ADSP-21061KSZ-133 Analog Devices Inc, ADSP-21061KSZ-133 Datasheet - Page 13

ADSP-21061KSZ-133

Manufacturer Part Number

ADSP-21061KSZ-133

Description

ADSP-21061 1MBIT, 33MHz, 5v SHARC

Manufacturer

Analog Devices Inc

Series

SHARC®r

Type

Floating Pointr

Datasheet

1.ADSP-21061LKSZ-160.pdf (56 pages)

Specifications of ADSP-21061KSZ-133

Interface

Synchronous Serial Port (SSP)

Clock Rate

33MHz

Non-volatile Memory

External

On-chip Ram

128kB

Voltage - I/o

5.00V

Voltage - Core

5.00V

Operating Temperature

0°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

240-MQFP, 240-PQFP

Package

240MQFP

Numeric And Arithmetic Format

Floating-Point

Maximum Speed

33 MHz

Ram Size

128 KB

Device Million Instructions Per Second

33 MIPS

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

BOSTOCK HK LIMITED

Part Number:

ADSP-21061KSZ-133

Manufacturer:

Analog Devices Inc

Quantity:

10 000

Current page: 13 of 56
Download datasheet (4Mb)

TARGET BOARD CONNECTOR FOR EZ-ICE PROBE

The ADSP-2106x EZ-ICE Emulator uses the IEEE 1149.1 JTAG

test access port of the ADSP-2106x to monitor and control the

target board processor during emulation. The EZ-ICE probe

requires the ADSP-2106x’s CLKIN, TMS, TCK, TDI, TDO, and

GND signals be made accessible on the target system via a

14-pin connector (a 2-row, 7-pin strip header) such as that

shown in

connector for chip-on-board emulation. You must add this con-

nector to your target board design if you intend to use the

ADSP-2106x EZ-ICE. The total trace length between the EZ-

ICE connector and the farthest device sharing the EZ-ICE JTAG

pin should be limited to 15 inches maximum for guaranteed

operation. This length restriction must include EZ-ICE JTAG

signals that are routed to one or more ADSP-2106x devices, or a

combination of ADSP-2106x devices and other JTAG devices

on the chain.

The 14-pin, 2-row pin strip header is keyed at the Pin 3 loca-

tion—Pin 3 must be removed from the header. The pins must be

0.025 inch square and at least 0.20 inches in length. Pin spacing

should be 0.1 × 0.1 inches. Pin strip headers are available from

vendors such as 3M, McKenzie, and Samtec. The BTMS, 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

board testing, tie BTRST to GND and tie or pull up BTCK to

up (through BTRST on the connector) or held low for proper

operation of the ADSP-2106x. None of the Bxxx pins (Pins 5, 7,

9, and 11) are connected on the EZ-ICE probe.

Figure 5. Target Board Connector For ADSP-2106x EZ-ICE Emulator

. The TRST pin must be asserted (pulsed low) after power-

5. If you are not going to use the test access port for

Figure

KEY (NO PIN)

5. The EZ-ICE probe plugs directly onto this

BTRST

BTMS

BTCK

GND

BTDI

GND

(Jumpers in Place)

TOP VIEW

EMU

GND

TMS

TCK

TRST

TDI

TDO

Rev. C | Page 13 of 56 | July 2007

The JTAG signals are terminated on the EZ-ICE probe as shown

Table 3. Core Instruction Rate/CLKIN Ratio Selection

Figure 6

contain multiple ADSP-2106x processors.

Connecting CLKIN to Pin 4 of the EZ-ICE header is optional.

The emulator only uses CLKIN when directed to perform oper-

ations such as starting, stopping, and single-stepping multiple

ADSP-2106xs in a synchronous manner. If you do not need

these operations to occur synchronously on the multiple proces-

sors, simply tie Pin 4 of the EZ-ICE header to ground.

If synchronous multiprocessor operations are needed and

CLKIN is connected, clock skew between the multiple

ADSP-21061 processors and the CLKIN pin on the EZ-ICE

header must be minimal. If the skew is too large, synchronous

operations may be off by one or more cycles between proces-

sors. For synchronous multiprocessor operation TCK, TMS,

CLKIN, and EMU should be treated as critical signals in terms

of skew, and should be laid out as short as possible on your

board. If TCK, TMS, and CLKIN are driving a large number of

ADSP-21061s (more than eight) in your system, then treat them

as a “clock tree” using multiple drivers to minimize skew. (See

Figure 7

tion” in the “High Frequency Design Considerations” section of

the ADSP-21061 SHARC User’s Manual, Revision 2.1.)

If synchronous multiprocessor operations are not needed (i.e.,

CLKIN is not connected), just use appropriate parallel termina-

tion on TCK and TMS. TDI, TDO, EMU, and TRST are not

critical signals in terms of skew.

For complete information on the SHARC EZ-ICE, see the

ADSP-21000 Family JTAG EZ-ICE User's Guide and Reference.

Signal

TMS

TCK

TRST

TDI

TDO

CLKIN

EMU

TRST is driven low until the EZ-ICE probe is turned on by the emulator at software

startup. After software startup, is driven high.

Table

shows JTAG scan path connections for systems that

below and “JTAG Clock Tree” and “Clock Distribu-

Termination

Driven Through 22 Ω Resistor (16 mA Driver)

Driven at 10 MHz Through 22 Ω Resistor (16 mA

Driver)

Active Low Driven Through 22 Ω Resistor (16 mA

Driver) (Pulled Up by On-Chip 20 kΩ Resistor)

Driven by 22 Ω Resistor (16 mA Driver)

One TTL Load, Split Termination (160/220)

Active Low, 4.7 kΩ Pull-Up Resistor, One TTL Load

(Open-Drain Output from the DSP)

ADSP-21061/ADSP-21061L

ADSP-21061KSZ-133 Analog Devices Inc, ADSP-21061KSZ-133 Datasheet - Page 13

ADSP-21061KSZ-133

Specifications of ADSP-21061KSZ-133

Available stocks

Related parts for ADSP-21061KSZ-133