintrusive
access to the ADSP-21020’s internal registers through the
processor’s 5-pin JTAG Test Access Port. This use of on-chip
emulation circuitry enables reliable, full-speed performance in
any target. The emulator uses the same graphical user interface as the ADSP-21020 Simulator, allowing an easy transition from software to hardware debug. (See “Target System
Requirements for Use of EZ-ICE Emulator” on page 27.)
ADDITIONAL INFORMATION
This data sheet provides a general overview of ADSP-21020
functionality. For additional information on the architecture and
instruction set of the processor, refer to the ADSP-21020 User’s
Manual. For development system and programming reference
information, refer to the ADSP-21000 Family Development
Software Manuals and the ADSP-21020 Programmer’s Quick
Reference. Applications code listings and benchmarks for key
DSP algorithms are available on the DSP Applications BBS; call
(617) 461-4258, 8 data bits, no parity, 1 stop bit, 300/1200/
2400/9600 baud.
ARCHITECTURE OVERVIEW
Figure 1 shows a block diagram of the ADSP-21020. The
processor features:
•
•
•
•
•
•
Three Computation Units (ALU, Multiplier, and Shifter)
with a Shared Data Register File
Two Data Address Generators (DAG 1, DAG 2)
Program Sequencer with Instruction Cache
32-Bit Timer
Memory Buses and Interface
JTAG Test Access Port and On-Chip Emulation Support
Computation Units
The ADSP-21020 contains three independent computation
units: an ALU, a multiplier with fixed-point accumulator, and a
shifter. In order to meet a wide variety of processing needs, the
computation units process data in three formats: 32-bit
fixed-point, 32-bit floating-point and 40-bit floating-point. The
floating-point operations are single-precision IEEE-compatible
(IEEE Standard 754/854). The 32-bit floating-point format is
EZ-LAB and EZ-ICE are registered trademarks of Analog Devices, Inc.
–2–
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ADSP-21020
CACHE
MEMORY
32 x 48
DAG 1
8 x 4 x 32
JTAG TEST &
EMULATION
FLAGS
DAG 2
8 x 4 x 24
PROGRAM
SEQUENCER
PMA BUS
24
DMA BUS
32
TIMER
PMA
DMA
PMD BUS
48
PMD
BUS CONNECT
DMD BUS
40
DMD
FLOATING & FIXED-POINT
MULTIPLIER, FIXED-POINT
ACCUMULATOR
REGISTER
FILE
16 x 40
32-BIT
BARREL
SHIFTER
FLOATING-POINT
& FIXED-POINT
ALU
Figure 1. ADSP-21020 Block Diagram
of the ADSP-21020 allow the following nine data transfers to be
performed every cycle:
the standard IEEE format, whereas the 40-bit IEEE extendedprecision format has eight additional LSBs of mantissa for
greater accuracy.
•
•
•
•
The multiplier performs floating-point and fixed-point
multiplication as well as fixed-point multiply/add and multiply/
subtract operations. Integer products are 64 bits wide, and the
accumulator is 80 bits wide. The ALU performs 45 standard
arithmetic and logic operations, supporting both fixed-point and
floating-point formats. The shifter performs 19 different
operations on 32-bit operands. These operations include logical
and arithmetic shifts, bit manipulation, field deposit, and extract
and derive exponent operations.
The processor’s 48-bit orthogonal instruction word supports
fully parallel data transfer and arithmetic operations in the same
instruction.
Address Generators and Program Sequencer
Two dedicated address generators and a program sequencer
supply addresses for memory accesses. Because of this, the
computation units need never be used to calculate addresses.
Because of its instruction cache, the ADSP-21020 can
simultaneously fetch an instruction and data values from both
off-chip program memory and off-chip data memory in a single
cycle.
The computation units perform single-cycle operations; there is
no computation pipeline. The three units are connected in
parallel rather than serially, via multiple-bus connections with
the 10-port data register file. The output of any computation
unit may be used as the input of any unit on the next cycle. In a
multifunction computation, the ALU and multiplier perform
independent, simultaneous operations.
The data address generators (DAGs) provide memory addresses
when external memory data is transferred over the parallel
memory ports to or from internal registers. Dual data address
generators enable the processor to output two simultaneous
addresses for dual operand reads and writes. DAG 1 supplies
32-bit addresses to data memory. DAG 2 supplies 24-bit
addresses to program memory for program memory data
accesses.
Data Register File
The ADSP-21020’s general-purpose data register file is used for
transferring data between the computation units and the data
buses, and for storing intermediate results. The register file has
two sets (primary and alternate) of sixteen 40-bit registers each,
for fast context switching.
With a large number of buses connecting the registers to the
computation units, data flow between computation units and
from/to off-chip memory is unconstrained and free from
bottlenecks. The 10-port register file and Harvard architecture
REV. C
Off-chip read/write of two operands to or from the register file
Two operands supplied to the ALU
Two operands supplied to the multiplier
Two results received from the ALU and multiplier (three, if
the ALU operation is a combined addition/subtraction)
Each DAG keeps track of up to eight address pointers, eight
modifiers, eight buffer length values and eight base values. A
pointer used for indirect addressing can be modified by a value
–3–
ADSP-21020
in a specified register, either before (premodify) or after
(postmodify) the access. To implement automatic modulo
addressing for circular buffers, the ADSP-21020 provides buffer
length registers that can be associated with each pointer. Base
values for pointers allow circular buffers to be placed at arbitrary
locations. Each DAG register has an alternate register that can
be activated for fast context switching.
The program sequencer supplies instruction addresses to
program memory. It controls loop iterations and evaluates
conditional instructions. To execute looped code with zero
overhead, the ADSP-21020 maintains an internal loop counter
and loop stack. No explicit jump or decrement instructions are
required to maintain the loop.
The ADSP-21020 derives its high clock rate from pipelined
fetch, decode and execute cycles. Approximately 70% of the
machine cycle is available for memory accesses; consequently,
ADSP-21020 systems can be built using slower and therefore
less expensive memory chips.
Instruction Cache
The program sequencer includes a high performance, selective
instruction cache that enables three-bus operation for fetching
an instruction and two data values. This two-way, set-associative
cache holds 32 instructions. The cache is selective—only the
instructions whose fetches conflict with program memory data
accesses are cached, so the ADSP-21020 can perform a program
memory data access and can execute the corresponding instruction
in the same cycle. The program sequencer fetches the instruction
from the cache instead of from program memory, enabling the
ADSP-21020 to simultaneously access data in both program
memory and data memory.
Context Switching
Many of the ADSP-21020’s registers have alternate register sets
that can be activated during interrupt servicing to facilitate a fast
context switch. The data registers in the register file, DAG
registers and the multiplier result register all have alternate sets.
Registers active at reset are called primary registers; the others
are called alternate registers. Bits in the MODE1 control register
determine which registers are active at any particular time.
The primary/alternate select bits for each half of the register file
(top eight or bottom eight registers) are independent. Likewise,
the top four and bottom four register sets in each DAG have
independent primary/ alternate select bits. This scheme allows
passing of data between contexts.
Interrupts
The ADSP-21020 has four external hardware interrupts, nine
internally generated interrupts, and eight software interrupts.
For the external interrupts and the internal timer interrupt, the
ADSP-21020 automatically stacks the arithmetic status and
mode (MODE1) registers when servicing the interrupt, allowing
five nesting levels of fast service for these interrupts.
An interrupt can occur at any time while the ADSP-21020 is
executing a program. Internal events that generate interrupts
include arithmetic exceptions, which allow for fast trap handling
and recovery.
Timer
The programmable interval timer provides periodic interrupt
generation. When enabled, the timer decrements a 32-bit count
register every cycle. When this count register reaches zero, the
ADSP-21020 generates an interrupt and asserts its TIMEXP
output. The count register is automatically reloaded from a
32-bit period register and the count resumes immediately.
System Interface
Figure 2 shows an ADSP-21020 basic system configuration.
The external memory interface supports memory-mapped
peripherals and slower memory with a user-defined combination
of programmable wait states and hardware acknowledge signals.
Both the program memory and data memory interfaces support
addressing of page-mode DRAMs.
The ADSP-21020’s internal functions are supported by four
internal buses: the program memory address (PMA) and data
memory address (DMA) buses are used for addresses associated
with program and data memory. The program memory data
(PMD) and data memory data (DMD) buses are used for data
associated with the two memory spaces. These buses are
extended off chip. Four data memory select (DMS) signals
select one of four user-configurable banks of data memory.
Similarly, two program memory select (PMS) signals select
between two user-configurable banks of program memory. All
banks are independently programmable for 0-7 wait states.
The PX registers permit passing data between program memory
and data memory spaces. They provide a bridge between the
48-bit PMD bus and the 40-bit DMD bus or between the 40-bit
register file and the PMD bus.
The PMA bus is 24 bits wide allowing direct access of up to
16M words of mixed instruction code and data. The PMD is 48
bits wide to accommodate the 48-bit instruction width. For
access of 40-bit data the lower 8 bits are unused. For access of
32-bit data the lower 16 bits are ignored.
The DMA bus is 32 bits wide allowing direct access of up to 4
Gigawords of data. The DMD bus is 40 bits wide. For 32-bit
data, the lower 8 bits are unused. The DMD bus provides a
path for the contents of any register in the processor to be
transferred to any other register or to any external data memory
location in a single cycle. The data memory address comes from
one of two sources: an absolute value specified in the instruction
code (direct addressing) or the output of a data address
generator (indirect addressing).
External devices can gain control of the processor’s memory
buses from the ADSP-21020 by means of the bus request/grant
signals (BR and BG). To grant its buses in response to a bus
request, the ADSP-21020 halts internal operations and places
its program and data memory interfaces in a high impedance
state. In addition, three-state controls (DMTS and PMTS)
allow an external device to place either the program or data
memory interface in a high impedance state without affecting
the other interface and without halting the ADSP-21020 unless
it requires a memory access from the affected interface. The
three-state controls make it easy for an external cache controller
to hold the ADSP-21020 off the bus while it updates an external
cache memory.
JTAG Test and Emulation Support
The ADSP-21020 implements the boundary scan testing
provisions specified by IEEE Standard 1149.1 of the Joint
Testing Action Group (JTAG). The ADSP-21020’s test
access port and on-chip JTAG circuitry is fully compliant with
the IEEE 1149.1 specification. The test access port enables
boundary scan testing of circuitry connected to the
ADSP-21020’s I/O pins.
–4–
REV. C
ADSP-21020
1×
CLOCK
4
CLKIN
PROGRAM
MEMORY
RESET
2
SELECTS
IRQ3-0
DMS3-0
PMS1-0
OE
WE
24
ADDR
PMRD
DMRD
PMWR
PMA
DMWR
DMA
48
DMD
PMD
DATA
4
SELECTS
OE
DATA
MEMORY
WE
32
ADDR
32
DATA
ADSP-21010
PMTS
PMACK
OE
WE
ACK
4
PERIPHERALS
ADDR
JTAG
FLAG3-0
RCOMP
TIMEXP
DMACK
BG
BR
SELECTS
DMTS
DMPAGE
PMPAGE
DATA
5
Figure 2. Basic System Configuration
The ADSP-21020 also implements on-chip emulation through
the JTAG test access port. The processor’s eight sets of breakpoint range registers enable program execution at full speed
until reaching a desired break-point address range. The
processor can then halt and allow reading/writing of all the
processor’s internal registers and external memories through the
JTAG port.
Pin
Name
Type Function
PMPAGE O
PIN DESCRIPTIONS
This section describes the pins of the ADSP-21020. When
groups of pins are identified with subscripts, e.g. PMD47–0, the
highest numbered pin is the MSB (in this case, PMD47). Inputs
identified as synchronous (S) must meet timing requirements
with respect to CLKIN (or with respect to TCK for TMS, TDI,
and TRST). Those that are asynchronous (A) can be asserted
asynchronously to CLKIN.
PMTS
I/S
DMA31–0
O
DMD39–0
I/O
DMS3–0
O
DMRD
O
DMWR
O
DMACK
I/S
O = Output; I = Input; S = Synchronous; A = Asynchronous;
P = Power Supply; G = Ground.
Pin
Name
Type
PMA23–0 O
PMD47–0 I/O
PMS1–0
O
PMRD
O
PMWR
O
PMACK I/S
REV. C
Function
Program Memory Address. The ADSP-21020
outputs an address in program memory on
these pins.
Program Memory Data. The ADSP-21020
inputs and outputs data and instructions on
these pins. 32-bit fixed-point data and 32-bit
single-precision floating-point data is transferred over bits 47-16 of the PMD bus.
Program Memory Select lines. These pins are
asserted as chip selects for the corresponding
banks of program memory. Memory banks
must be defined in the memory control
registers. These pins are decoded program
memory address lines and provide an early
indication of a possible bus cycle.
Program Memory Read strobe. This pin is
asserted when the ADSP-21020 reads from
program memory.
Program Memory Write strobe. This pin is
asserted when the ADSP-21020 writes to
program memory.
Program Memory Acknowledge. An external
device deasserts this input to add wait states
to a memory access.
–5–
Program Memory Page Boundary. The
ADSP-21020 asserts this pin to signal that a
program memory page boundary has been
crossed. Memory pages must be defined in
the memory control registers.
Program Memory Three-State Control.
PMTS places the program memory address,
data, selects, and strobes in a highimpedance state. If PMTS is asserted while
a PM access is occurring, the processor will
halt and the memory access will not be
completed. PMACK must be asserted for at
least one cycle when PMTS is deasserted to
allow any pending memory access to complete properly. PMTS should only be
asserted (low) during an active memory
access cycle.
Data Memory Address. The ADSP-21020
outputs an address in data memory on these
pins.
Data Memory Data. The ADSP-21020
inputs and outputs data on these pins.
32-bit fixed point data and 32-bit
single-precision floating point data is
transferred over bits 39-8 of the DMD bus.
Data Memory Select lines. These pins are
asserted as chip selects for the corresponding banks of data memory. Memory banks
must be defined in the memory control
registers. These pins are decoded data
memory address lines and provide an early
indication of a possible bus cycle.
Data Memory Read strobe. This pin is
asserted when the ADSP-21020 reads from
data memory.
Data Memory Write strobe. This pin is
asserted when the ADSP-21020 writes to
data memory.
Data Memory Acknowledge. An external
device deasserts this input to add wait states
to a memory access.
ADSP-21020
Pin
Name
Type Function
DMPAGE O
DMTS
CLKIIN
RESET
IRQ3–0
FLAG3–0
BR
BG
TIMEXP
RCOMP
EVDD
EGND
Data Memory Page Boundary. The ADSP21020 asserts this pin to signal that a data
memory page boundary has been crossed.
Memory pages must be defined in the
memory control registers.
I/S
Data Memory Three-State Control. DMTS
places the data memory address, data,
selects, and strobes in a high-impedance
state. If DMTS is asserted while a DM
access is occurring, the processor will halt
and the memory access will not be
completed. DMACK must be asserted for
at least one cycle when DMTS is
deasserted to allow any pending memory
access to complete properly. DMTS should
only be asserted (low) during an active
memory access cycle.
I
External clock input to the ADSP-21020.
The instruction cycle rate is equal to
CLKIN. CLKIN may not be halted,
changed, or operated below the specified
frequency.
I/A
Sets the ADSP-21020 to a known state and
begins execution at the program memory
location specified by the hardware reset
vector (address). This input must be
asserted (low) at power-up.
I/A
Interrupt request lines; may be either edge
triggered or level-sensitive.
I/O/A External Flags. Each is configured via
control bits as either an input or output. As
an input, it can be tested as a condition. As
an output, it can be used to signal external
peripherals.
I/A
Bus Request. Used by an external device to
request control of the memory interface.
When BR is asserted, the processor halts
execution after completion of the current
cycle, places all memory data, addresses,
selects, and strobes in a high-impedance
state, and asserts BG. The processor
continues normal operation when BR is
released.
O
Bus Grant. Acknowledges a bus request
(BR), indicating that the external device
may take control of the memory interface.
BG is asserted (held low) until BR is
released.
O
Timer Expired. Asserted for four cycles
when the value of TCOUNT is
decremented to zero.
Compensation Resistor input. Controls
compensated output buffers. Connect
RCOMP through a 1.8 kΩ ± 15% resistor
to EVDD. Use of a capacitor (approximately 100 pF), placed in parallel with the
1.8 kΩ resistor is recommended.
P
Power supply (for output drivers),
nominally +5 V dc (10 pins).
G
Power supply return (for output drivers);
(16 pins).
Pin
Name
Type
Function
IVDD
P
IGND
G
TCK
I
TMS
I/S
TDI
VS
TDO
O
TRST
I/A
Power supply (for internal circuitry),
nominally +5 V dc (4 pins).
Power supply return (for internal circuitry); (7
pins).
Test Clock. Provides an asynchronous clock
for JTAG boundary scan.
Test Mode Select. Used to control the test
state machine. TMS has a 20 kΩ internal
pullup resistor.
Test Data Input. Provides serial data for the
boundary scan logic. TDI has a 20 kΩ internal
pullup resistor.
Test Data Output. Serial scan output of the
boundary scan path.
Test Reset. Resets the test state machine.
TRST must be asserted (pulsed low) after
power-up or held low for proper operation of
the ADSP-21020. TRST has a 20 kΩ internal
pullup resistor.
No Connect. No Connects are reserved pins
that must be left open and unconnected.
NC
INSTRUCTION SET SUMMARY
The ADSP-21020 instruction set provides a wide variety of
programming capabilities. Every instruction assembles into a
single word and can execute in a single processor cycle.
Multifunction instructions enable simultaneous multiplier and
ALU operations, as well as computations executed in parallel
with data transfers. The addressing power of the ADSP-21020
gives you flexibility in moving data both internally and
externally. The ADSP-21020 assembly language uses an
algebraic syntax for ease of coding and readability.
The instruction types are grouped into four categories:
Compute and Move or Modify
Program Flow Control
Immediate Move
Miscellaneous
The instruction types are numbered; there are 22 types. Some
instructions have more than one syntactical form; for example,
Instruction 4 has four distinct forms. The instruction number
itself has no bearing on programming, but corresponds to the
opcode recognized by the ADSP-21020 device.
Because of the width and orthogonality of the instruction word,
there are many possible instructions. For example, the ALU
supports 21 fixed-point operations and 24 floating-point
operations; each of these operations can be the compute portion
of an instruction.
The following pages provide an overview and summary of the
ADSP-21020 instruction set. For complete information, see the
ADSP-21020 User’s Manual. For additional reference information, see the ADSP-21020 Programmer’s Quick Reference.
This section also contains several reference tables for using the
instruction set.
• Table I describes the notation and abbreviations used.
• Table II lists all condition and termination code mnemonics.
• Table III lists all register mnemonics.
• Tables IV through VII list the syntax for all compute
(ALU, multiplier, shifter or multifunction) operations.
• Table VIII lists interrupts and their vector addresses.
–6–
REV. C
ADSP-21020
COMPUTE AND MOVE OR MODIFY INSTRUCTIONS
1.
compute,
|DM(Ia, Mb) = dreg1|
|dreg1 = DM(Ia, Mb)|
|PM(Ic, Md) = dreg2|
|dreg2 = PM(Ic, Md)|
,
2.
IF condition
compute;
3a.
IF condition
compute,
3b.
IF condition
compute,
3c.
IF condition
compute,
3d.
IF condition
compute,
4a.
IF condition
compute,
4b.
IF condition
compute,
4c.
IF condition
compute,
4d.
IF condition
compute,
5.
IF condition
compute,
ureg1 = ureg2 ;
6a.
IF condition
shiftimm,
6b.
IF condition
shiftimm,
7.
IF condition
compute,
7.
IF condition
compute,
|DM(Ia, Mb)| = dreg ;
|PM(Ic, Md) |
dreg = |DM(Ia, Mb)| ;
|PM(Ic, Md) |
MODIFY |(Ia, Mb) | ;
MODIFY |(Ic, Md) |
|DM(Ia, Mb)| = ureg ;
|PM(Ic, Md) |
|DM(Mb, Ia)| = ureg ;
|PM(Md, Ic) |
ureg = |DM(Ia, Mb) | ;
|PM(Ic, Md) |
ureg = |DM(Mb, Ia) | ;
|PM(Md, Ic) |
|DM(Ia, <data6>)| = dreg ;
|PM(Ic, <data6>) |
|DM(<data6>, Ia)| = dreg ;
|PM(<data6>, Ic) |
dreg = |DM(Ia, <data6>) | ;
|PM(Ic, <data6>) |
dreg = |DM(<data6>, Ia)| ;
|PM(<data6>, Ic) |
PROGRAM FLOW CONTROL INSTRUCTIONS
8.
IF condition
9.
IF condition
11.
IF condition
12.
LCNTR =
12.
LCNTR =
13.
LCNTR =
12.
LCNTR =
|JUMP |
|CALL |
|CALL|
|JUMP |
|CALL |
|CALL|
|<addr24>
|
|(PC, <reladdr6>) |
|(PC, <reladdr6>) |
|(Md, Ic)
|
|(PC, <reladdr6>) |
|(PC, <reladdr6>) |
(|DB
(|LA,
|
( DB, LA
|) ;
|
|
(|DB
(|LA,
|
( DB, LA
|)
|
|
|RTS | (|DB, |) , compute ;
|RTI | (|LA, |
|
|
|RTI |
( DB, LA
|<data16> | , DO |<addr24>
|
|ureg
| , DO |(<PC, <reladdr24>)( |
|<data16> | , DO |<addr24>
|
|ureg
| , DO |(|(PC, <reladdr24>) |
(DB) Delayed branch
(LA) Loop abort (pop loop PC stacks on branch)
REV. C
–7–
, compute ;
UNTIL LCE ;
UNTIL LCE ;
UNTIL termination ;
;
ADSP-21020
IMMEDIATE MOVE INSTRUCTIONS
Table II. Condition and Termination Codes
14a. DM(<addr32>) = ureg ;
PM(<addr24>)
Name
Description
14b. ureg =
eq
ne
ge
lt
le
gt
ac
not ac
av
not av
mv
not mv
ms
not ms
sv
not sv
sz
not sz
flag0_in
not flag0_in
flag1_in
not flag1_in
flag2_in
not flag2_in
flag3_in
not flag3_in
tf
not tf
lce
not lce
forever
true
ALU equal to zero
ALU not equal to zero
ALU greater than or equal to zero
ALU less than zero
ALU less than or equal to zero
ALU greater than zero
ALU carry
Not ALU carry
ALU overflow
Not ALU overflow
Multiplier overflow
Not multiplier overflow
Multiplier sign
Not multiplier sign
Shifter overflow
Not shifter overflow
Shifter zero
Not shifter zero
Flag 0
Not Flag 0
Flag 1
Not Flag l
Flag 2
Not Flag 2
Flag 3
Not Flag 3
Bit test flag
Not bit test flag
Loop counter expired (DO UNTIL)
Loop counter not expired (IF)
Always False (DO UNTIL)
Always True (IF)
DM(<addr32>) ;
PM(<addr24>)
15a. DM(<data32>, Ia) = ureg;
PM(< data24>, Ic)
15b. ureg =
DM(<data32>, Ia) ;
PM(<data24>, Ic)
16. DM(Ia, Mb) = <data32>;
PM(Ic, Md)
17. ureg = <data32>;
MISCELLANEOUS INSTRUCTIONS
18. BIT
SET
CLR
TGL
TST
XOR
sreg <data32>;
19a. MODIFY
(Ia, <data32>)|;
(Ic, <data32>)|
19b. BITREV
(Ia, <data32>) ;
20. |PUSH
|POP
LOOP ,
PUSH
POP
STS ;
21. NOP ;
22. IDLE ;
Table I. Syntax Notation Conventions
Notation
UPPERCASE
;
,
italics
| between lines |
<datan>
<addrn>
<reladdrn>
compute
shiftimm
condition
termination
ureg
sreg
dreg
Ia
Mb
Ic
Md
Meaning
Explicit syntax—assembler keyword (notation only; assembler is not case-sensitive
and lowercase is the preferred programming
convention)
Instruction terminator
Separates parallel operations in an
instruction
Optional part of instruction
List of options (choose one)
n-bit immediate data value
n-bit immediate address value
n-bit immediate PC-relative address value
ALU, multiplier, shifter or multifunction
operation (from Tables IV-VII)
Shifter immediate operation
(from Table VI)
Status condition (from Table II)
Termination condition (from Table II)
Universal register (from Table III)
System register (from Table III)
R15-R0, F15-F0; register file location
I7-I0; DAG1 index register
M7-M0; DAG1 modify register
I15-I8; DAG2 index register
M15-M8; DAG2 modify register
In a conditional instruction, the execution of the entire instruction is based on
the specified condition.
–8–
REV. C
ADSP-21020
Table III. Universal Registers
Name
Table IV. ALU Compute Operations
Function
Register File
R15–R0
Register file locations
Program Sequencer
PC*
Program counter; address of instruction currently executing
PCSTK
Top of PC stack
PCSTKP
PC stack pointer
FADDR*
Fetch address
DADDR*
Decode address
LADDR
Loop termination address, code; top of loop
address stack
CURLCNTR Current loop counter; top of loop count stack
LCNTR
Loop count for next nested counter-controlled
loop
Data Address Generators
I7–I0
DAG1 index registers
M7–M0
DAG1 modify registers
L7–L0
DAG1 length registers
B7–B0
DAG1 base registers
I15–I8
DAG2 index registers
M15–M8
DAG2 modify registers
L15–L8
DAG2 length registers
B15–B8
DAG2 base registers
Bus Exchange
PX1
PMD-DMD bus exchange 1 (16 bits)
PX2
PMD-DMD bus exchange 2 (32 bits)
PX
48-bit PX1 and PX2 combination
Timer
TPERIOD
Timer period
TCOUNT
Timer counter
Memory Interface
DMWAIT
Wait state and page size control for data
memory
DMBANK1
Data memory bank 1 upper boundary
DMBANK2
Data memory bank 2 upper boundary
DMBANK3
Data memory bank 3 upper boundary
DMADR*
Copy of last data memory address
PMWAIT
Wait state and page size control for program
memory
PMBANK1
Program memory bank 1 upper boundary
PMADR*
Copy of last program memory address
System Registers
MODE1
Mode control bits for bit-reverse, alternate registers, interrupt nesting and enable, ALU saturation, floating-point rounding mode and
boundary
MODE2
Mode control bits for interrupt sensitivity,
cache disable and freeze, timer enable, and I/O
flag configuration
IRPTL
Interrupt latch
IMASK
Interrupt mask
IMASKP
Interrupt mask pointer (for nesting)
ASTAT
Arithmetic status flags, bit test, I/O flag values,
and compare accumulator
STKY
Sticky arithmetic status flags, circular buffer
overflow flags, stack status flags (not sticky)
USTAT1
User status register l
USTAT2
User status register 2
Floating-Point
Rn = Rx + Ry
Rn = Rx – Ry
Rn = Rx + Ry, Rm = Rx – Ry
Rn = Rx + Ry + CI
Rn = Rx – Ry + CI – l
Rn = (Rx + Ry)/2
COMP(Rx, Ry)
Rn = –Rx
Rn = ABS Rx
Rn = PASS Rx
Rn = MIN(Rx, Ry)
Rn = MAX(Rx, Ry)
Rn = CLIP Rx BY Ry
Rn = Rx + CI
Rn = Rx + CI – 1
Rn = Rx + l
Rn = Rx – l
Rn = Rx AND Ry
Rn = Rx OR Ry
Rn = Rx XOR Ry
Rn = NOT Rx
Fn = Fx + Fy
Fn = Fx – Fy
Fn = Fx + Fy, Fm = Fx – Fy
Fn = ABS (Fx + Fy)
Fn = ABS (Fx – Fy)
Fn = (Fx + Fy)/2
COMP(Fx, Fy)
Fn = –Fx
Fn = ABS Fx
Fn = PASS Fx
Fn = MIN(Fx, Fy)
Fn = MAX(Fx, Fy)
Fn = CLIP Fx BY Fy
Fn = RND Fx
Fn = SCALB Fx BY Ry
Rn = MANT Fx
Rn = LOGB Fx
Rn = FIX Fx BY Ry
Rn = FIX Fx
Fn = FLOAT Rx BY Ry
Fn = FLOAT Rx
Fn = RECIPS Fx
Fn = RSQRTS Fx
Fn = Fx COPYSIGN Fy
Rn, Rx, Ry R15–R0; register file location, fixed-point
Fn, Fx, Fy F15–F0; register file location, floating point
*read-only
Refer to User’s Manual for bit-level definitions of each register.
REV. C
Fixed-Point
–9–
ADSP-21020
Table V. Multiplier Compute Operations
Rn
MRF
MRB
Rn
Rn
MRF
MRB
Rn
Rn
MRF
MRB
MRF
MRB
MRxF
MRxB
= Rx * Ry ( S S F
= Rx * Ry ( U U I
= Rx * Ry ( U U FR
= MRF + Rx * Ry ( S
= MRB + Rx * Ry ( U
= MRF + Rx * Ry ( U
= MRB
= SAT MRF (SI)
= SAT MRB (UI)
= SAT MRF (SF)
= SAT MRB (UF)
=0
)
= Rn
Fn
S F )
U I
U FR
= Fx * Fy
Rn
Rn
MRF
MRB
Rn
Rn
MRF
MRB
= MRF – Rx * Ry ( S S F )
= MRB= Rx * Ry ( U U I
= MRF= Rx * Ry ( U U I FR
= MRB
= RND MRF (SF)
= RND MRB (UF)
= RND MRF
= RND MRB
Rn
Rn
= MRxF
= MRxB
Rn, Rx, Ry
R15–R0; register file location, fixed-point
Fn, Fx, Fy
F15–F0; register file location, floating-point
MRxF
MR2F, MR1F; MR0F; multiplier result accumulators, foreground
MRxB
MR2B, MR1B, MR0B; multiplier result accumulators, background
( x-input
y-input data format, )
( x-input
y-input rounding
S
Signed input
U
Unsigned input
I
Integer input(s)
F
Fractional input(s)
FR
Fractional inputs, Rounded output
(SF)
Default format for 1-input operations
(SSF) Default format for 2-input operations
Table VI. Shifter and Shifter Immediate Compute Operations
Shifter
Shifter Immediate
Rn = LSHIFT Rx BY Ry
Rn = Rn OR LSHIFT Rx BY Ry
Rn = ASHIFT Rx BY Ry
Rn = Rn OR ASHIFT Rx BY Ry
Rn = ROT Rx BY RY
Rn = BCLR Rx BY Ry
Rn = BSET Rx BY Ry
Rn = BTGL Rx BY Ry
BTST Rx BY Ry
Rn = FDEP Rx BY Ry
Rn = Rn OR FDEP Rx BY Ry
Rn = FDEP Rx BY Ry (SE)
Rn = Rn OR FDEP Rx BY Ry (SE)
Rn = FEXT Rx BY Ry
Rn = FEXT Rx BY Ry (SE)
Rn = EXP Rx
Rn = EXP Rx (EX)
Rn = LEFTZ Rx
Rn = LEFTO Rx
Rn = LSHIFT Rx BY<data8>
Rn = Rn OR LSHIFT Rx BY<data8>
Rn = ASHIFT Rx BY<data8>
Rn = Rn OR ASHIFT Rx BY<data8>
Rn = ROT Rx BY<data8>
Rn = BCLR Rx BY<data8>
Rn = BSET Rx BY<data8>
Rn = BTGL Rx BY<data8>
BTST Rx BY<data8>
Rn = FDEP Rx BY <bit6>: <len6>
Rn = Rn OR FDEP Rx BY <bit6>:<1en6>
Rn = FDEP Rx BY <bit6>:<1en6> (SE)
Rn = Rn OR FDEP Rx BY <bit6>:<1en6> (SE)
Rn = FEXT Rx BY <bit6>:<1en6>
Rn = FEXT Rx BY <bit6>:<1en6> (SE)
Rn, Rx, Ry
R15-R0; register file location, fixed-point
<bit6>:<len6> 6-bit immediate bit position and length values (for shifter immediate operations)
–10–
REV. C
ADSP-21020
Table Vll. Multifunction Compute Operations
Table VIII. Interrupt Vector Addresses and Priorities
Fixed-Point
Rm=R3-0 * R7-4 (SSFR), Ra=R11-8 + R15-12
Rm=R3-0 * R7-4 (SSFR), Ra=R11-8 – R15-12
Rm=R3-0 * R7-4 (SSFR), Ra=(R11-8 + R15-12)/2
MRF=MRF + R3-0 * R7-4 (SSF), Ra=R11-8 + R15-12
MRF=MRF + R3-0 * R7-4 (SSF), Ra=R11-8 – R15-12
MRF=MRF + R3-0 * R7-4 (SSF), Ra=(R11-8 + R15-12)/2
Rm=MRF + R3-0 * R7-4 (SSFR), Ra=R11-8 + R15-12
Rm=MRF + R3-0 * R7-4 (SSFR), Ra=R11-8 – R15-12
Rm=MRF + R3-0 * R7-4 (SSFR), Ra=(R11-8 + R15-12)/2
MRF=MRF – R3-0 * R7-4 (SSF), Ra=R11-8 + R15-12
MRF=MRF – R3-0 * R7-4 (SSF), Ra=R11-8 – R15-12
MRF=MRF – R3-0 * R7-4 (SSF), Ra=(R11-8 + R15-12)/2
Rm=MRF – R3-0 * R7-4 (SSFR), Ra=R11-8 + R15-12
Rm=MRF – R3-0 * R7-4 (SSFR), Ra=R11-8 – R15-12
Rm=MRF – R3-0 * R7-4 (SSFR), Ra=(R11-8 + R15-12)/2
Rm=R3-0 * R7-4 (SSFR), Ra=R11-8 + R15-12,
Rs=R11-8 – R15-12
Floating-Point
Fm=F3-0 * F7-4, Fa=F11-8 + F15-12
Fm=F3-0 * F7-4, Fa=F11-8 – F15-12
Fm=F3-0 * F7-4, Fa=FLOAT R11-8 by R15-12
Fm=F3-0 * F7-4, Fa=FIX R11-8 by R15-12
Fm=F3-0 * F7-4, Fa=(F11-8 + F15-12)/2
Fm=F3-0 * F7-4, Fa=ABS F11-8
Fm=F3-0 * F7-4, Fa=MAX (F11-8, F15-12)
Fm=F3-0 * F7-4, Fa=MIN (F11-8, F15-12)
Fm=F3-0 * F7-4, Fa=F11-8 + F15-12,
Fs=F11-8 – F15-12
Ra, Rm
R3-0
R7-4
R11-8
R15-12
Fa, Fm
F3-0
F7-4
F11-8
F15-12
(SSF)
(SSFR)
REV. C
No.
Vector
Address
(Hex)
0
1*
2
3
0x00
0x08
0xl0
0xl8
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19–23
24–31
0x20
0x28
0x30
0x38
0x40
0x48
0x50
0x58
0x60
0x68
0x70
0x78
0x80
0x88
0x90
0x98-0xB8
0xC0–OxF8
*Nonmaskable
Any register file location (fixed-point)
R3, R2, R1, R0
R7, R6, R5, R4
R11, R10, R9, R8
R15, R14, R13, R12
Any register file location (floating-point)
F3, F2, F1, F0
F7, F6, F5, F4
F11, F10, F9, F8
F15, F14, F13, F12
X-input signed, Y-input signed, fractional inputs
X-input signed, Y-input signed, fractional inputs, rounded output
–11–
Function
Reserved
Reset
Reserved
Status stack or loop stack overflow or
PC stack full
Timer=0 (high priority option)
IRQ3 asserted
IRQ2 asserted
IRQ1 asserted
IRQ0 asserted
Reserved
Reserved
DAG 1 circular buffer 7 overflow
DAG 2 circular buffer 15 overflow
Reserved
Timer=0 (low priority option)
Fixed-point overflow
Floating-point overflow
Floating-point underflow
Floating-point invalid operation
Reserved
User software interrupts
ADSP-21020–SPECIFICATIONS
RECOMMENDED OPERATING CONDITIONS
Parameter
K Grade
Min
Max
B Grade
Min
Max
T Grade
Min
Max
Unit
VDD
TAMB
4.50
0
4.50
–40
4.50
–55
V
°C
Supply Voltage
Ambient Operating Temperature
5.50
+70
5.50
+85
5.50
+125
Refer to Environmental Conditions for information on thermal specifications.
ELECTRICAL CHARACTERISTICS
Parameter
VIH
VIHCR
VIL
VILC
VOH
VOL
IIH
IIL
IILT
IOZH
IOZL
IDDIN
Hi-Level Input Voltage1
Hi-Level Input Voltage2, 12
Lo-Level Input Voltage1, 12
Lo-Level Input Voltage2
Hi-Level Output Voltage3, 11
Lo-Level Output Voltage3, 11
Hi-Level Input Current4, 5
Lo-Level Input Current4
Lo-Level Input Current5
Tristate Leakage Current6
Tristate Leakage Current6
Supply Current (Internal)7
IDDIDLE
CIN
Supply Current (Idle)8
Input Capacitance9, 10
Test Conditions
Min
VDD = max
VDD = max
VDD = min
VDD = max
VDD = min, IOH = –1.0 mA
VDD = min, IOL = 4.0 mA
VDD = max, VIN = VDD max
VDD = max, VIN = 0 V
VDD = max, VIN = 0 V
VDD = max, VIN = VDD max
VDD = max, VIN = 0 V
tCK = 30–33 ns, VDD = max, VIHCR = 3.0 V,
VIH = 2.4 V, VIL = VILC = 0.4 V
VDD = max, VIN = 0 V or VDD max
fIN = 1 MHz, TCASE = 25°C, VIN = 2.5 V
2.0
3.0
Max
Unit
0.4
10
10
350
10
10
490
V
V
V
V
V
V
µA
µA
µA
µA
µA
mA
150
10
mA
pF
0.8
0.6
2.4
NOTES
l
Applies to: PMD47–0, PMACK, PMTS, DMD39–0, DMACK, DMTS, IRQ3–0. FLAG3–0, BR, TMS, TDI.
2
Applies to: CLKIN, TCK.
3
Applies to: PMA23–0, PMD47–0, PMS1–0, PMRD, PMWR, PMPAGE, DMA31–0, DMD39–0, DMS3–0, DMRD, DMWR, DMPAGE, FLAG3–0,
TIMEXP, BG.
4
Applies to: PMACK, PMTS, DMACK, DMTS, IRQ3–0, BR, CLKIN, RESET, TCK.
5
Applies to: TMS, TDI, TRST.
6
Applies to: PMA23–0, PMD47–0, PMS1–0, PMRD, PMWR, PMPAGE, DMA31–0, DMD39–0, DMS3–0, DMRD, DMWR, DMPAGE, FLAG3–0, TDO.
7
Applies to IVDD pins. At t CK = 30–33 ns, I DDIN (typical) = 230 mA; at t CK = 40 ns, I DDIN (max) = 420 mA and I DDIN (typical) = 200 mA; at t CK = 50 ns,
IDDIN (max) = 370 mA and I DDIN (typical) = 115 mA. See “Power Dissipation” for calculation of external (EVDD) supply current for total supply current.
8
Applies to IVDD pins. Idle refers to ADSP-21020 state of operation during execution of the IDLE instruction.
9
Guaranteed but not tested.
10
Applies to all signal pins.
11
Although specified for TTL outputs, all ADSP-21020 outputs are CMOS-compatible and will drive to V DD and GND assuming no dc loads.
12
Applies to RESET, TRST.
ABSOLUTE MAXIMUM RATINGS*
Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . –0.3 V to +7 V
Input Voltage . . . . . . . . . . . . . . . . . . . . –0.3 V to VDD + 0.3 V
Output Voltage Swing . . . . . . . . . . . . . –0.3 V to VDD + 0.3 V
Load Capacitance . . . . . . . . . . . . . . . . . . . . . . . . . . . . 200 pF
Operating Temperature Range (Ambient) . . –55°C to +125°C
Storage Temperature Range . . . . . . . . . . . . –65°C to +150°C
Lead Temperature (10 seconds) CPGA . . . . . . . . . . . +300°C
*Stresses above those listed under “Absolute Maximum Ratings” may cause
permanent damage to the device. These are stress ratings only and functional
operation of the device at these or any other conditions above 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.
ESD SENSITIVITY
The ADSP-21020 features proprietary input protection circuitry to dissipate high energy discharges
(Human Body Model). Per method 3015 of MIL-STD-883, the ADSP-21020 has been classified
as a Class 3 device, with the ability to withstand up to 4000 V ESD.
Proper ESD precautions are strongly recommended to avoid functional damage or performance
degradation. Charges readily accumulate on the human body and test equipment and discharge
without detection. Unused devices must be stored in conductive foam or shunts, and the foam
should be discharged to the destination socket before devices are removed. For further information
on ESD precautions, refer to Analog Devices’ ESD Prevention Manual.
–12–
WARNING!
ESD SENSITIVE DEVICE
REV. C
ADSP-21020
TIMING PARAMETERS
General Notes
See Figure 15 on page 24 for voltage reference levels. 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, you cannot meaningfully add parameters to
derive other specifications.
Clock Signal
K/B/T Grade
K/B/T Grade
B/T Grade
K Grade
Parameter
20 MHz
Min
Max
25 MHz
Min
Max
30 MHz
Min
Max
33.3 MHz
Min
Max
Unit
Timing Requirement:
tCK
CLKIN Period
tCKH
CLKIN Width High
tCKL
CLKIN Width Low
50
10
10
40
10
10
33
10
10
30
10
10
ns
ns
ns
150
150
150
150
t CK
CLKIN
t CKL
t CKH
Figure 3. Clock
Reset
K/B/T Grade K/B/T Grade B/T Grade
20 MHz
Min
Max
Parameter
Timing Requirement:
tWRST1 RESET Width Low
200
tSRST2 RESET Setup before CLKIN High 29
50
K Grade
25 MHz
Min
Max
30 MHz
Min Max
33.3 MHz
Min Max
Frequency Dependency*
Min
Max
Unit
160
24
132
21
120
19
4tCK
29 + DT/2
40
33
30
30
ns
ns
NOTES
DT = tCK –50 ns
1
Applies after the power-up sequence is complete. At power up, the Internal Phase Locked Loop requires no more than 1000 CLKIN cycles while RESET is low,
assuming stable VDD and CLKIN (not including clock oscillator start-up time).
2
Specification only applies in cases where multiple ADSP-21020 processors are required to execute in program counter lock-step (all processors start execution at
location 8 in the same cycle). See the Hardware Configuration chapter of the ADSP-21020 User’s Manual for reset sequence information.
CLKIN
tSRST
t WRST
RESET
Figure 4. Reset
REV. C
–13–
ADSP-21020
Interrupts
K/B/T Grade K/B/T Grade B/T Grade
20 MHz
Min Max
Parameter
Timing Requirement:
tSIR IRQ3-0 Setup before CLKIN High 38
tHIR IRQ3-0 Hold after CLKIN High
0
tIPW IRQ3-0 Pulse Width
55
K Grade
25 MHz
30 MHz
33.3 MHz Frequency Dependency*
Min
Max Min Max Min Max Min
Max
Unit
31
0
45
25
0
38
23
0
35
38 + 3DT/4
ns
ns
tCK + 5
ns
NOTE
*DT = tCK – 50 ns
Meeting setup and hold guarantees interrupts will be latched in that cycle. Meeting the pulse width is not necessary if the setup and hold is met. Likewise, meeting the
setup and hold is not necessary if the pulse width is met. See the Hardware Configuration chapter of the ADSP-21020 User’s Manual for interrupt servicing information.
CLKIN
t HIR
t SIR
IRQ3-0
t IPW
Figure 5. Interrupts
Timer
K/B/T Grade K/B/T Grade
Parameter
20 MHz
Min Max
Switching Characteristic:
tDTEX CLKIN High to TIMEXP
24
25 MHz
Min Max
B/T Grade
K Grade
30 MHz
33.3 MHz Frequency Dependency*
Min Max Min Max Min
Max
Unit
24
24
24
ns
NOTE
*DT = tCK – 50 ns
CLKIN
t DTEX
t DTEX
TIMEXP
Figure 6. TIMEXP
–14–
REV. C
ADSP-21020
Flags
K/B/T Grade K/B/T Grade B/T Grade
20 MHz
Min
Max
Parameter
Timing Requirement:1
tSFI
FLAG3-0IN Setup before CLKIN High 19
0
tHFI FLAG3-0IN Hold after CLKIN High
tDWRFI FLAG3-0IN Delay from xRD, xWR Low
tHFIWR FLAG3-0IN Hold after xRD, xWR
0
Deasserted
Switching Characteristic:
tDFO FLAG3-0OUT Delay from CLKIN High
tHFO FLAG3-0OUT Hold after CLKIN High 5
1
tDFOE CLKIN High to FLAG3-0OUT Enable
tDFOD CLKIN High to FLAG3-0OUT Disable
K Grade
25 MHz
30 MHz
Min
Max Min Max
33.3 MHz Frequency Dependency*
Min Max Min
Max
Unit
16
0
13
0
14
0
12
8
0
5
0
24
3
24
5
1
24
ns
ns
12 + 7DT/16 ns
ns
0
24
5
1
19 + 5DT/16
24
ns
ns
ns
ns
5
1
24
24
24
NOTES
*DT = tCK – 50 ns
1
Flag inputs meeting these setup and hold times will affect conditional operations in the next instruction cycle. See the Hardware Configuration chapter of the
ADSP-21020 User’s Manual for additional flag servicing information.
x = PM or DM.
CLKIN
tDFO
t DFO
tDFOE
tHFO
FLAG3-0 OUT
FLAG OUTPUT
CLKIN
tSFI
tHFI
FLAG3-0 IN
t DWRFI
t HFIWR
xRD, xWR
FLAG INPUT
Figure 7. Flags
REV. C
–15–
t DFOD
ADSP-21020
Bus Request/Bus Grant
K/B/T Grade K/B/T Grade B/T Grade
K Grade
Parameter
20 MHz
Min
Max
25 MHz
30 MHz
Min
Max Min Max
33.3 MHz Frequency Dependency*
Min Max Min
Max
Unit
Timing Requirement:
tHBR
BR Hold after CLKIN High
BR Setup before CLKIN High
tSBR
0
18
0
15
0
13
0
12
–2
–2
–2
Switching Characteristic:
tDMDBGL Memory Interface Disable to BG Low –2
CLKIN High to Memory Interface
tDME
Enable
25
tDBGL
CLKIN High to BG Low
tDBGH
CLKIN High to BG High
20
22
22
16
22
22
18 + 5DT/16
ns
15
22
22
ns
ns
25 + DT/2
22
22
ns
ns
ns
NOTES
*DT = tCK – 50 ns.
Memory Interface = PMA23-0, PMD47-0, PMS1-0, PMRD, PMWR, PMPAGE, DMA31-0, DMD39-0, DMS3-0, DMRD, DMWR, DMPAGE.
Buses are not granted until completion of current memory access.
See the Memory Interface chapter of the ADSP-21020 User’s Manual for BG, BR cycle relationships.
CLKIN
t HBR
t HBR
tSBR
tSBR
BR
t DME
MEMORY
INTERFACE
t DMDBGL
t DBGL
t DBGH
BG
Figure 8. Bus Request/Bus Grant
–16–
REV. C
ADSP-21020
External Memory Three-State Control
K/B/T Grade K/B/T Grade B/T Grade
Parameter
Timing Requirement:
tSTS
xTS, Setup before CLKIN High
tDADTS xTS Delay after Address, Select
tDSTS xTS Delay after XRD, XWR Low
Switching Characteristic:
tDTSD Memory Interface Disable before
CLKIN High
tDTSAE xTS High to Address, Select Enable
K Grade
20 MHz
Min
Max
25 MHz
Min
Max
30 MHz 33.3 MHz Frequency Dependency*
Min Max Min Max Min
Max
Unit
14
12
10
50
28
16
0
0
40
19
11
–2
0
–4
0
33
13
7
9
–5
0
30
10
6
14 + DT/4 tCK
ns
28 + 7DT/8 ns
16 + DT/2
ns
DT/4
NOTES
*DT = tCK – 50 ns.
xTS should only be asserted (low) during an active memory access cycle.
Memory Interface = PMA23-0, PMD47-0, PMS1-0, PMRD, PMWR, PMPAGE, DMA31-0, DMD39-0, DMS3-0, DMRD, DMWR, DMPAGE.
Address = PMA23-0, DMA31-0. Select = PMS1-0, DMS3-0.
x = PM or DM.
CLKIN
tSTS
tSTS
PMTS, DMTS
t DADTS
t DSTS
t DTSD
xRD, xWR
t DTSAE
ADDRESS,
SELECTS
DATA
Figure 9. External Memory Three-State Control
REV. C
–17–
ns
ns
ADSP-21020
Memory Read
Parameter
Timing Requirement:
tDAD
Address, Select to Data Valid
tDRLD xRD Low to Data Valid
tHDA Data Hold from Address, Select
tHDRH Data Hold from xRD High
tDAAK xACK Delay from Address
tDRAK xACK Delay from xRD Low
tSAK
xACK Setup before CLKIN High
xACK Hold after CLKIN High
tHAK
Switching Characteristic:
tDARL Address, Select to xRD Low
xPAGE Delay from Address, Select
tDAP
tDCKRL CLKIN High to xRD Low
tRW
xRD Pulse Width
tRWR xRD High to xRD, xWD Low
K/B/T Grade K/B/T Grade
B/T Grade
20 MHz
Min
Max
30 MHz
33.3 MHz Frequency Dependence*
Min Max Min Max Min
Max
Unit
25 MHz
Min
Max
37
24
0
–1
27
18
0
–1
27
15
14
0
8
16
26
17
18
10
13
20
13
12
6
12
15
11
37 + DT
24 + 5DT/8
9
5
27 + 7DT/8
15 + DT/2
9
0
2
1
24
17
11
0
–1
10
0
4
1
26
20
13
0
–1
12
0
K Grade
14 + DT/4
0
1
22
11
13
9
8 + 3DT/8
1
21
16 + DT/4 26 + DT/4
26 + 5DT/8
17 + 3DT/8
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
NOTES
*DT = tCK – 50 ns
x = PM or DM; Address = PMA23-0, DMA31-0; Data = PMD47-0, DMD39-0; Select = PMS1-0, DMS3-0.
–18–
REV. C
ADSP-21020
CLKIN
ADDRESS,
SELECT
t DAP
DMPAGE,
PMPAGE
t DCKRL
t DARL
t RW
DMRD,
PMRD
t HDA
t DRLD
t HDRH
t DAD
DATA
t DRAK
t RWR
tSAK
t DAAK
DMACK,
PMACK
DMWR,
PMWR
Figure 10. Memory Read
REV. C
–19–
t HAK
ADSP-21020
Memory Write
Parameter
Timing Requirement:
tDAAK xACK Delay from Address, Select
tDWAK xACK Delay from xWR Low
xACK Setup before CLKIN High
tSAK
tHAK
xACK Hold after CLKIN High
Switching Characteristic:
tDAWH Address, Select to xWR Deasserted
tDAWL Address, Select to xWR Low
xWR Pulse Width
tWW
tDDWH Data Setup before xWR High
tDWHA Address, Select Hold after xWR
Deasserted
tHDWH Data Hold after xWR Deasserted1
tDAP
xPAGE Delay from Address, Select
tDCKWL CLKIN High to xWR Low
tWWR xWR High to xWR or xRD Low
tDDWR Data Disable before xWR or xRD
Low
tWDE xWR Low to Data Enabled
K/B/T Grade K/B/T Grade
B/T Grade
20 MHz
Min
Max
30 MHz 33.3 MHz Frequency Dependency*
Min Max Min Max Min
Max
Unit
25 MHz
Min
Max
27
15
18
10
14
0
12
0
37
11
26
23
28
7
20
18
1
0
0
–1
16
17
13
0
1
26
13
13
1
24
9
–1
K Grade
12
6
9
0
27 + 7DT/8 ns
15 + DT/2
ns
14 + DT/4
ns
ns
21
5
16
14
18
3
15
13
37+ 15DT/16
11 + 3DT/8
26 + 9DT/16
23 + DT/2
ns
ns
ns
ns
0
–1
0
–1
1 + DT/16
DT/16
16 + DT/4 26 + DT/4
17 + 7DT/16
ns
ns
ns
ns
ns
13 + 3DT/8
DT/16
ns
ns
10
0
12
10
7
–1
1
22
9
5
11
8
1
21
5
–1
NOTES
*DT = tC – 50 ns
See “System Hold Time Calculation” in “Test Conditions” section for calculating hold times given capacitive and DC loads.
x = PM or DM; Address = PMA23-0, DMA31-0; Data = PMD47-0, DMD39-0; Select = PMS1-0, DMS3-0.
–20–
REV. C
ADSP-21020
CLKIN
ADDRESS,
SELECT
t DAP
DMPAGE,
PMPAGE
t DAWH
t DAWL
DMWR,
PMWR
t DWHA
tWW
tWWR
t DCKWL
tWDE
t HDWH
t DDWH
DATA
t DDWR
t DWAK
t DAAK
tSAK
DMACK,
PMACK
DMRD,
PMRD
Figure 11. Memory Write
REV. C
–21–
t HAK
ADSP-21020
IEEE 1149.1 Test Access Port
K/B/T Grade K/B/T Grade B/T Grade
K Grade
Parameter
20 MHz
Min Max
25 MHz
Min
Max
30 MHz
33.3 MHz Frequency Dependency*
Min Max Min Max Min
Max
Unit
Timing Requirement:
tTCK TCK Period
tSTAP TDI, TMS Setup before TCK High
tHTAP TDI, TMS Hold after TCK High
tSSYS System Inputs Setup before TCK High
tHSYS System Inputs Hold after TCK High
tTRSTW TRST Pulse Width
50
5
6
7
9
200
40
5
6
7
9
160
33
5
6
7
9
132
Switching Characteristic:
tDTDO TDO Delay from TCK Low
tDSYS System Outputs Delay from TCK Low
15
26
15
26
30
5
6
7
9
120
15
26
tCK
15
26
ns
ns
ns
ns
ns
ns
ns
ns
NOTES
*DT = tC – 50 ns
System Inputs = PMD47-0, PMACK, PMTS, DMD39-0, DMACK, DMTS, CLKIN, IRQ3 0, RESET, FLAG3-0, BR.
System Outputs = PMA23-0, PMS1-0, PMRD, PMWR, PMD47-0, PMPAGE, DMA31-0, DMS1-0, DMRD, DMWR, DMD39-0, DMPAGE, FLAG3-0, BG,
TIMEXP.
See the IEEE 1149.1 Test Access Port chapter of the ADSP-21020 User’s Manual for further detail.
–22–
REV. C
ADSP-21020
t TCK
TCK
tSTAP
t HTAP
TMS,TDI
t DTDO
TDO
tSSYS
t HSYS
SYSTEM
INPUTS
t DSYS
SYSTEM
OUTPUTS
Figure 12. IEEE 1149.1 Test Access Port
REV. C
–23–
ADSP-21020
TEST CONDITIONS
Output Disable Time
IOL
Output pins are considered to be disabled when they stop
driving, go into a high-impedance state, and start to decay from
their output high or low voltage. The time for the voltage on the
bus to decay by ∆V is dependent on the capacitive load, CL, and
the load current, IL. It can be approximated by the following
equation:
t DECAY =
TO
OUTPUT
PIN
CL ∆V
IL
+1.5V
50pF*
IOH
*AC TIMING SPECIFICATIONS ARE CALCULATED FOR 100pF
DERATING ON THE FOLLOWING PINS: PMA23–0, PMS1–0, PMRD,
PMWR, PMPAGE, DMA31–0, DMS3–0, DMRD, DMWR, DMPAGE
The output disable time (tDIS) is the difference between
tMEASURED and tDECAY as shown in Figure 13. The time
tMEASURED) is the interval from when the reference signal
switches to when the output voltage decays ∆V from the
measured output high or output low voltage. tDECAY is
calculated with ∆V equal to 0.5 V, and test loads CL and IL.
Figure 14. Equivalent Device Loading For AC
Measurements (Includes All Fixtures)
INPUT OR
OUTPUT
Output Enable Time
Output pins are considered to be enabled when they have made
a transition from a high-impedance state to when they start
driving. The output enable time (tENA) is the interval from when
a reference signal reaches a high or low voltage level to when the
output has reached a specified high or low trip point, as shown
in the Output Enable/Disable diagram. If multiple pins (such as
the data bus) are enabled, the measurement value is that of the
first pin to start driving.
1.5V
1.5V
Figure 15. Voltage Reference Levels For AC
Measurements (Except Output Enable/Disable)
Example System Hold Time Calculation
To determine the data output hold time in a particular system,
first calculate tDECAY using the above equation. Choose ∆V to be
the difference between the ADSP-21020’s output voltage and
the input threshold for the device requiring the hold time. A
typical ∆V will be 0.4 V. CL is the total bus capacitance (per
data line), and IL is the total leakage or three-state current (per
data line). The hold time will be tDECAY plus the minimum
disable time (i.e. tHDWD for the write cycle).
REFERENCE
SIGNAL
t MEASURED
t DIS
t ENA
VOH (MEASURED)
2.0V
VOH (MEASURED) –∆V
VOH (MEASURED)
OUTPUT
VOL (MEASURED) +∆V
1.0V
VOL (MEASURED)
VOL (MEASURED)
t DECAY
OUTPUT STOPS DRIVING
HIGH-IMPEDANCE STATE. TEST CONDITIONS
CAUSE THIS VOLTAGE LEVEL TO BE
APPROXIMATELY 1.5 V.
OUTPUT STARTS DRIVING
Figure 13. Output Enable/Disable
–24–
REV. C
ADSP-21020
Capacitive Loading
12
OUTPUT DELAY OR HOLD – ns
Output delays are based on standard capacitive loads: 100 pF
on address, select, page and strobe pins, and 50 pF on all others
(see Figure 14). For different loads, these timing parameters
should be derated. See the Hardware Configuration chapter of
the ADSP-21020 User’s Manual for further information on
derating of timing specifications.
Figures 16 and 17 show how the output rise time varies with
capacitance. Figures 18 and 19 show how output delays vary
with capacitance. Note that the graphs may not be linear outside
the ranges shown.
11.19
10
8
1
6
5.34
4
2
2
– 0.89
NOMINAL
10
9.18
9
–1.86
–2
25
50
1
75
100
125
175
150
200
LOAD CAPACITANCE – pF
NOTES:
(1) OUTPUT PINS BG, TIMEXP
(2) OUTPUT PINS PMD47–0, DMD39–0, FLAG3–0
7
6
5
Figure 18. Typical Output Delay or Hold vs. Load
Capacitance (at Maximum Case Temperature)
3.95
4
2
3
2 1.46
1.31
1
OUTPUT DELAY OR HOLD – ns
RISE TIME – ns (0.8V – 2.0V)
8
0
25
50
75
100
125
150
LOAD CAPACITANCE – pF
175
200
NOTES:
(1) OUTPUT PINS BG, TIMEXP
(2) OUTPUT PINS PMD47–0, DMD39–0, FLAG3–0
Figure 16. Typical Output Rise Time vs. Load
Capacitance (at Maximum Case Temperature)
2.99
3
1
2
2.27
2
1
NOMINAL
–1
– 1.70
–2
RISE TIME – ns (0.8V – 2.0V)
– 2.24
4
–3
3.59
25
1
1.33
1
0
50
75
100
125
150
175
200
π
LOAD CAPACITANCE – pF
NOTES:
(1) OUTPUT PINS PMA23–0, PMS1–0, PMPAGE, DMA31–0, DMS3–0, DMPAGE, TDO
(2) OUTPUT PINS PMRD, PMWR, DMRD, DMWR
Figure 17. Typical Output Rise Time vs. Load
Capacitance (at Maximum Case Temperature)
REV. C
100
125
150
175
200
Figure 19. Typical Output Delay or Hold vs. Load
Capacitance (at Maximum Case Temperature)
0.85
25
75
NOTES:
(1) OUTPUT PINS PMA23–0, PMS1–0, PMPAGE, DMA31–0, DMS3–0, DMPAGE, TDO
(2) OUTPUT PINS PMRD, PMWR, DMRD, DMWR
3.00
2
2
50
LOAD CAPACITANCE – pF
3
–25–
ADSP-21020
ENVIRONMENTAL CONDITIONS
Example:
The ADSP-21020 is available in a Ceramic Pin Grid Array
(CPGA). The package uses a cavity-down configuration which
gives it favorable thermal characteristics. The top surface of the
package contains a raised copper slug from which much of the
die heat is dissipated. The slug provides a surface for mounting
a heat sink (if required).
Estimate PEXT with the following assumptions:
The commercial grade (K grade) ADSP-21020 is specified for
operation at TAMB of 0°C to +70°C. Maximum TCASE (case
temperature) can be calculated from the following equation:
T CASE = T AMB + ( PD × θCA )
where PD is power dissipation and θCA is the case-to-ambient
thermal resistance. The value of PD depends on your
application; the method for calculating PD is shown under
“Power Dissipation” below. θCA varies with airflow and with the
presence or absence of a heat sink. Table IX shows a range of
θCA values.
Table IX. Maximum θCA for Various Airflow Values
Airflow (Linear ft./min.) 0
100
200
300
CPGA with No Heat Sink 12.8°C/W 9.2°C/W 6.6°C/W 5.5°C/W
NOTES
θJC is approximately 1°C/W.
Maximum recommended T J is 130°C.
As per method 1012 MIL-STD-883. Ambient temperature: 25 °C. Power:
3.5 W.
Power Dissipation
Total power dissipation has two components: one due to
internal circuitry and one due to the switching of external
output drivers. Internal power dissipation is dependent on the
instruction execution sequence and the data values involved.
Internal power dissipation is calculated in the following way:
PINT = IDDIN 3 VDD
The external component of total power dissipation is caused by
the switching of output pins. Its magnitude depends on:
1) the number of output pins that switch during each cycle (O),
2) the maximum frequency at which they can switch (f),
3) their load capacitance (C), and
4) their voltage swing (VDD).
It is calculated by:
PEXT = O 3 C 3 VDD2 3 f
The load capacitance should include the processor’s package
capacitance (CIN). The switching frequency includes driving the
load high and then back low. Address and data pins can drive
high and low at a maximum rate of 1/(2tCK). The write strobes
can switch every cycle at a frequency of 1/tCK. Select pins switch
at 1/(2tCK), but 2 DM and 2 PM selects can switch on each
cycle. If only one bank is accessed, no select line will switch.
•
A system with one RAM bank each of PM (48 bits) and DM
(32 bits).
•
•
32K 3 8 RAM chips are used, each with a load of 10 pF.
Single-precision mode is enabled so that only 32 data pins can
switch at once.
•
PM and DM writes occur every other cycle, with 50% of the
pins switching.
•
The instruction cycle rate is 20 MHz (tCK = 50 ns) and
VDD = 5.0 V.
The PEXT equation is calculated for each class of pins that can
drive:
Pin
Type
#
%
Pins Switch 3 C
3f
3 VDD2 PEXT
PMA
PMS
PMWR
PMD
DMA
DMS
DMWR
DMD
15
2
1
32
15
2
1
32
5 MHz
5 MHz
10 MHz
5 MHz
5 MHz
5 MHz
10 MHz
5 MHz
25 V
25 V
25 V
25 V
25 V
25 V
25 V
25 V
50
0
—
50
50
0
—
50
68 pF
68 pF
68 pF
18 pF
48 pF
48 pF
48 pF
18 pF
0.064 W
0.000 W
0.017 W
0.036 W
0.045 W
0.000 W
0.012 W
0.036 W
PEXT =0.210 W
A typical power consumption can now be calculated for this
situation by adding a typical internal power dissipation:
PTOTAL = PEXT + (5 V 3 IDDIN (typ)) = 0.210 + 1.15
= 1.36 W
Note that the conditions causing a worst case PEXT are different
from those causing a worst case PINT. Maximum PINT cannot
occur while 100% of the output pins are switching from all ones
to all zeros. Also note that it is not common for a program to
have 100% or even 50% of the outputs switching simultaneously.
Power and Ground Guidelines
To achieve its fast cycle time, including instruction fetch, data
access, and execution, the ADSP-21020 is designed with high
speed drivers on all output pins. Large peak currents may pass
through a circuit board’s ground and power lines, especially
when many output drivers are simultaneously charging or
discharging their load capacitances. These transient currents can
cause disturbances on the power and ground lines. To minimize
these effects, the ADSP-21020 provides separate supply pins for
its internal logic (IGND and IVDD) and for its external drivers
(EGND and EVDD).
To reduce system noise at low temperatures when transistors
switch fastest, the ADSP-21020 employs compensated output
drivers. These drivers equalize slew rate over temperature
extremes and process variations. A 1.8 kΩ resistor placed
between the RCOMP pin and EVDD (+5 V) provides a
reference for the compensated drivers. Use of a capacitor
(approximately 100 pF), placed in parallel with the 1.8 kΩ
resistor, is recommended.
–26–
REV. C
ADSP-21020
All GND pins should have a low impedance path to ground. A
ground plane is required in ADSP-21020 systems to reduce this
impedance, minimizing noise.
2.435 (61.9)
0.590
(15.0)
The EVDD and IVDD pins should be bypassed to the ground
plane using approximately 14 high-frequency capacitors (0.1 µF
ceramic). Keep each capacitor’s lead and trace length to the
pins as short as possible. This low inductive path provides the
ADSP-21020 with the peak currents required when its output
drivers switch. The capacitors’ ground leads should also be
short and connect directly to the ground plane. This provides a
low impedance return path for the load capacitance of the
ADSP-21020’s output drivers.
0.128 (3.25)
0.408 (10.4)
0.92
(23.4)
BOTTOM
VIEW
If a VDD plane is not used, the following recommendations
apply. Traces from the +5 V supply to the 10 EVDD pins
should be designed to satisfy the minimum VDD specification
while carrying average dc currents of [IDDEX/10 3 (number of
EVDD pins per trace)]. IDDEX is the calculated external supply
current. A similar calculation should be made for the four
IVDD pins using the IDDIN specification. The traces connecting
+5 V to the IVDD pins should be separate from those connecting to the EVDD pins.
The ADSP-21020 EZ-ICE uses the IEEE 1149.1 JTAG test
access port of the ADSP-21020 to monitor and control the
target board processor during emulation. The EZ-ICE probe
requires that CLKIN, TMS, TCK, TRST, TDI, TDO, and
GND be made accessible on the target system via a 12-pin
connector (pin strip header) such as that shown in Figure 20.
The EZ-ICE probe plugs directly onto this connector for
chip-on-board emulation; you must add this connector to your
target board design if you intend to use the ADSP-21020
EZ-ICE. Figure 21 shows the dimensions of the EZ-ICE probe;
be sure to allow enough space in your system to fit the probe
onto the 12-pin connector.
KEY (NO PIN 1)
X
CLKIN
BTMS
TMS
BTCK
TCK
BTRST
Figure 21. EZ-ICE Probe
The 12-pin, 2-row pin strip header is keyed at the Pin 1 location
–you must clip Pin 1 off of the header. The pins must be 0.025
inch square and at least 0.20 inch in length. Pin spacing is
0.1 3 0.1 inches.
The tip of the pins must be at least 0.10 inch higher than the
tallest component under the probe to allow clearance for the
bottom of the probe. Pin strip headers are available from
vendors such as 3M, McKenzie, and Samtec.
The length of the traces between the EZ-ICE probe connector
and the ADSP-21020 test access port pins should be less than 1
inch. Note that the EZ-ICE probe adds two TTL loads to the
CKIN pin of the ADSP-21020.
The BMTS, BTCK, BTRST, and BTDI signals are provided so
that the test access port can also be used for board-level testing.
When the connector is not being used for emulation, place
jumpers between the BXXX pins and the XXX pins as shown in
Figure 20. If you are not going to use the test access port for
board test, tie BTRST to GND and tie or pull up BTCK to
VDD. The TRST pin must be asserted (pulsed low) after power
up (through BTRST on the connector) or held low for proper
operation of the ADSP-21020.
TDI
GND
TDO
TOP VIEW
Figure 20. Target Board Connector for EZ-ICE Emulator
(Jumpers In Place)
REV. C
2.435
(61.9)
ALL DIMENSIONS IN INCHES AND (mm)
TRST
BTDI
0.6
(15.2)
RIBBON
CABLE
A low frequency bypass capacitor (20 µF tantalum) located near
the junction of the IVDD and EVDD traces is also recommended.
Target System Requirements For Use Of EZ-ICE Emulator
0.2 (5.1)
RIBBON CABLE LENGTH = 60.0 INCHES
–27–
ADSP-21020
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
U
PMA17
PMA20
TMS
EGND
TCK
EVDD
RCOMP
EGND
PMACK
EVDD
PMWR
EGND
PMD44
EGND
PMD40
PMD39
PMD35
PMD31
U
T
EGND
PMA19
PMA23
PMS1
TRST
DMWR
DMACK
CLKIN
NC
NC
PMTS
PMD45
PMD42
NC
PMD37
PMD32
PMD30
PMD27
T
S
PMA11
PMA14
PMA18
PMA22 PMPAGE
TDI
DMTS
DMRD
NC
PMRD
PMD47
PMD43
PMD41
PMD36
PMD34
PMD28
PMD26
PMD21
S
R
EGND
PMA10
PMA15
PMA16
PMS0
TDO
IGND
RESET
IVDD
PMD46
IGND
PMD38
PMD33
PMD29
PMD25
PMD23
EGND
R
P
PMA8
PMA9
PMA13
PMA12
PMD24
PMD22
PMD19
PMD18
P
N
EVDD
PMA5
PMA6
PMA7
PMD20
PMD17
PMD16
EVDD
N
M
PMA1
PMA4
PMA3
PMA2
PMD15
PMD14
PMD13
PMD12
M
L
EGND
PMA0
TIMEXP
IGND
IGND
PMD10
PMD11
EGND
L
K
EVDD
NC
IRQ2
IRQ3
PMD6
PMD7
PMD8
PMD9
K
IVDD
PMD2
PMD5
EVDD
J
PMA21
ADSP-21020
TOP VIEW
(PINS DOWN)
J
EVDD
IRQ0
IRQ1
IVDD
H
EGND
FLAG2
FLAG0
FLAG1
DMD1
DMD0
PMD3
PMD4
H
G
FLAG3
DMA1
DMA0
IGND
IGND
DMD3
NC
EGND
G
F
DMA2
DMA3
DMA4
DMA5
DMD9
DMD6
PMD0
PMD1
F
E
DMA6
DMA7
DMA8
DMA10
DMD13
DMD10
DMD2
EGND
E
D
DMA9
DMA11
DMA12
DMA15
DMA19
DMA23
DMA27
IGND
DMS0
IVDD
DMD36
DMD31
DMD27
DMD22
DMD17
DMD11
DMD5
DMD4
D
C
DMA13
DMA14
DMA18
DMA20
DMA24
DMA28
DMA31
DMS1
NC
DMD38
DMD35
DMD30
DMD28
DMD24
DMD20
DMD15
DMD8
DMD7
C
B
DMA16
DMA17
DMA21
DMA25
DMA26
DMA30 DMPAGE
DMS3
DMD39
DMD37
DMD33
DMD32
DMD26
DMD25
DMD21
DMD18
DMD14
DMD12
B
A
BR
BG
DMA22
EGND
DMA29
EVDD
DMS2
EGND
DMD34
EVDD
DMD29
EGND
DMD23
EVDD
DMD19
EGND
DMD16
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
–28–
A
1
REV. C
ADSP-21020
1
2
3
4
5
6
7
8
9
10
11
12
U
PMD31
PMD35
PMD39
PMD40
EGND
PMD44
EGND
PMWR
EVDD
PMACK
EGND
RCOMP
T
PMD27
PMD30
PMD32
PMD37
NC
PMD42
PMD45
PMTS
NC
NC
CLKIN
S
PMD21
PMD26
PMD28
PMD34
PMD36
PMD41
PMD43
PMD47
PMRD
NC
R
EGND
PMD23
PMD25
PMD29
PMD33
PMD38
IGND
PMD46
IVDD
RESET
P
PMD18
PMD19
PMD22
N
EVDD
PMD16
M
PMD12
L
14
15
EVDD
TCK
EGND
TMS
PMA20
PMA17
U
DMACK
DMWR
TRST
PMS1
PMA23
PMA19
EGND
T
DMRD
DMTS
TDI
PMPAGE
PMA22
PMA18
PMA14
PMA11
S
IGND
TDO
PMS0
PMA21
PMA16
PMA15
PMA10
EGND
R
PMD24
PMA12
PMA13
PMA9
PMA8
P
PMD17
PMD20
PMA7
PMA6
PMA5
EVDD
N
PMD13
PMD14
PMD15
PMA2
PMA3
PMA4
PMA1
M
EGND
PMD11
PMD10
IGND
IGND
TIMEXP
PMA0
EGND
L
K
PMD9
PMD8
PMD7
PMD6
ADSP-21020
IRQ3
IRQ2
NC
EVDD
K
J
EVDD
PMD5
PMD2
IVDD
BOTTOM VIEW
(PINS UP)
IVDD
IRQ1
IRQ0
EVDD
J
H
PMD4
PMD3
DMD0
DMD1
FLAG1
FLAG0
FLAG2
EGND
H
G
EGND
NC
DMD3
IGND
IGND
DMA0
DMA1
FLAG3
G
F
PMD1
PMD0
DMD6
DMD9
DMA5
DMA4
DMA3
DMA2
F
E
EGND
DMD2
DMD10
DMD13
DMA10
DMA8
DMA7
DMA6
E
D
DMD4
DMD5
DMD11
DMD17
DMD22
DMD27
DMD31
DMD36
IVDD
DMS0
IGND
DMA27
DMA23
DMA19
DMA15
DMA12
DMA11
DMA9
D
C
DMD7
DMD8
DMD15
DMD20
DMD24
DMD28
DMD30
DMD35
DMD38
NC
DMS1
DMA31
DMA28
DMA24
DMA20
DMA18
DMA14
DMA13
C
B
DMD12
DMD14
DMD18
DMD21
DMD25
DMD26
DMD32
DMD33
DMD37
DMD39
DMS3
DMPAGE
DMA30
DMA26
DMA25
DMA21
DMA17
DMA16
B
DMD16
EGND
DMD19
EVDD
DMD23
EGND
DMD29
EVDD
DMD34
EGND
DMS2
EVDD
DMA29
EGND
DMA22
BG
BR
A
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
A
1
REV. C
–29–
13
16
17
18
ADSP-21020
PGA
LOCATION
G16
G17
F18
F17
F16
F15
E18
E17
E16
D18
E15
D17
D16
C18
C17
D15
B18
B17
C16
D14
C15
B16
A16
D13
C14
B15
B14
D12
C13
A14
B13
C12
H3
H4
E2
G3
D1
D2
F3
C1
C2
F4
E3
D3
B1
E4
B2
C3
A2
D4
B3
A4
C4
B4
D5
A6
C5
PIN
NAME
DMA0
DMA1
DMA2
DMA3
DMA4
DMA5
DMA6
DMA7
DMA8
DMA9
DMA10
DMA11
DMA12
DMA13
DMA14
DMA15
DMA16
DMA17
DMA18
DMA19
DMA20
DMA21
DMA22
DMA23
DMA24
DMA25
DMA26
DMA27
DMA28
DMA29
DMA30
DMA31
DMD0
DMD1
DMD2
DMD3
DMD4
DMD5
DMD6
DMD7
DMD8
DMD9
DMD10
DMD11
DMD12
DMD13
DMD14
DMD15
DMD16
DMD17
DMD18
DMDl9
DMD20
DMD21
DMD22
DMD23
DMD24
PGA
LOCATION
B5
B6
D6
C6
A8
C7
D7
B7
B8
A10
C8
D8
B9
C9
B10
D10
C11
A12
B11
T13
S11
B12
S12
T12
L17
M18
M15
M16
M17
N17
N16
N15
P18
P17
R17
S18
P15
P16
S17
R16
R15
U18
S16
T17
U17
R14
S15
T16
F2
F1
J3
H2
H1
J2
K4
K3
K2
PIN
NAME
DMD25
DMD26
DMD27
DMD28
DMD29
DMD30
DMD31
DMD32
DMD33
DMD34
DMD35
DMD36
DMD37
DMD38
DMD39
DMS0
DMS1
DMS2
DMS3
DMWR
DMRD
DMPAGE
DMTS
DMACK
PMA0
PMA1
PMA2
PMA3
PMA4
PMA5
PMA6
PMA7
PMA8
PMA9
PMA10
PMA11
PMA12
PMA13
PMA14
PMA15
PMA16
PMA17
PMA18
PMA19
PMA20
PMA21
PMA22
PMA23
PMD0
PMD1
PMD2
PMD3
PMD4
PMD5
PMD6
PMD7
PMD8
PGA
LOCATION
K1
L3
L2
M1
M2
M3
M4
N2
N3
P1
P2
N4
S1
P3
R2
P4
R3
S2
T1
S3
R4
T2
U1
T3
R5
S4
U2
S5
T4
R6
U3
U4
S6
T6
S7
U6
T7
R8
S8
R13
T15
U8
S9
S14
T8
U10
A17
A18
H16
H15
H17
G18
J17
J16
K16
K15
R10
–30–
PIN
NAME
PMD9
PMD10
PMD11
PMD12
PMD13
PMD14
PMD15
PMD16
PMD17
PMD18
PMD19
PMD20
PMD21
PMD22
PMD23
PMD24
PMD25
PMD26
PMD27
PMD28
PMD29
PMD30
PMD31
PMD32
PMD33
PMD34
PMD35
PMD36
PMD37
PMD38
PMD39
PMD40
PMD41
PMD42
PMD43
PMD44
PMD45
PMD46
PMD47
PMS0
PMS1
PMWR
PMRD
PMPAGE
PMTS
PMACK
BG
BR
FLAG0
FLAG1
FLAG2
FLAG3
IRQ0
IRQ1
IRQ2
IRQ3
RESET
PGA
LOCATION
L16
U12
T11
T14
R12
S13
U16
U14
H18
A3
A7
A11
A15
E1
G1
L1
L18
R1
R18
T18
U5
U7
U11
U15
D11
G4
G15
L4
L15
R7
R11
A5
A9
A13
J1
J18
N1
N18
U9
U13
K18
D9
J4
J15
R9
C10
S10
T10
T9
K17
T5
G2
PIN
NAME
TIMEXP
RCOMP
CLKIN
TRST
TD0
TDI
TMS
TCK
EGND
EGND
EGND
EGND
EGND
EGND
EGND
EGND
EGND
EGND
EGND
EGND
EGND
EGND
EGND
EGND
IGND
IGND
IGND
IGND
IGND
IGND
IGND
EVDD
EVDD
EVDD
EVDD
EVDD
EVDD
EVDD
EVDD
EVDD
EVDD
IVDD
IVDD
IVDD
IVDD
NC
NC
NC
NC
NC
NC
NC
REV. C
ADSP-21020
OUTLINE DIMENSIONS
Dimensions shown in inches and (mm).
223-Pin Ceramic Pin Grid Array
e1
e1
j2
D
TOP VIEW
j1
h
A B C D E F G H J K L M N P R S T U
D
A1
A
L3
φb
φ b1
e
INCHES
MILLIMETERS
SYMBOL
MIN
MAX
MIN
MAX
A
0.084
0.102
2.11
2.59
A1
0.40
0.60
1.02
1.52
φb
0.018 TYP
0.46 TYP
φb1
0.050 TYP
1.27 TYP
D
1.844
1.876
46.84
47.64
e1
1.700 TYP
43.18 TYP
e
0.100 TYP
2.54 TYP
L3
h
0.172
0.188
0.020 TYP
4.37
4.77
0.500 TYP
j1
1.125
1.147
28.56
29.14
j2
1.065
1.186
27.05
27.61
NOTE
When socketing the CPGA package, use of a low
insertion force socket is recommended.
REV. C
–31–
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
ADSP-21020
Part Number*
Ambient Temperature
Range
Instruction
Rate (MHz)
Cycle Time
(ns)
Package
ADSP-21020KG-80
ADSP-21020KG-100
ADSP-21020KG-133
ADSP-21020BG-80
ADSP-21020BG-100
ADSP-21020BG-120
ADSP-21020TG-80
ADSP-21020TG-100
ADSP-21020TG-120
ADSP-21020TG-80/883B
ADSP-21020TG-100/883B
ADSP-21020TG-120/883B
0°C to +70°C
0°C to +70°C
0°C to +70°C
–40°C to +85°C
–40°C to +85°C
–40°C to +85°C
–55°C to +125°C
–55°C to +125°C
–55°C to +125°C
–55°C to +125°C
–55°C to +125°C
–55°C to +125°C
20
25
33.3
20
25
30
20
25
30
20
25
30
50
40
30
50
40
33.3
50
40
33.3
50
40
33.3
223-Lead Ceramic Pin Grid Array
223-Lead Ceramic Pin Grid Array
223-Lead Ceramic Pin Grid Array
223-Lead Ceramic Pin Grid Array
223-Lead Ceramic Pin Grid Array
223-Lead Ceramic Pin Grid Array
223-Lead Ceramic Pin Grid Array
223-Lead Ceramic Pin Grid Array
223-Lead Ceramic Pin Grid Array
223-Lead Ceramic Pin Grid Array
223-Lead Ceramic Pin Grid Array
223-Lead Ceramic Pin Grid Array
C1601c–5–8/94
ORDERING GUIDE
PRINTED IN U.S.A.
*G = Ceramic Pin Grid Array.
–32–
REV. C