Fujitsu MAG3182FC User Manual

MAF3364FC SERIES

MAG3182FC, MAG3091FC SERIES

DISK DRIVES

FIBRE CHANNEL INTERFACE

PRODUCT MANUAL

C141-E078-02EN

This page is intentionally left blank.

FOR SAFE OPERATION

Handling of This manual

This manual contains important information for using this product. Read thoroughly before

using the product. Use this product only after thoroughly reading and understanding especially

the section “Important Alert Items” in this manual. Keep this manual handy, and keep it

carefully.

FUJITSU makes every effort to prevent users and bystanders from being injured or from suffering

damage to their property. Use the product according to this manual.

Functional Limitations

There may be certain functional limitations concerning the specifications and functions of the

products covered by this manual depending on the equipment version, especially concerning the

following functions.

Versions in which there functions can be used will be communicated through “ENGINEERING

CHANGE REQUEST/NOTICE”, issued by Fujitsu.

Function

Equipment Version Which Supports These Functions

Equipment EPROM Standard INQUIRY Data Product

Version No. Version No. Revision (ASCII)

READ RAM Command

WRITE RAM Command

These commands cannot be used in the current version.

(Proceed to the Copyright Page)

C141-E078-02EN

iii

Related Standards

Specifications and functions of products covered by this manual comply with the following

standards.

Standard (Text) No.

Name

Enacting Organization

NCITS TR-19

FIBRE CHANNEL PRIVATE LOOP

SCSI DIRECT ATTACH (FC-PLDA)

American National

Standards Institute

(ANSI)

ANSI

X3.230-1994

X3.297-1996

X3.272-199X

X3.269-199X

FIBRE CHANNEL PHYSICAL AND

SIGNALING INTERFACE (FC-PH)

American National

Standards Institute

(ANSI)

FIBRE CHANNEL PHYSICAL AND

SIGNALING INTERFACE-2 (FC-PH-2) Standards Institute

(ANSI)

American National

FIBRE CHANNEL ARBITRATED

LOOP (FC-AL)

American National

Standards Institute

(ANSI)

FIBRE CHANNEL PROTOCOL FOR American National

SCSI (SCSI-FCP)

Standards Institute

(ANSI)

C141-E078-02EN

PREFACE

This manual describes the MAF3364FC, MAG3182FC and MAG3091FC (hereafter, MAG series) series

3.5-inch fixed disk drives with an embedded fibre-channel controller.

This manual details the specifications and functions of the above disk drive, and gives the requirements

and procedures for installing it into a host computer system.

This manual is written for users who have a basic understanding of fixed disk drives and their use in

computer systems. The MANUAL ORGANIZATION section describes organization and scope of this

manual.

Chapter 1

GENERAL DESCRIPTION

This chapter introduces the MAF3364FC and MAG series disk drives and discusses their standard

features, hardware, and system configuration.

Chapter 2

SPECIFICATIONS

This chapter gives detailed specifications of the MAF3364FC and MAG series disk drives and their

installation environment.

Chapter 3

DATA FORMAT

This chapter describes the data structure of the disk, the address method, and what to do about media

defects.

Chapter 4

INSTALLATION REQUIREMENTS

This chapter describes the basic physical and electrical requirements for installing MAF3364FC and

MAG series disk drives.

Chapter 5

INSTALLATION

This chapter explains how to install MAF3364FC and MAG series disk drives. It includes the notice and

procedures for setting device number and operation modes, mounting the disk drive, and confirming drive

operation.

Chapter 6

DIAGNOSIS and MAINTENANCE

This chapter describes the automatic diagnosis, and maintenance of the MAF3364FC and MAG series

disk drives.

APPENDICES A to D

The appendixes give supplementary information, including the locations of mounting connectors, a list of

setting items, the signal assignments of interface connectors, lists of model names and product numbers,

and SCSI interface functions.

Glossary

Abbreviations

C141-E078-02EN

CONVENTIONS

This manual uses the following conventions for alerts to prevent physical or property damages to users or

by standards.

DANGER

DANGER indicates that personal injury will occur if the user does not perform the procedure correctly.

WARNING

WARNING indicates that personal injury could occur if the user does not perform the procedure

correctly.

CAUTION

CAUTION indicates that either minor or moderate personal injury may occur if the user does not

perform the procedure correctly.

NOTICE

NOTICE indicates that inconvenience to the user such as damages to the product, equipment, data, and/or

other property may occur if the user does not pay attention or perform the procedure correctly.

IMPORTANT

IMPORTANT indicates information that the helps the user use the product more effectively.

Indicates

This manual indicates;

Decimal number: Indicates as it is.

Hexadecimal number: Indicates as X’17B9’, 17B9h, or 17B9H

Binary number: Indicates as “010” or 010b

C141-E078-02EN

DISCLAIMER

Failure of the MAF3364FC and MAG series intelligent disk drive is defined as a failure requiring

adjustments, repairs, or replacement. Fujitsu is not responsible for drive failures caused by misuse by the

user, poor environmental conditions, power trouble, host problems, cable failures, or any failure not

caused by the drive itself.

The suffix of the model name of this disk drive varies depending on the two device types and storage

capacity (Note 1). However, in this manual, the typical model names (Note 2) are used unless otherwise

noted. These disk drives may be called intelligent disk drives (IDD), drives, or devices in this manual.

Note 1:

Model names

M AF 3 182 FC

Interface types

FC: Fibre-channel

Formatted capacity (100 MB units)

Disk size

Type

3: 3 inch

AF: Full height (10,025 rpm)

AG: 1-inch height (10,025 rpm)

Note 2:

Type model name

MAF3364

Model name

MAF3364FC

MAG3182FC

MAG3091FC

MAG3182

MAG3091

C141-E078-02EN

vii

SAFETY PRECAUTIONS

List of Important Precautions

This manual includes the following important precautions:

CAUTION

Indicates that either minor or moderate personal injury may occur or may cause

damages to this product itself or property of other users if the user does not perform

the procedure correctly.

Work division

Precaution

Page

4-8

Assembly/installation

Damage to drive

A hole or screw portion as shown in Figure 4.8 is used for adjusting air

pressure balance between inside and outside the DE. Do not fill with a

seal or label.

Seals on the DE prevent the DE inside from the dust. Do not damage or

peel off labels.

Damage

5-15

1. When dismounting the drive which is mounted on the system while

power is supplied to it.

•

The drive to be dismounted must be separated from the loop.

Dismounting the drive which is not separated from the loop may

cause an unexpected error.

•

If the drive is not separated from the loop, issue an LPB to the

drive from the initiator in a primitive sequence of the order set.

It is recommended to stop the spindle motor prior to this loop

separation operation. The spindle motor can be stopped by a

START/STOP command. It takes about 30 seconds for the

spindle motor to stop completely.

•

Then, dismount the drive using the drive mounting/dismounting

mechanism, etc. of the system. If the drive is dismounted while

the spindle motor is running, special care is required to avoid

excessive vibration or shock to the drive. It is recommended to

stop the operation once the SCA connector breaks off contact

and wait until the spindle motor stops (about 30 seconds) before

dismount the drive.

•

When storing or transporting the drive, put it in an antistatic

bag. (Shown in Section 5.1).

2. When dismounting the drive which is mounted on the system while

power is not supplied to it

•

Do not move the drive until the drive stops completely (about 30

seconds if the spindle motor was stopped by a START/STOP

UNIT command, and about 30 seconds after powering-off when

the power was simply turned off).

•

Then, dismount the drive using the drive mounting/dismounting

mechanism, etc. of the system.

When storing or transporting the drive, put it in an antistatic

bag. (Shown in Section 5.1).

viii

C141-E078-02EN

Work division

Precaution

Page

6-4

Data loss

When the SEND DIAGNOSTIC command terminates with the CHECK

CONDITION status, the INIT must collect the error information using

the REQUEST SENSE command. The RECEIVE DIAGNOSTIC

RESULTS command cannot read out the error information detected in

the self-diagnostics.

Damage

6-5

6-6

Do not open the DE in the field because it is completely sealed.

Data loss

Save data stored on the disk drive before requesting repair. Fujitsu does

not assume responsibility if data is destroyed during servicing or repair.

C141-E078-02EN

MANUAL ORGANIZATION

FIBRE CHANNEL

INTERFACE

PRODUCT

1. General Description

2. Specifications

3. Data Format

MANUAL

4. Installation Requirements

5. Installation

(This manual)

6. Diagnostics and Maintenance

FIBRE CHANNEL

INTERFACE

1. Fibre Channel Interface

2. Command Processing

SPECIFICATIONS

3. Data Buffer Management

4. Command Specification

5. Sense Data and Error Recovery Procedure

6. Disk Medium Management

FIBRE CHANNEL

INTERFACE

MAINTENANCE

MANUAL

1. Specifications and Equipment Configuration

2. Maintenance and Diagnostic

3. Error Analysis

4. Removal and Replacement Procedures

5. Principle of Operation

C141-E078-02EN

CONTENTS

page

GENERAL DESCRIPTION.............................................................................1-1

CHAPTER 1

1.1

1.2

1.3

Standard Features.............................................................................................................1-2

Hardware Structure ..........................................................................................................1-5

System Configuration.......................................................................................................1-8

CHAPTER 2

SPECIFICATIONS...........................................................................................2-1

2.1

Hardware Specifications...................................................................................................2-1

Model name and part number...........................................................................................2-1

Function specifications.....................................................................................................2-2

Environmental specifications ...........................................................................................2-4

Error rate .........................................................................................................................2-5

Reliability ........................................................................................................................2-5

2.1.1

2.1.2

2.1.3

2.1.4

2.1.5

CHAPTER 3

DATA FORMAT..............................................................................................3-1

3.1

Data Space.......................................................................................................................3-1

Cylinder configuration .....................................................................................................3-1

Alternate spare area .........................................................................................................3-4

Track format ....................................................................................................................3-5

Sector format ...................................................................................................................3-7

Format capacity................................................................................................................3-9

Logical Data Block Addressing........................................................................................3-10

Defect Management .........................................................................................................3-11

Defect list.........................................................................................................................3-11

Alternate block allocation.................................................................................................3-11

3.1.1

3.1.2

3.1.3

3.1.4

3.1.5

3.2

3.3

3.3.1

3.3.2

CHAPTER 4

INSTALLATION REQUIREMENTS .............................................................4-1

4.1

Mounting Requirements...................................................................................................4-1

External dimensions.........................................................................................................4-1

Mounting.........................................................................................................................4-4

Notes on mounting...........................................................................................................4-4

Power Supply Requirements.............................................................................................4-10

Connection Requirements ................................................................................................4-11

Connector ........................................................................................................................4-11

4.1.1

4.1.2

4.1.3

4.2

4.3

4.3.1

C141-E078-02EN

4.3.2

4.3.3

Interface connector...........................................................................................................4-12

Recommended components for connection .......................................................................4-12

CHAPTER 5

INSTALLATION..............................................................................................5-1

5.1

Notes on Handling Drives ................................................................................................5-1

Setting .............................................................................................................................5-3

Loop ID setting ................................................................................................................5-3

Mode settings...................................................................................................................5-3

Mounting Drives..............................................................................................................5-4

Mounting procedures .......................................................................................................5-4

Confirming Operations after Installation and Preparation for Use ....................................5-5

Confirming initial operations ...........................................................................................5-5

Checking connection........................................................................................................5-6

Formatting.......................................................................................................................5-9

Setting parameters ...........................................................................................................5-10

Dismounting Drive...........................................................................................................5-15

5.2

5.2.1

5.2.2

5.3

5.3.1

5.4

5.4.1

5.4.2

5.4.3

5.4.4

5.5

CHAPTER 6

DIAGNOSTICS AND MAINTENANCE.........................................................6-1

6.1

Diagnostics ......................................................................................................................6-1

Self-diagnostics................................................................................................................6-1

Test programs ..................................................................................................................6-4

Maintenance Information.................................................................................................6-5

Maintenance requirements ...............................................................................................6-5

Revision numbers.............................................................................................................6-7

6.1.1

6.1.2

6.2

6.2.1

6.2.2

APPENDIX A LOCATIONS OF CONNECTORS..................................................................A-1

A.1 Locations of Connectors...................................................................................................A-2

APPENDIX B CONNECTOR SIGNAL ALLOCATION .......................................................B-1

B.1 Interface (FC-SCA) Connector Signal Allocation.............................................................B-2

APPENDIX C MODEL NAMES AND PRODUCT NUMBERS ............................................C-1

C.1 Model Names and Product Numbers.................................................................................C-2

APPENDIX D FIBRE CHANNEL INTERFACE FUNCTIONS ............................................D-1

D.1

Fibre Channel Interface Function Specifications...............................................................D-2

xii

C141-E0782EN

Glossary........................................................................................................................................GL-1

Abbreviations...............................................................................................................................AB-1

C141-E078-02EN

xiii

FIGURES

page

1.1

1.2

1.3

1.4

3.1

3.2

3.3

3.4

3.5

3.6

3.7

3.8

4.1

4.2

4.3

4.4

4.5

4.6

4.7

4.8

4.9

4.10

4.11

4.12

5.1

5.2

6.1

6.2

A.1

MAF3364FC outer view...................................................................................................1-5

MAG series outer view.....................................................................................................1-5

Disk/head configuration ...................................................................................................1-6

FC-AL system configuration ............................................................................................1-8

Cylinder configuration .....................................................................................................3-2

Spare area in cylinders.....................................................................................................3-5

Alternate cylinder ............................................................................................................3-5

Track format ....................................................................................................................3-6

Track skew/cylinder skew ................................................................................................3-7

Sector format ...................................................................................................................3-7

Alternate block allocation by FORMAT UNIT command .................................................3-13

Alternate block allocation by REASSIGN BLOCKS command.........................................3-14

External dimensions (MAF3364FC).................................................................................4-2

External dimensions (MAG series)...................................................................................4-3

IDD orientation................................................................................................................4-4

Mounting frame structure.................................................................................................4-5

Limitation of side-mounting.............................................................................................4-6

Surface temperature measurement points..........................................................................4-7

Service clearance area ......................................................................................................4-8

Air pressure adjustment hole............................................................................................4-9

Current waveform (+12 VDC)..........................................................................................4-10

AC noise filter (recommended) ........................................................................................4-11

Connector location of SCA2 type interface model.............................................................4-11

SCA2 type interface connector .........................................................................................4-12

Checking the IDD connection (A)....................................................................................5-7

Checking the IDD connection (B) ....................................................................................5-8

Revision label...................................................................................................................6-7

Indicating revision numbers.............................................................................................6-8

Locations of connectors................................................................................................................A-2

xiv

C141-E078-02EN

TABLES

page

2.1

2.2

3.1

3.2

3.3

4.1

5.1

6.1

B.1

C.1

D.1

Function specifications.....................................................................................................2-2

Environmental/power requirements..................................................................................2-4

Zone layout and track capacity (MAF3364FC) .................................................................3-3

Zone layout and track capacity (MAG series) ...................................................................3-3

Format capacity................................................................................................................3-9

Surface temperature check point.......................................................................................4-7

Motor start mode..............................................................................................................5-3

Self-diagnostic functions..................................................................................................6-1

FC-SCA connector: CN1.................................................................................................B-2

MAF and MAG series model names and product numbers ...............................................C-2

Fibre channel interface function specifications .................................................................D-2

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CHAPTER 1

GENERAL DESCRIPTION

1.1 Standard Features

1.2 Hardware Structure

1.3 System Configuration

This chapter describes the feature and configuration of the intelligent disk drives (IDD).

MAF3364FC and MAG series intelligent disk drives (IDDs) are high performance large capacity 3.5-inch

fixed disk drives with an embedded fibre-channel controller.

The interface between the MAF3364FC/MAG series intelligent disk drives and host system conforms to

the fibre channel PLDA standard [NCITS TR-19 FIBRE CHANNEL PRIVATE LOOP SCSI DIRECT

ATTACH (FC-PLDA] which covers from the fibre channel physical layer to SCSI command protocol.

A combination of the high transfer speed and long-distance transfer of the fibre channel and high function

command set of the MAF3364FC and MAG series intelligent disk drives will facilitate construction of a

high performance and highly reliable disk subsystem with large storage capacity.

With respect to data formatting, it is possible to change it to a format different from the one at the time of

shipment by performing reinitialization on the installed system.

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1 - 1

1.1

Standard Features

(1)

Compactness

The IDD has the FC-AL controller which supports the Arbitrated Loop (FC-AL) of the fibre

channel modes defined by the ANSI standard, embedded in the 3.5-inch fixed disk drive form

factor.

(2)

FC-AL standard

The IDD provides not only FC-AL basic functions but also the following features:

•

Arbitration

Data frame CRC function

Command set which meets the logical specification of the SCSI CCS (Common Command

Set for Direct Access Device) requirements (Rev. 4.B)

The SCSI commands can manipulate data through logical block addressing regardless of the

physical characteristics of the disk drive. This allows software to accommodate future expansion

of system functions.

(3)

(4)

Dual port support

In order to support dual ports, the IDD is equipped with two pairs of fibre channel

driver/receiver.

High speed data transfer

The data transfer rate on the fibre channel loop is 106.25 MB/s maximum. In addition, the large

capacity data buffer of the IDD allows the user to make full use of the high speed data transfer

capability of the fibre channel loop.

(5)

(6)

High speed spindle motor

The IDD increases the number of revolutions of the spindle motor from conventional 7,200 rpm

to 10,025 rpm. Increasing the number of revolutions of the spindle motor will make it possible to

improve the data transfer rate and reduce the rotation wait time.

Continuous block processing

The addressing method of data blocks is logical block address. The initiator can access data by

specifying block number in a logically continuous data space without concerning the physical

structure of the track or cylinder boundaries.

The continuous processing up to [64K-1] blocks in a command can be achieved, and IDD can

perform continuous read/write operation when processing data blocks on several tracks or

cylinder.

1 - 2

C141-E078-02EN

(7)

4MB programmable multi-segment data buffer

Data is transferred between fibre-channel loop and disk media through the embedded 4MB data

buffer in the IDD. This buffer can be divided into maximum 32 areas. This feature provides the

suitable usage environment for users.

Since the initiator can control the disconnect/reconnect timing on the fibre-channel loop by

specifying the condition of stored data to the data buffer or empty condition of the data buffer, the

initiator can perform the effective input/output operations with utilizing high data transfer

capability of the fibre-channel regardless of actual data transfer rate of the disk drive.

(8)

Read-ahead cache feature

After executing the READ command, the IDD reads automatically and stores (prefetches) the

subsequent data blocks into the data buffer (Read-ahead caching).

The high speed sequential data access can be achieved by transferring the data from the data

buffer without reaccessing the disk in case the subsequent command requests the prefetched data

blocks.

(9)

Command queuing feature

The IDD can queue maximum 63 commands, and optimizes the issuing order of queued

commands by the reordering function. This feature realizes the high speed processing.

(10)

(11)

Reserve and release functions

The IDD can be accessed exclusively in the multi-host or multi-initiator environment by using

the reserve and release functions.

Enclosure service function

The IDD supports an enclosure service interface (ESI) compliant with the SFF-8067. This

interface provides the function of setting/readin enclosure service information using the SCSI-3

enclosure service command set (SES).

(12)

(13)

Error recovery

The IDD can try to recover from errors in fibre-channel loop or the disk drive using its powerful

retry processing. If a recoverable data check occurs, error-free data can be transferred to the

initiator after being corrected in the data buffer. The initiator software is released from the

complicated error recover processing by these error recovery functions of the IDD.

Automatic alternate block reassignment

If a defective data block is detected during read, the IDD can automatically reassign its alternate

data block.

C141-E078-02EN

1 - 3

(14)

(15)

Programmable data block length

Data can be accessed in fixed-block length units. The data block length is programmable, and

can at initializing with a multiple of four for the 512 to 528 bytes.

Defective block slipping

A logical data block can be reallocated in a physical sequence by slipping the defective data block

at formatting. This results in high speed contiguous data block processing without a revolution

delay due to defective data block.

(16)

(17)

High speed positioning

A rotary voice coil motor achieves fast positioning.

Large capacity

A large capacity can be obtained from 3-inch disk drives by dividing all cylinders into several

partitions and changing the recording density on each partition (constant density recording). The

disk subsystem with large capacity can be constructed in the good space efficiency.

(18)

(19)

Start/Stop of spindle motor

Using the SCSI command, the host system can start and stop the spindle motor.

Diagnosis

The IDD has a diagnostic capability which checks internal controller functions and drive

operations to facilitate testing and repair.

(20)

(21)

Low power consumption

By using highly integrated LSI components, the power consumption of the IDD is very low, and

this enables the unit to be used in wide range of environmental conditions.

Low noise and low vibration

The noise level is low: Approx. 4.2 bels for the MAF3364FC and 4.0 bels for the MAG series.

This makes it ideal for office use. The IDD has rubber vibration isolators, which minimize the

transfer of vibration.

(22)

Microcode downloading

The IDD implements the microcode download feature. This feature achieves easy maintainability

of the IDD and function enhancing.

1 - 4

C141-E078-02EN

1.2

Hardware Structure

An outer view of the IDD is given in Figures 1.1 and 1.2. The IDD is composed of the disk,

head, spindle motor, hermetically sealed disk enclosure (DE) with actuator and air circulation

filter, as well as read/write pre-amp with the print card unit (PCA) of the controller.

Figure 1.1 MAF3364FC outer view

Figure 1.2 MAG series outer view

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1 - 5

(1)

Disks

The disks have an outer diameter of 84 mm (3.31 inch) and inner diameter of 25 mm (0.98 inch).

The disks are good for at least 15,000 contact starts and stops. Each model contains following

number of disks.

MAF3364:10

MAG3182:5

MAG3091:3

(2)

Heads

The MR (Magnet - Resistive) of the CSS (contact start/stop) type heads are in contact with the

disks when the disks are not rotating, and automatically float when the rotation is started. Figure

1.5 shows the configuration of disks and heads.

MAG3091

MAF3364

MAG3182

Head No.

Figure 1.3 Disk/head configuration

(3)

Spindle motor

The disks are rotated by a direct-drive hall-less DC motor. The motor speed is controlled by a

feedback circuit using the counter electromotive current to precisely maintain the speed at ±0.5%

of the specified speed.

1 - 6

C141-E078-02EN

(4)

Actuator

The actuator, which uses a rotary voice coil motor (VCM), consumes little power and generates

little heat. The head assembly at the end of the actuator arm is controlled and positioned via

feedback of servo information in the data.

The actuator positions heads on the CCS zone over the disk and is locked by the mechanical lock

when the power is off or the spindle motor is stopped.

(5)

Air circulation (recirculation filter, breather filter)

The heads, disks, and actuator are hermetically sealed inside a disk enclosure (DE) to keep out

dust and other pollutants. The DE has a closed-loop air recirculation system. Using the

movement of the rotating disks, air is continuously cycled through a filter. This filter will trap

any dust generated inside the enclosure and keep the air inside the DE contaminant free. To

prevent negative pressure in the vicinity of the spindle when the disks begin rotating, a breather

filter is attached. The breather filter also equalizes the internal air pressure with the atmospheric

pressure due to surrounding temperature changes.

(6)

(7)

Read/write circuit

The read/write circuit uses head LSI chips and extended partial response class 4 maximum

likelihood (EPR4ML) modulator and demodulator circuit to prevent errors caused by external

noise, thus improving data reliability.

Controller circuit

The controller circuit uses LSIs to increase the reliability and uses a high speed microprocessing

unit (MPU) to increase the performance of the SCSI controller.

C141-E078-02EN

1 - 7

1.3

System Configuration

As the fibre channel mode, the ANSI standard defines three modes: Arbitrated Loop, Fabric and

Point-to-Point. This drive supports Arbitrated Loop (FC-AL). Figure 1.4 shows an example of

the system configuration.

Port B

Port A

Port B

Port A

Initiator

(Node-1)

Drive

(Node-2)

Port B

Port A

Port B

Port A

Drive

(Node-4)

Drive

(Node-3)

Figure 1.4 FC-AL system configuration

The mode of connection of all devices to the fibre channel is called “node.” The drive and

initiator correspond to the node shown in Figure 1.4. Each node has at least one port called “N-

port.” In the FC-AL, a port is particularly called “node loop (NL) port.” The MAF3364FC and

MAG series have two ports; one is connected to one FC-AL and a maximum of 126 NL ports can

be connected to one loop.

(1)

Loop configuration

One port incorporates a transmit circuit and receive circuit. Information is transmitted/received

by differential signals via electric signal lines. This pair of signal lines is called a link. Since

signals on a link are transmitted in one direction, wiring must be conducted so that it may form a

loop connection on the system.

In the case of the FC-AL interface, information is transmitted/received via each node connected

on a loop. Accordingly, if the power supply is off at a node connected to the loop or if interface

signals cannot be transmitted/received normally, the loop will no longer function. To avoid such

a nonconformity, a circuit called “port bypass circuit” is generally provided on the back plane of

the system. BC in Figure 1.4 shows this port bypass circuit.

(2)

Node addressing

Each node on the fibre channel loop is assigned its specific model number (SEL ID). The SEL

ID of the drive is set at the signal level on the back plane through 7 signals from SEL_0 to

SEL_6 of the SCA interface connector (CN1). In signal bit weighting, SEL_6 is the MSB

indicating 2⁶and SEL_0 is the LSB indicating 2⁰.

The SEL ID setting of the drive ranges from #0(x‘00’) to #125(x‘7D’).

1 - 8

C141-E078-02EN

CHAPTER 2

SPECIFICATIONS

2.1 Hardware Specifications

This chapter describes specifications of the IDD.

2.1

Hardware Specifications

2.1.1

Model name and part number

The IDD is provided with various models according to the device type, device capacity, etc.

For the model name (type) and product number, refer to the model name/product number list

Appendix D.

With respect to data formatting, it is possible to change it to a format different from the one set at

the time of shipment by performing reinitialization on the installed system.

C141-E078-02EN

2 - 1

2.1.2

Function specifications

Table 2.1 shows the function specifications of the IDD.

Table 2.1

Function specifications

Specification

MAG3182

18.2 GB

23.0 GB

Item

MAF3364

MAG3091

Formatted capacity/device (*1)

Unformatted capacity/device

Number of disks

36.4 GB

9.1 GB

45.6 GB

11.5 GB

Number of heads

Number of cylinders (*2)

Formatted capacity/track

Number of rotations (rpm)

Average latency time

10,200

9,866

139,776 to 215,040

10,025±0.5%

2.99 ms

143,872 to 215,040

Seek time (*3) Minimum

(Read/Write)

0.7 ms (Read)/

0.9 ms (Write)

5.7 ms (Read)/

6.2 ms (Write)

12.0 ms (Read)/

13.0 ms (Write)

0.7 ms (Read)/

1.1 ms (Write)

5.2 ms (Read)/

5.8 ms (Write)

11.0 ms (Read)/

12.0 ms (Write)

Average

Maximum

Start/stop time Start time

30 s typ. (60 s max.)

30 s typ.

(*4)

Stop time

Recording mode

16/17 EPR4ML

Recording density

Track density

283,000 bpi

275,000 bpi

13,500 TPI

External

dimensions

Height

Width

Depth

41.3 mm

101.6 mm

146.0 mm

25.4 mm

101.6 mm

146.0 mm

Weight

1.1 kg

17 W

0.7 kg

13 W

Power consumption (*5)

Interface

Cable length: 30 m max.

29.5 to 45.0 MB/s

106.25 MB/s max.

512 to 528 byte

Data transfer

rate

Disk drive

FC-AL

Logical data block length

SCSI command specification

SCSI-2 (ANSI X3T9.2/86-109 Rev 10h) command support

SCSI-3 command partial support

Fujitsu-specific command

4 MB FIFO ring buffer, multi-segment buffer: Segment count 1 to 32,

Read-ahead cache

Data buffer

(*1)

(*2)

(*3)

The formatted capacity can be changed by changing the logical block length and using spare sector

space. See Chapter 3 for the further information.

The number of user cylinders indicates the max., and includes the alternate cylinder. The number

of user cylinders and alternate cylinders can be specified at format of the IDD.

The seek time is as follows:

C141-E078-02EN

2 - 2

MAG3364FC Seek Time

MAG series Seek Time

(*4)

(*5)

The start time is the time from power on or start command to when the IDD is ready, and stop time

is the time for disks to completely stop from power off or stop command.

This value indicates at ready mode.

C141-E078-02EN

2 - 3

2.1.3

Environmental specifications

Table 2.2 lists environmental and power requirements.

Table 2.2

Environmental/power requirements

Specification

MAG3182FC

5 to 50°C

Item

MAF3364FC

MAG3091FC

Temperature (*1) Operating

Non-operating

– 40 to 60°C

5 to 55°C

DE surface temperature at operating

Gradient

15°C/h or less

20 to 80%RH

Relative humidity Operating

Non operating

Packaged (inside of a week) 5 to 90%RH

Maximum wet bulb temperature

Operating (*3)

29°C (no condensation)

Vibration (*2)

Shock (*2)

0.3 mm (5 to 20Hz)/0.5G (20 to 250 Hz) or less

3.1 mm (5 to 20Hz)/5G (20 to 250Hz) or less

Packaged 3.1 mm (5 to 20Hz)/5G (20 to 250Hz) or less

Non-operating (*4)

Operating

20G (2 ms)

Non-operating

Operating

175G (2 ms)

Altitute

– 60 m to 3,000 m (above sea level)

– 60 m to 12,000 m (above sea level)

(above sea level)

Non-operating

+12 VDC

±5%

Ready (Average)

Spin-up, Seek

Peak within 100 µs

at spin-up

0.95 A

2.5 A (Max)

3.2 A

0.65 A

2.5 A (Max)

3.0 A

Power

requirements

Input power (*5)

+5 VDC

±5%

Ready

1.4 A

1.7 A

1.3 A

1.6 A

Random W/R

(about 80 IOPS)

Ripple (*6)

+5 V 250 mVp-p, +12 V 250 mVp-p

(*1)

(*2)

For detail condition, see Section 4.1.

Vibration applied to the drive is measured at near the mounting screw hole on the DE base as

much as possible.

(*3)

(*4)

(*5)

(*6)

At random seek write/read and default on retry setting with log sweep vibration.

At power-off state after installation

Input voltages are specified at the connector.

High frequency noise is less than 250 mVp-p.

C141-E078-02EN

2 - 4

2.1.4

(1)

Error rate

Errors detected during initialization and replaced by alternate block assignments are not included

in the error rate. Data blocks to be accessed should be distributed over the disk medium equally.

Unrecoverable error rate

Errors which cannot be recovered within 63 retries and ECC correction should not exceed 10 per

10¹⁵bits.

(2)

Positioning error rate

Positioning errors which can be recovered by one retry should be 10 or less per 10⁸seeks.

2.1.5

Reliability

(1)

Mean Time Between Failures (MTBF)

MTBF of the IDD during its life time is 1,000,000 hours (operating: 24 hours/day, 7 days/week

average DE surface temperature: 40°C or less).

Note:

The MTBF is defined as:

Operating time (hours) at all field sites

MTBF =

The number of equipment failures (*1) from all field sites

*1 Failure of the equipment means failure that requires repair, adjustments, or replacement.

Mishandling by the operator, failures due to bad environmental conditions, power trouble, host

system trouble, cable failures, or other failures not caused by the equipment are not considered.

C141-E078-02EN

2 - 5

(2)

(3)

Mean Time To Repair (MTTR)

MTTR is the average time taken by a well-trained service mechanic to diagnose and repair a drive

malfunction. The drive is designed for a MTTR of 30 minutes or less.

Service life

The service life is depending on the environment temperature. Therefore, the user must design the

system cabinet so that the average DE surface temperature is as possible as low.

The service life under suitable conditions and treatment is as follows.

•

DE surface temperature: 40°C or less

DE surface temperature: 41°C to 45°C

DE surface temperature: 46°C to 50°C

DE surface temperature: 51°C to 55°C

DE surface temperature: 56°C and more Strengthen cooling power so that DE

surface temperature is 55°C or less.

5 years

4.5 years

4 years

3.5 years

Even if the IDD is used intermittently, the longest service life is 5 years.

Note:

The "average DE surface temperature" means the average temperature at the DE surface

throughout the year when the IDD is operating.

(4)

Data security at power failure

Integrity of the data on the disk is guaranteed against all forms of DC power failure except on

blocks where a write operation is being performed. The above does not applied to formatting

disks or assigning alternate blocks.

C141-E078-02EN

2 - 6

CHAPTER 3

DATA FORMAT

3.1 Data Space

3.2 Logical Data Block Addressing

3.3 Defect Management

This chapter explains data space definition, logical data block addressing, and defect management on the

IDD.

3.1

Data Space

The IDD manages the entire data storage area divided into the following three data spaces.

•

User space: Storage area for user data

Internal test space: Reserved area for diagnostic purposes

System space: Area for exclusive use of IDD itself

The user space allow a user access by specifying data. These space can be accessed with the

logical data block addressing method described in Section 3.2. The internal test space is used by

Read/write test of self-diagnostics test, but user can’t use direct access. The system space is

accessed inside the IDD at power-on or during the execution of a specific command, but the user

cannot directly access the system space.

3.1.1

Cylinder configuration

The IDD allocates cylinders to the user space, internal test space, and system space. Figure 3.1 is

the cylinder configuration.

Spare areas (alternate areas) for defective sectors are provided in the user space. Several sectors

in the last track of one cylinder and several cylinders (alternate cylinders) in the user space are

allocated as alternate areas according to the user's assignment (MODE SELECT command). See

Subsection 3.1.2 for details.

C141-E078-02EN

3 - 1

P: MAF3364FC = 10400

MAG series = 10066

MAC30xxxx = 8690

Figure 3.1 Cylinder configuration

Apart from the above logical configuration, the IDD intends to increase the storage capacity by

dividing all cylinders into several zones and changing a recording density of each zone. Tables

3.1 and 3.2 show the zone layout and the track capacity.

3 - 2

C141-E078-02EN

Table 3.1

Zone layout and track capacity (MAF3364FC)

Zone

Cylinder

0 to 899

900 to

1,999

2,000 to

3,019

3,020 to

3,729

3,730 to

4,029

4,030 to

4,669

4,670 to

5,189

Byte/track 267,428

267,428

420

267,428

420

260,017

405

256,665

400

249,755

390

244,019

380

Sector/track

420

Zone

Cylinder

5,190 to

5,459

5,460 to

6,459

6,460 to

7,369

7,370 to

7,929

7,930 to

8,399

8,400 to

9,519

9,520 to

10,199

Byte/track 240,931

Sector/track 376

229,596

360

218,471

340

211,617

330

205,757

320

191,178

300

181,401

281

Remarks: The sector/track capacities are expressed in values when the logical data block is 512 bytes

long.

Table 3.2

Zone layout and track capacity (MAG series)

Zone

Cylinder

0 to 679

680 to

1,559

1,560 to

2,409

2,410 to

3,139

3,140 to

3,469

3,470 to

4,119

4,120 to

4,659

Byte/track 267,428

267,428

420

267,428

420

260,410

405

256,969

400

250,231

390

244,449

381

Sector/track

420

Zone

Cylinder

4,660 to

4,939

4,940 to

5,989

5,990 to

6,919

6,920 to

7,499

7,500 to

7,979

7,980 to

9,149

9,150 to

9,865

Byte/track 241,779

Sector/track 377

229,631

360

218,894

340

211,976

330

206,169

320

191,474

300

176,273

273

Remarks: The sector/track capacities are expressed in values when the logical data block is 512 bytes

long.

(1)

User space

The user space is a storage area for user data. The data format on the user space (the length of

data block and the number of data blocks) can be specified with the MODE SELECT or MODE

SELECT EXTENDED command.

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3 - 3

The default number of cylinders in the user space is 10,200 for MAF3364FC and 9,866 for MAG

series. The user, however, can select the number of cylinders to be allocated in the user space by

specifying 10,200 for MAF3364FC and 9,866 for MAG series as the maximum and the number

of alternate cylinders + 1 as the minimum. The user can also specify the number of logical data

blocks to be placed in the user space with the MODE SELECT or MODE SELECT EXTENDED

command. When the number of logical data blocks is specified, as many cylinders as required to

place the specified data blocks are allocated in the user space.

A number starting with 0 is assigned to each cylinder required in the user space in ascending

order. If the number does not reach 10,200 (MAF3364FC) and 9,866 (MAG series), the rest of

the cylinders will not be used.

Always one alternate cylinders can be established in the user space. Alternate cylinders will be

used for alternate blocks when primary cylinders in the user space are used up. See Subsections

3.1.2 and 3.3.2 for details.

(2)

Internal test space

The Internal test space is an area for diagnostic purposes only and its data block length is always

512 byte. The internal test space consists of only 1 cylinder and outer-host cylinder (–37) is

always assigned. The user cannot change the number of cylinders in the internal test space or

their positions.

The IDD reads or writes the data block in the CE space during the self-diagnostic test specified

with the setting terminal (diagnostic mode) or a SEND DIAGNOSTIC command.

(3)

System space

The system space is an area for exclusive use of the IDD itself and the following information are

recorded. The length of the data block is always 512 bytes.

•

Defect list (P list and G list)

MODE SELECT parameter (saved value)

Statistical information (log data)

Controller control information

The above information are duplicated in several different locations for safety.

Note:

The system space is also called SA space.

3.1.2

Alternate spare area

The alternate spare area is provided in the last track of each primary cylinder in the user space,

and in the last track of the cylinder and the alternate cylinder.

3 - 4

C141-E078-02EN

The spare area in each cylinder is placed at the end of the last track as shown in Figure 3.2. These

spare sectors are located in the end of the track logically, not necessarily located at the end physically

because of track skew or cylinder skew. (Details are explained on Subsection 3.1.3.)

Size can be specified by the MODE SELECT or MODE SELECT EXTENDED command.

The number of spare sectors per cylinder can be specified exceeding 32. The default number of

spare sectors per cylinder is 20 for the MAF3364FC and MAG3182FC and 12 for the

MAG3091FC.

SPR1

Figure 3.2 Spare area in cylinders

An alternate cylinder is used when spare sectors in a cylinder are used up or 0 is specified as the

number of spare sectors in a cylinder. Several cylinders at the end of the user space are allocated

as alternate cylinders as shown in Figure 3.3.

The number of alternate cylinder is 1.

The user space and the CE space share the alternate cylinders.

Figure 3.3 Alternate cylinder

3.1.3

Track format

(1)

Physical sector allocation

Figure 3.4 shows the allocation of the physical sectors in a track. The length in bytes of each

physical sector and the number of sectors per track vary depending on the logical data block

length. The unused area (G4) exists at the end of the track in formats with most logical data

block lengths.

C141-E078-02EN

3 - 5

The interval of the sector pulse (length of the physical sector) is decided by multiple of 20MHz

free running frequency. This clock is not equal to the interval of the byte clock for each zone.

Therefore, the physical sector length cannot be described with a byte length.

119,700 CLKs^*1(20MHz)

Figure 3.4 Track format

*1: MAF3364FC, MAG series

(2)

Track skew and cylinder skew

To avoid waiting for one turn involved in head and cylinder switching, the first logical data block

in each track is shifted by the number of sectors (track skew and cylinder skew) corresponding to

the switching time. Figure 3.5 shows how the data block is allocated in each track.

At the head switching location in a cylinder, the first logical data block in track t + 1 is allocated

at the sector position which locates the track skew behind the sector position of the last logical

data block sector in track t.

At the cylinder switching location, like the head switching location, the first logical data block in

a cylinder is allocated at the sector position which locates the cylinder skew behind the last

logical sector position in the preceding cylinder. The last logical sector in the cylinder is

allocated when formatting, and is an unused spare sector.

3 - 6

C141-E078-02EN

Figure 3.5 Track skew/cylinder skew

The number of physical sectors (track skew factor and cylinder skew factor) corresponding to the

skew time varies depending on the logical data block length because the track skew and the

cylinder skew are managed for individual sectors. The IDD automatically determines appropriate

values for the track skew factor and the cylinder skew factor according to the specified logical

data block length. The value can be read out by the MODE SENSE or MODE SENSE

EXTENDED command after the track has been formatted.

3.1.4

Sector format

Each sector on the track consists of an ID field, a data field, and a gap field which separates

them. Figure 3.6 and Table 3.3 gives sector format examples.

G1:

8 bytes

17 bytes

5 bytes

6 bytes

7 bytes

8 bytes

6 bytes

PLO Sync:

TRNG1/SB1:

TRNG2/SB2:

PAD 1:

PAD 2:

PAD 3:

Figure 3.6 Sector format

C141-E078-02EN

3 - 7

Each sector on the track consists of the following fields:

Gaps (G1)

(1)

The gap length at the time of formatting (initializing) is listed in Figure 3.7. Pattern X'00' is

written on the gap field.

(2)

(3)

(4)

(5)

PLO Sync

In this field, pattern X'00' in the length in bytes listed in Figure 3.6 is written.

Trailing (TRNG)/Sync Byte (SB)

In this field, special pattern in the length in bytes listed in Figure 3.6 is written.

LBA

The logical block address is written in this field.

Data field

User data is stored in the data field of the sector. The length of the data field is equal to that of

the logical data block which is specified with a parameter in the MODE SELECT command.

Any even number between 512 to 528 bytes can be specified as the length.

(6)

(7)

(8)

(9)

BCRC

It is a 4-byte error detection code. Errors in the ID field. Single burst errors with lengths of up to

32 bits for each logical block can be detected.

ECC

24-byte data error detection/correction code for the data field. It is possible to on-the-fly correct

the single burst errors with lengths of up to 89 bits.

PAD 1

A specified length of x‘00’ pattern shown in Figure 3.6 is written in this field. This field

includes the variation by rotation and circuit delay till reading/writing.

PAD 2/PAD 3

A specified length of x‘00’ pattern shown in Figure 3.6 is written in this field. This field

contains the processing time necessary to process next sector continuously. This field have

rotational speed variation.

3 - 8

C141-E078-02EN

3.1.5

Format capacity

The size of the usable area for storing user data on the IDD (format capacity) varies according to

the logical data block or the size of the spare sector area. Table 3.3 lists examples of the format

capacity when the typical logical data block length and the default spare area are used. The

following is the general formula to calculate the format capacity.

[Number of sectors of each zone] = [number of sectors per track × number of tracks (heads) –

number of alternate spare sectors per cylinder] × [number of cylinders in the zone]

[Formatted capacity] = [total of sectors of all zones] – [number of sectors per track in last zone ×

number of tracks (heads) × number of alternate cylinders] ÷ [number of physical sectors in logical

block] × [logical data block length]

The following formula must be used when the number of logical data blocks are specified with

the parameter in the MODE SELECT or MODE SELECT EXTENDED command.

[Format capacity] = [logical data block length] × [number of logical data blocks]

The logical data block length, the maximum logical block address, and the number of the logical

data blocks can be read out by a READ CAPACITY, MODE SENSE, or MODE SENSE

EXTENDED command after initializing the disk medium.

Table 3.3

Format capacity

Model

Data heads Data block length

User blocks

71,161,520

35,694,860

17,827,698

Format capacity (GB)

MAF3364FC

MAG3182FC

MAG3091FC

512

36.43

18.27

9.12

C141-E078-02EN

3 - 9

3.2

Logical Data Block Addressing

Independently of the physical structure of the disk drive, the IDD adopts the logical data block

addressing as a data access method on the disk medium. The IDD relates a logical data block

address to each physical sector at formatting. Data on the disk medium is accessed in logical

data block units. The INIT specifies the data to be accessed using the logical data block address

of that data.

The logical data block addressing is a function whereby individual data blocks are given

addresses of serial binaries in each drive.

(1)

Block address of user space

The logical data block address number is consecutively assigned to all of the data blocks in the

user space starting with 0 to the first data block.

The IDD treats sector 0, track 0, cylinder 0 as the first logical data block. The data block is

allocated in ascending order of addresses in the following sequence (refer to Figure 3.5):

1) Numbers are assigned in ascending order to all sectors in the same track.

2) By following step 1), numbers are assigned in ascending order of tracks to all sectors in each

track in the same cylinder except the last track.

3) By following step 1), numbers are assigned to all sectors in the last track except the spare

sectors.

4) After completing steps 1) through 3) for the same cylinder, this allocation is repeated from

track 0 in the next cylinder and on to the last cylinder (cylinder p-q in Figure 3.1) except for

the alternate cylinders in ascending order of cylinder numbers.

When the logical data block is allocated, some sectors (track skew and cylinder skew) shown in

Figure 3.5 are provided to avoid waiting for one turn involving head and cylinder switching at

the location where the track or the cylinder is physically switched.

See Subsection 3.3.2 for defective/alternate block treatment and the logical data block allocation

method in case of defective sectors exist on the disk.

(2)

Alternate area

Alternate areas in the user space (spare sectors in the cylinder and alternate cylinders) are not

included in the above logical data block addresses. Access to sectors which are allocated as an

alternate block in the alternate area is made automatically by means of IDD sector slip treatment

or alternate block treatment (explained in Subsection 3.3.2), so the user does not have to worry

about accessing the alternate area. The user cannot access with specifying the data block on the

alternate area explicitly.

3 - 10

C141-E078-02EN

3.3

Defect Management

Defect list

3.3.1

Information of the defect location on the disk is managed by the defect list. The following are

defect lists which the IDD manages.

•

P list (Primary defect list): This list consists of defect location information available at the

disk drive shipment and is recorded in a system space. The defects in this list are permanent,

so the INIT must execute the alternate block allocation using this list when initializing the

disk.

D list (Data defect list): This list consists of defect location information specified in a

FORMAT UNIT command by the INIT at the initialization of the disk. This information is

recorded in the system space of the disk drive as the G list. To execute the alternate block

allocation, the FORMAT UNIT command must be specified.

C list (Certification defect list): This list consists of location information on defective blocks

which are detected by the verifying operation (certification) of the data block after the

initiation when executing the FORMAT UNIT command. The IDD generates this

information when executing the FORMAT UNIT command, and the alternate block

allocation is made upon the defective block. This information is recorded in the system space

of the disk drive as the G list.

•

G list (Growth defect list): This list consists of defective logical data block location

information specified in a REASSIGN BLOCKS command by the INIT, information on

defective logical data blocks assigned alternate blocks by means of IDD automatic alternate

block allocation, information specified as the D list, and information generated as the C list.

They are recorded in the system space on the disk drive.

The INIT can read out the contents of the P and G lists by the READ DEFECT DATA command.

3.3.2

Alternate block allocation

The alternate data block is allocated to a defective data block (= sectors) in defective sector units

by means of the defect management method inside the IDD.

The INIT can access all logical data blocks in the user space, as long as there is no error.

Spare sectors to which alternate blocks are allocated can be provided in either "spare sectors in a

cylinder" or "alternate cylinders". See Subsection 3.1.2 for details.

The INIT can specify the size and area for spare sectors by the MODE SELECT or MODE

SELECT EXTENDED command at the time of the initialization of the disk.

Both of the following are applicable to the alternate block allocation.

•

Sector slip treatment: Defective sectors are skipped and the logical data block corresponding

to those sectors is allocated to the next physical sectors. This treatment is made on the same

cylinder as the defective sector's and is effective until all spare sectors in that cylinder are

used up.

C141-E078-02EN

3 - 11

•

Alternate sector treatment: The logical data block corresponding to defective sectors is

allocated to unused spare sectors in the same cylinder or unused spare sectors in the alternate

cylinder.

The alternate block allocation is executed by the FORMAT UNIT command, the REASSIGN

BLOCKS command, or the automatic alternate block allocation. Refer to OEM Manual–SCSI

Logical Specifications–for details of specifications on these commands. The logical data block is

allocated to the next physically continued sectors after the above sector slip treatment is made.

On the other hand, the logical data block is allocated to spare sectors which are not physically

consecutive to the adjacent logical data blocks. If a command which processes several logical

data blocks is specified, the IDD processes those blocks in ascending order of logical data block.

(1)

Alternate block allocation during FORMAT UNIT command execution

When the FORMAT UNIT command is specified, the allocation of the alternate block to those

defective sectors included in the specified lists (P, G, or D) is continued until all spare sectors in

the same cylinder are used up. When they are used up, unused spare sectors in the alternate

cylinder are allocated to the subsequent sectors in the cylinder by means of alternate sector

treatment. Figure 3.7 is examples of the alternate block allocation during the FORMAT UNIT

command execution.

3 - 12

C141-E078-02EN

: n represents a logical data block number

: Defective sector

: Unused spare sector

Figure 3.7 Alternate block allocation by FORMAT UNIT command

If the data block verifying operation (certification) is not permitted (DCRT flag = 0) in the

FORMAT UNIT command, the IDD checks all initialized logical data blocks by reading them

out after the above alternate block allocation is made to initialize (format) the disk. If a defective

data block is detected during the check, the IDD generates the C list for defect location

information and allocates the alternate block to the defective data block. This alternate block

allocation is made by means of alternate sector treatment only like processing by the REASSIGN

BLOCKS command even if unused spare sectors exists in the same cylinder.

C141-E078-02EN

3 - 13

(2)

Alternate block allocation by REASSIGN BLOCKS command

When the REASSIGN BLOCKS command is specified, the alternate block is allocated to the

defective logical data block specified by the initiator by means of alternate sector treatment. If

there are unused spare sectors in the same cylinder as the specified defective logical data block,

the alternate block is allocated to these unused spare sectors. However, the alternate block is

allocated to unused spare sectors in the alternate cylinder when all spare sectors in the cylinder

are used up.

Figure 3.8 is examples of the alternate block allocation by the REASSIGN BLOCKS command.

: n represents a logical data block number

: Defective sector

: Unused spare sector

Figure 3.8 Alternate block allocation by REASSIGN BLOCKS command

3 - 14

C141-E078-02EN

(3)

Automatic alternate block allocation

If the ARRE flag in the MODE SELECT parameter permits the automatic alternate block

allocation, the IDD automatically executes the alternate block allocation and data duplication on

the defective data block detected during the READ EXTENDED command. This allocation

method is the same as with the REASSIGN BLOCKS command (alternate sector treatment).

IMPORTANT

Automatic alternate block allocation is made only once during the

execution of one command. If second defective block is detected,

the alternate block assignment processing for the first defective

block is executed but the alternate block assignment processing for

the second one is not executed and the command being executed

terminates. However, the initiator can recover the twice error by

issuing the same command again.

When an error is detected in a data block in the data area, recovery

data is rewritten and verified in automatic alternate block

allocation during the execution of the READ or READ EXTENDED

command. Alternate block allocation will not be made for the data

block if recovery is successful.

Example: Even if the data error which is recoverable by the

WRITE LONG command is simulated, automatic

alternate block allocation will not be made for the data

block.

C141-E078-02EN

3 - 15

This page is intentionally left blank.

CHAPTER 4

INSTALLATION REQUIREMENTS

4.1 Mounting Requirements

4.2 Power Supply Requirements

4.3 Connection Requirements

This chapter describes the environmental, mounting, power supply, and connection requirements.

4.1

Mounting Requirements

External dimensions

4.1.1

Figures 4.1 and 4.2 show the external dimensions of the IDD and the positions of the holes for

the IDD mounting screws.

Note:

Dimensions are in mm.

C141-E078-02EN

4 - 1

Figure 4.1 External dimensions (MAF3364FC)

4 - 2

C141-E078-02EN

Figure 4.2 External dimensions (MAG series)

C141-E078-02EN

4 - 3

4.1.2

Mounting

The permissible orientations of the IDD are shown in Figure 4.3, and the tolerance of the angle is

±5° from the horizontal plane.

(a) Horizontal –1

(b) Horizontal –2

Direction of

gravity

(d) Vertical –2

(e) Upright mounting –1

(f) Upright mounting –2

Figure 4.3 IDD orientation

4.1.3

Notes on mounting

Mounting frame structure

Special attention must be given to mount the IDD disk enclosure (DE) as follows:

(1)

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4 - 4

a) Use the frame with an embossed structure, or the like. Mount the IDD with making a

gap of 2.5 mm or more between the IDD and the frame of the system.

b) As shown in Figure 4.6, the inward projection of the screw from the IDD frame wall at

the corner must be 4 mm or less.

c) Tightening torque of screw must be secured with 6kg-cm or less.

d) Impact caused by the electric driver must be within the device specifications.

e) Must be handled on an anti-static mat.

Figure 4.4 Mounting frame structure

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4 - 5

(2)

Limitation of side-mounting

Mount the side using the screw holes at both the ends as shown in Figure 4.5. Do not use the

center hole.

Holes for

mounting

screw

Do not use these holes

Holes for mounting screw

Use these holes (No. 1 to 4)

to mount.

Figure 4.5 Limitation of side-mounting

(3)

Environmental temperature

Temperature condition at installed in a cabinet is indicated with ambient temperature measured 3

cm from the disk drive. At designing the system cabinet, consider following points.

•

Make a suitable air flow so that the DE surface temperature does not exceed 55°C.

CAUTION

An air flow with an adequate wind velocity must be maintained to

deal with much heat generated from the MAC30xxFC.

Reference value: An air flow with a wind velocity of more than 0.5

m/s is required in an environment at 40°C, and

an air flow with a wind velocity of more than

1.0m/s in an environment at 45°C (Center of DE

cover ≤ 55°C).

•

Cool the PCA side especially with air circulation inside the cabinet. Confirm the cooling

effect by measuring temperature of specific ICs and the DE. These measurement results

should be within a criteria listed in Table 4.1.

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4 - 6

Table 4.1

Surface temperature check point

No.

Measurement point

Criteria

55°C

Center of DE cover

Read channel LSI

VCM/SPM Driver

HDC

83°C

75°C

85°C

Figure 4.6

Surface temperature measurement points

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4 - 7

(4)

Service clearance area

The service clearance area, or the sides which must allow access to the IDD for installation or

maintenance, is shown in Figures 4.7.

[Surface R]

• Hole for mounting screw

[Surface P]

• Cable connection

[Surface Q]

• Hole for mounting screw

Figure 4.7 Service clearance area

(5)

(6)

External magnetic field

The drive should not be installed near the ferromagnetic body like a speaker to avoid the

influence of the external magnetic field.

Leak magnetic flux

The IDD uses a high performance magnet to achieve a high speed seek. Therefore, a leak

magnetic flux at surface of the IDD is large. Mount the IDD so that the leak magnetic flux does

not affect to near equipment.

CAUTION

Damage to drive

A hole or screw portion as shown in Figure 4.8 is used for adjusting

air pressure balance between inside and outside the DE. Do not fill

with a seal or label.

Seals on the DE prevent the DE inside from the dust. Do not

damage or peel off labels.

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4 - 8

(a) MAF3364FC

Air pressure adjustment hole

(b) MAG series

Air pressure adjustment hole

Figure 4.8 Air pressure adjustment hole

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4 - 9

4.2

Power Supply Requirements

(1)

Allowable input voltage and current

The power supply input voltage measured at the power supply connector pin of the IDD

(receiving end) must satisfy the requirement given in Subsection 2.1.3. (For other requirements,

see Items (4) and (5) below.)

(2)

Current waveform (reference)

Figure 4.9 shows the waveform of +12 VDC.

MAF3364FC

MAG series

Figure 4.9 Current waveform (+12 VDC)

(3)

(4)

Power on/off sequence

a) The order of the power on/off sequence of +5 VDC and +12 VDC, supplied to the IDD, does

not matter.

Sequential starting of spindle motors

After power is turned on to the IDD, a large amount of current flows in the +12 VDC line when the

spindle motor rotation starts. Therefore, if more than one IDD is used, the spindle motors should be

started sequentially using one of the following procedures to prevent overload of the power supply unit.

For how to set a spindle motor start control mode, see Subsection 5.3.2.

a) Issue START/STOP UNIT command at 20-second intervals to start the spindle motors. For

details of this command specification, refer to SCSI Logical Interface Specifications.

For details of this command, see "Chapter 4 Command Specification" of the Fibre Channel

Interface Specification.

b) Turn on the +12 VDC power in the power supply unit at 20-second intervals to start the

spindle motors sequentially.

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4 - 10

(5)

Noise filter

To eliminate AC line noise, a noise filter should be installed at the AC input terminal on the IDD

power supply unit. The specification of this noise filter is as follows:

•

Attenuation: 40 dB or more at 10 MHz

Circuit construction: T-configuration as shown in Figure 4.10 is recommended.

Figure 4.10 AC noise filter (recommended)

4.3

Connection Requirements

4.3.1

Connector

Figure 4.11 shows the locations of connector on the interface model.

Interface connector

Figure 4.11

Connector location of SCA2 type interface model

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4 - 11

4.3.2

Interface connector

The connector for the fibre channel loop bus is an unshielded SCA-2 connector conforming to

SCSI-3 type which has two 20-pin rows spaced 1.27 mm (0.05 inch) apart. Figure 4.12 shows the

fibre channel connector. See Section C.5 in Appendix C for signal assignments on the connector.

For details on the physical/electrical requirements of the interface signals, refer to Sections 1

Interface Specifications.

ESD contact

Figure 4.12 SCA2 type interface connector

Recommended components for connection

4.3.3

Applicable model

Name

Connector

Par number

787317-1

Manufacturer

AMP

MAF3364FC

MAG series

Interface connector

(CN1)

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4 - 12

CHAPTER 5

INSTALLATION

5.1 Notes on Handling Drives

5.2 Setting

5.3 Mounting Drives

5.4 Confirming Operations after Installation and Preparation

for Use

5.5 Dismounting Drive

This chapter describes the notes on handling drives, connections, setting switches and plugs, mounting

drives, connecting cables, confirming drive operations after installation and preparation for use, and

dismounting drives.

5.1

Notes on Handling Drives

(1)

General notes

a) Do not give the drive shocks or vibrations exceeding the value defined in the standard

because it may cause critical damage to the drive. Especially be careful when unpacking.

b) Do not leave the drive in a dirty or contaminated environment.

c) Since static discharge may destroy the CMOS semiconductors in the drive, note the following

after unpacking:

•

Use an antistatic mat and body grounding when handling the drive.

Hold the DE when handling the drive. Do not touch PCAs except for setting.

(2)

Unpackaging

a) Use a flat work area. Check that the "This Side Up" sign side is up. Handle the package on

soft material such as a rubber mat, not on hard material such as a desk.

b) Be careful not to give excess pressure to the internal unit when removing cushions.

c) Be careful not to give excess pressure to the PCAs and interface connector when removing

the drive from the antistatic bag.

d) Do not remove the sealing label or cover of the DE and screws.

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5 - 1

(3)

Installation

a) When mounting/dismounting the drive, make sure the vibration and shock requirements of

"2.1.3 Environmental Specification" are met.

b) When removing the spindle motor from the system without stopping it while power is on, pay

special attention to shock in particular until the disk drive completely stops running (about 30

seconds).

(4)

Packaging

a) Store the drive in an antistatic vinyl bag with a desiccant (silica gel).

b) It is recommended to use the same cushions and packages as those at delivery. If those at

delivery cannot be used, use a package with shock absorption so that the drive is free from

direct shocks. In this case, fully protect the PCAs and interface connector so that they are not

damaged.

c) Indicate "This Side Up" and "Handle With Care" on the outside of the package so that it is

not turned over.

(5)

Delivery

a) When delivering the drive, provide packaging and do not turn it over.

b) Minimize the delivery distance after unpacking and avoid shocks and vibrations with

cushions. For the carrying direction at delivery, use one of the mount allowable directions in

Subsection 4.1.2 (vertical direction is recommended).

(6)

Storage

a) Provide vaporproof packaging for storage.

b) The storage environment must satisfy the requirements specified in Subsection 2.1.3 when

the drive is not operating.

c) To prevent condensation, avoid sudden changes in temperature.

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5 - 2

5.2

Setting

5.2.1

Loop ID setting

When setting the fibre channel loop ID, use SEL0 to SEL6 of interface connector CN1. IN bit

weighting, SEL6 corresponds to the MSB, SEL0 to the LSB, and 126 types of X'00' to X'7D' can

be specified as loop IDs.

5.2.2

Mode settings

(1)

Motor start mode

The method for start control of the IDD spindle motor can be set in accordance with Table 5.1.

Table 5.1 Motor start mode

Setting

Signal name

Start_2/Mated

Start_1/Mated

Start mode

Connector pin

CN1-10

Open

CN1-09

Open

The drive is not connected to the system. The drive does not start

the spindle motor.

Open

GND

Open

GND

The drive is connected to the system. After recognizing the

connection, the drive starts the spindle motor upon receipt of a

START/STOP UNIT command.

The drive is connected to the system. After recognizing the

connection, the drive starts the spindle motor after a prescribed

delay time has elapsed.

The drive is connected to the system. The driver starts the spindle

motor immediately after recognizing the connection.

IMPORTANT

Set the loop ID so that there are no duplicates between devices on the same

loop.

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5 - 3

5.3

Mounting Drives

5.3.1

Mounting procedures

Since mounting the drive depends on the system cabinet structure, determine the work procedures

considering the requirements specific to each system. The general mounting method and items to

be checked are shown below.

See Subsection 4.1 for the details of requirements for installing the IDD.

1) Fix the drive in the system cabinet with four mounting screws as follows:

•

The drive has 8 mounting holes (both sides: 2 × 2, bottom: 4). Fix the drive by using

four mounting holes of both sides or the bottom. (See Figure 4.5)

Use mounting screws whose lengths inside the drive mounting frame are 4 mm or less

when the screws are tightened (see Figure 4.4).

When mounting the drive, be careful not to damage parts on the PCAs.

2) Check to ensure that the DE is not touching the frame on the system side after tightening the

screws. At least 2.5 mm of clearance is required between the DE and the frame. (Indicated

in Figure 4.4)

3) When an electric driver is in use, less than low-impact device specifications must be used.

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5 - 4

5.4

Confirming Operations after Installation and Preparation for Use

Confirming initial operations

5.4.1

This section describes the operation check procedures after power is turned on. Since the initial

operation of the IDD depends on the setting of the motor start mode, check the initial operation

by either of the following procedures.

(1)

Initial operation in the case of setting so that motor starts at powering-on

a) When power is turned on, the IDD executes initial self-diagnosis.

b) If an error is detected in initial self-diagnosis, the Fault LED lights up.

Remark:

The spindle motor may or may not start rotating in this stage.

c) When the IDD status is idle, the Active LED remains off (the LED lights up when the

initiator accesses the IDD).

(2)

Initial operation in the case of setting so that motor starts with START/STOP UNIT command

a) When power is turned on, the IDD executes initial self-diagnosis.

b) If an error is detected in initial self-diagnosis, the Fault LED lights up.

c) The spindle motor does not start rotating until the START/STOP UNIT command for the

start is issued. The INIT needs to issue the START/STOP UNIT command to start the

spindle motor by the procedure in Subsection 5.6.2.

d) The disk drive enters the READY status in 30 seconds after the START/STOP UNIT

command is issued. At this time, the IDD reads "system information" from the system space

on the disk.

e) The active LED blinks during command execution.

(3)

Check items at illegal operation

a) Check that IDD are mounted correctly.

b) Check that power and voltages are supplied correctly (measure them with the IDD power

connection position).

c) When the Fault LED continues lighting up, indicates that an error is detected in initial self-

diagnosis. In this case, it is recommended to issue the REQUEST SENSE command from the

initiator (host system) to obtain information (sense data) for error analysis.

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5 - 5

IMPORTANT

The LED lights during the IDD is executing a command. However,

in same commands, the lighting time is only an instant. Therefore,

it seems that the LED blinks or the LED remains off.

5.4.2

Checking connection

When the initial operation is checked normally after power is turned on, check that the IDD is

connected to the loop from the host system. Although checking the connection depends on the

structure of the host system, this section describes the general procedures.

(1)

Checking procedure

Issuing the commands and determining the end status depends on the start mode of the spindle

motor and unit attention report mode (specified with setting terminal). Figure 5.1 shows the

recommended checking procedure for the mode that the motor starts when power is turned on.

Figure 5.2 shows for the mode that the motor starts by the START/STOP UNIT command. In

these recommended checking procedures, following items are checked.

Note:

Following steps a) to e) correspond to a) to e) in Figures 5.1 and 5.2.

a) Issue the TEST UNIT READY command and check that the IDD is connected correctly

to the loop and the initial operation after power is turned on ended normally. The

command issue period of the TEST UNIT READY command shall be more than 20 ms.

b) To control starting of the spindle motor from the host system, issue the START/STOP

UNIT command to start the spindle motor.

c) Check the loop operations with the WRITE BUFFER and READ BUFFER commands.

d) Start the IDD self-diagnostic test with the SEND DIAGNOSTIC command and check

the basic operations of the controller and disk drive.

5 - 6

C141-E078-02EN

Motor starts when power is turned on

For Figure 5.2

Figure 5.1 Checking the IDD connection (A)

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5 - 7

Motor starts by START/STOP command

Executing time: opprox. 30 seconds

To Figure 5.1

Figure 5.2 Checking the IDD connection (B)

5 - 8

C141-E078-02EN

(2)

Checking at abnormal end

a) When sense data can be obtained with the REQUEST SENSE command, analyze the sense

data and retry recovery for a recoverable error. Refer to Chapter 5 of Fibre Channel Interface

Specifications for further details.

b) Check the setting of the terminals. Note that the checking procedure of loop connection

differs depending on the setting of the motor start mode and unit attention report mode.

5.4.3

Formatting

Since the disk drive is formatted with a specific (default) data format for each model (part

number) when shipped from the factory, the disk need not be formatted (initialized) when it is

installed in the system.

However, when the system needs data attributes different from the default format, all sides of the

disk must be formatted (initialized) according to the procedures below.

The user can change the following data attributes at initialization:

•

Logical data block length

Number of logical data blocks or number of cylinders in the user space

Alternate spare area size

This section outlines the formatting at installation. Refer to Chapters 4 and 6 of Fibre Channel

Interface Specifications for further details.

(1)

MODE SELECT/MODE SELECT EXTENDED command

Specify the format attributes on the disk with the MODE SELECT or MODE SELECT

EXTENDED command. The parameters are as follows.

a. Block descriptor

Specify the size (byte length) of the logical data block in the "data block length" field. To

explicitly specify the number of logical data blocks, specify the number in the "number of

data blocks" field. Otherwise, specify 0 in "number of data blocks" field. In this case, the

number of logical data blocks after initialization is determined by the value specified in the

format parameter (page code = 3) and drive parameter (page code = 4).

b. Format parameter (page code = 3)

Specify the number of spare sectors for each cylinder in the "alternate sectors/zone" field and

specify the number of tracks for alternate cylinders (= number of alternate cylinders ×

number of disk drive heads) in the "alternate tracks/zone" field. It is recommended not to

specify values smaller than the IDD default value in this field.

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5 - 9

c. Drive parameter (page code = 4)

To explicitly specify the number of cylinders in the user space, specify the number in the

"number of cylinders" field. Note that the number of alternate cylinders specified by the

format parameter (page code = 3) is included in the number of cylinders in the user space.

When the number of cylinders need not be specified, specify 0 or the default value in the

"number of cylinders" field. In this case, either of the smaller value between the number of

cylinders to allocate the number of logical data blocks specified in the "number of data

blocks" field of the block descriptor or the maximum number of cylinders that can be used as

the user space on the disk drive is allocated in the user space. When 0 is specified both in the

"number of cylinders" field and the "number of data blocks" field of the block descriptor, the

maximum number of cylinders that can be used as the user space on the disk drive is

allocated in the user space.

(2)

FORMAT UNIT command

Initialize all sides of the disk with the FORMAT UNIT command. The FORMAT UNIT

command initializes all sides of the disk using the P lists, verifies data blocks after initialization,

and allocates an alternate block for a defect block detected with verification. With initialization,

the value "00" is written into all bytes of all logical data blocks. Only the position information of

defect blocks detected with verification is registered in the G list. The specifications are as

follows:

a. Specifying CDB

Specify 0 for the "FmtData" bit and the "CmpLst" bit on CDB, 000 for the "Defect List

Format" field, and data pattern written into the data block at initialization for the "initializing

data pattern" field.

b. Format parameter

When the values in step a. are specified with CDB, the format parameter is not needed.

5.4.4

Setting parameters

The user can specify the optimal operation mode for the user system environments by setting the

following parameters with the MODE SELECT or MODE SELECT EXTENDED command:

•

Error recovery parameter

Disconnection/reconnection parameter

Caching parameter

Control mode parameter

With the MODE SELECT or MODE SELECT EXTENDED command, specify 1 for the "SP" bit

on CDB to save the specified parameter value on the disk. This enables the IDD to operate by

using the parameter value set by the user when power is turned on again. When the system has

more than one INIT, different parameter value can be set for each INIT.

5 - 10

C141-E078-02EN

When the parameters are not set or saved with the MODE SELECT or MODE SELECT

EXTENDED command, the IDD sets the default values for parameters and operates when power

is turned on or after reset. Although the IDD operations are assured with the default values, the

operations are not always optimal for the system. To obtain the best performance, set the

parameters in consideration of the system requirements specific to the user.

This section outlines the parameter setting procedures. Refer to Chapter 4 of Fibre Channel

Interface Specifications for further details of the MODE SELECT and MODE SELECT

EXTENDED commands and specifying the parameters.

IMPORTANT

1. At factory shipment of the IDD, the saving operation for the MODE

SELECT parameter is not executed. So, if the user does not set

parameters, the IDD operates according to the default value of each

parameter

2. The model select parameter is not saved for each SCSI ID of but as the

common parameter for all IDs. In the multi-INIT System, parameter

setting cannot be changed for each INIT.

3. Once parameters are saved, the saved value is effective as long as next

saving operation is executed from the INIT. For example, even if the

initialization of the disk is performed by the FORMAT UNIT command,

the saved value of parameters described in this section is not affected.

4. When the IDD, to which the saving operation has been executed on a

system, is connected to another system, the user must pay attention to

that the IDD operates according to the saved parameter value if the

saving operation is not executed at installation.

5. The saved value of the MODE SELECT parameter is assumed as the

initial value of each parameter after the power-on, the RESET

condition, or the BUS DEVICE RESET message. The INIT can change

the parameter value temporary (actively) at any timing by issuing the

MODE SELECT or MODE SELECT EXTENDED command with

specifying "0" to the SP bit in the CDB.

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5 - 11

(1)

Error recovery parameter

The following parameters are used to control operations such as IDD internal error recovery:

a. Read/write error recovery parameters (page code = 1)

Parameter

Default value

1 (enabled)

• ARRE:

Automatic alternate block allocation at read

operation

• TB:

Uncorrectable data transfer to the INIT

Immediate correction of correctable error

Report of recovered error

1 (enabled)

0 (disabled)

0 (Correction is

enabled.)

• EER:

• PER:

• DCR:

Suppression of ECC error correction

• Retry count at read operation

• Retry count at write operation

b. Verify error recovery parameters (page code = 7)

Parameter

Default value

• ERR:

• PER:

• DTE:

Immediate correction of recoverable error

Report of recovered error

Stop of command processing at successful

error recovery

1 (enabled)

0 (disabled)

0 (Processing is

continued.)

• DCR:

Suppression of ECC error correction

0 (Correction is

enabled.)

• Retry count at verification

c. Additional error recovery parameters (page code = 21)

Parameter

Default value

0 (disabled)

• RPR:

Report on parameter rounding by mode select

command

• Retry count at seek error

IMPORTANT

1. The user can arbitrarily specify the following parameters

according to the system requirements:

•

ARRE

PER

2. The user also can arbitrarily specify parameters other than the

above. However, it is recommended to use the default setting in

normal operations.

5 - 12

C141-E078-02EN

(2)

Disconnection/reconnection parameters (page code = 2)

The following parameters are used to optimize the start timing of reconnection processing to

transfer data on the loop at a read (READ or READ EXTENDED command) or write operation

(WRITE, WRITE EXTENDED, or WRITE AND VERIFY command) of the disk. Refer to

Chapter 3 of Fibre Channel Interface Specifications for further details.

a. Disconnection/reconnection parameters (page code = 2)

Parameter

Default value

20 (HEX)

• Buffer full ratio

• Buffer empty ratio

20 (HEX)

IMPORTANT

1. In a system without the disconnection function, these parameters

need not be specified.

2. Determine the parameter values in consideration of the

following performance factors of the system:

•

Time required for reconnection processing

Average amount of processing data specified with a

command

Refer to Chapter 3 of Fibre Channel Interface Specifications for

how to obtain the rough calculation values for the parameter

values to be set. It is recommended to evaluate the validity of

the specified values by measuring performance in an operation

status under the average system load requirements.

(3)

Caching parameters

The following parameters are used to optimize IDD Read-Ahead caching operations under the

system environments. Refer to Chapter 3 of Fibre Channel Interface Specifications for further

details.

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5 - 13

a. Read caching parameters

Parameter

Default value

0 (enabled)

0 (disabled)

• RCD:

• WCE:

• MS:

Disabling Read-Ahead caching operations

Write Cache Enable

Specifying the multipliers of "minimum prefetch"

and "maximum prefetch" parameters

0 (Specifying

absolute value)

• DISC:

Prefetch operation after track switching during

prefetching

0 (inhibit)

• Number of blocks for which prefetch is suppressed

• Minimum prefetch

X'FFFF'

X'0000'

• Maximum prefetch

X'0XXX'

(1 cache segment)

• Number of blocks with maximum prefetch restrictions

• Number of segments

X'FFFF'

X'4'

IMPORTANT

1. When Read-Ahead caching operations are disabled by the

caching parameter, these parameter settings have no meaning

except write cache feature.

2. Determine the parameters in consideration of how the system

accesses the disk. When the access form is not determined

uniquely because of the processing method, the parameters can

be re-set actively.

3. For sequential access, the effective access rate can be increased

by enabling Read-Ahead caching operations and Write Cache

feature.

(4)

Control mode parameters

The following parameters are used to control the tagged queuing and error logging.

a. Control mode parameters

Parameter

Default value

• RLEC:

Specification of operation when cumulative

value parameter reaches maximum value 0

0 (Does not

report error)

• Queue algorithm modifier

0 (Ordering is

executed by read

command only.)

• QErr:

Resume or abort remaining suspended

commands after sense pending state

0 (After release

of sense retention

status, executes

queued command.)

5 - 14

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5.5

Dismounting Drive

Since the method and procedure for dismounting the disk drive for replacement of the drive, etc.

depends on the locker structure of the system, etc., the work procedure must be determined in

consideration of the requirements specific to the system. This section describes the general

procedure and notes on dismounting the drive.

CAUTION

Damage

1. When dismounting the drive which is mounted on the system while

power is supplied to it.

•

The drive to be dismounted must be separated from the loop.

Dismounting the drive which is not separated from the loop may

cause an unexpected error.

•

If the drive is not separated from the loop, issue an LPB to the drive

from the initiator in a primitive sequence of the order set.

It is recommended to stop the spindle motor prior to this loop

separation operation. The spindle motor can be stopped by a

START/STOP command. It takes about 30 seconds for the spindle

motor to stop completely.

•

Then, dismount the drive using the drive mounting/dismounting

mechanism, etc. of the system. If the drive is dismounted while the

spindle motor is running, special care is required to avoid excessive

vibration or shock to the drive. It is recommended to stop the

operation once the SCA connector breaks off contact and wait until

the spindle motor stops (about 30 seconds) before dismount the

drive.

•

When storing or transporting the drive, put it in an antistatic bag.

(Shown in Section 5.1).

2. When dismounting the drive which is mounted on the system while

power is not supplied to it.

•

Do not move the drive until the drive stops completely (about 30

seconds if the spindle motor was stopped by a START/STOP UNIT

command, and about 30 seconds after powering-off when the power

was simply turned off).

•

Then, dismount the drive using the drive mounting/dismounting

mechanism, etc. of the system.

When storing or transporting the drive, put it in an antistatic bag.

(Shown in Section 5.1).

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CHAPTER 6

DIAGNOSTICS AND MAINTENANCE

6.1 Diagnostics

6.2 Maintenance Information

This chapter describes diagnostics and maintenance information.

6.1

Diagnostics

6.1.1

Self-diagnostics

The IDD has the following self-diagnostic function. This function checks the basic operations of

the IDD.

•

Initial self-diagnostics

Online self-diagnostics (SEND DIAGNOSTIC command)

Table 6.1 lists the contents of the tests performed with the self-diagnostics. For a general check

of the IDD including the operations of the host system and interface, use a test program that runs

on the host system (see Subsection 6.1.2).

Table 6.1

Self-diagnostic functions

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6 - 1

Brief test contents of self-diagnostics are as follows.

a. Hardware function test

This test checks the basic operation of the controller section, and contains following test.

•

RAM (microcode is stored)

Peripheral circuits of microprocessor (MPU)

Memory (RAM)

Data buffer

b. Seek test

This test checks the positioning operation of the disk drive using several seek modes (2 points

seek, 1 position sequential seek, etc.). The positioning operation is checked with confirming

the physical address information by reading the ID field from the data block on track 0 after

completion of the seek operation to the target cylinder.

c. Write/read test

This test check the write/read function by using the Internal test space of the disk drive.

(1)

Initial self-diagnostics

When power is turned on, the IDD starts initial self-diagnostics. The initial self-diagnostics

checks the basic operations of the hardware functions.

If an error is detected in initial self-diagnosis, the Fault LED lights up. In this status, the IDD

reports the CHECK CONDITION status to all input/output operation requests other than the

REQUEST SENSE command. When the CHECK CONDITION status is posted, the INIT should

issue the REQUEST SENSE command. The sense data obtained with the REQUEST SENSE

command details the error information detected with the initial self-diagnostics.

Even if CHECK CONDITION status and sense data are posted, the LED continues blinking.

Only when the SCSI bus is reset, the BUS DEVICE RESET message is issued, or the power is

turned off or re-turned on, this status can be cleared. When this status is cleared, the IDD

executes the initial self-diagnosis again.

6 - 2

C141-E078-02EN

The IDD does not reply to the loop for up to 2 seconds after the initial self-diagnostics is started.

After that, the IDD can accept the I/O operation request correctly, but the received command,

except the executable commands under the not ready state (such as INQUIRY, START/STOP

UNIT), is terminated with the CHECK CONDITION status (NOT READY [=2]/logical unit not

ready [=04-00]) during the interval from the spindle motor becomes stable to the IDD becomes

ready. The executable command under the not ready state is executed in parallel with the initial

self-diagnostics, or is queued by the command queuing feature and is executed after completion

of the initial self-diagnostics. When the command that comes under the exception condition of

the command queuing is issued at that time, the IDD posts the BUSY status for the command.

When the error is detected during the initial self-diagnostics, the CHECK CONDITION status is

posted for all commands that were stacked during the initial self-diagnostics. For the command

execution condition, refer to Section 2.4 and Subsection 2.7.4 in Fibre Channel Interface

Specifications.

(2)

Online self-diagnostics (SEND DIAGNOSTIC command)

The INIT can make the IDD execute self-diagnostics by issuing the SEND DIAGNOSTIC

command.

The INIT specifies the execution of self-diagnostics by setting 1 for the SelfTest bit on the CDB in the

SEND DIAGNOSTIC command and specifies the test contents with the UnitOfl bit.

When the UnitOfl bit on the CDB is set to 0, the IDD executes the hardware function test only

once. When UnitOfl bit is set to 1, the IDD executes the hardware function test, seek

(positioning) test, and data write/read test for the CE space only once.

a. Error recovery during self-diagnostics

During the self-diagnostics specified by the SEND DIAGNOSTIC command, when the

recoverable error is detected during the seek or the write/read test, the IDD performs the error

recovery according to the MODE SELECT parameter value (read/write error recovery

parameter, additional error recovery parameter) which the INIT specifies at the time of

issuing the SEND DIAGNOSTIC command.

PER

Operation of self-diagnostics

The self-diagnostics continues when the error is recovered. The self-

diagnostics terminates normally so far as the unrecoverable error is not

detected.

The self-diagnostics continues when the error is recovered. If the

unrecoverable error is not detected, the consecutive tests are executed till last

test but the self-diagnostics terminates with error. The error information

indicates that of the last recovered error.

b. Reporting result of self-diagnostics and error indication

When all specified self-diagnostics terminate normally, the IDD posts the GOOD status for

the SEND DIAGNOSTIC command.

C141-E078-02EN

6 - 3

When an error is detected in the self-diagnostics, the IDD terminates the SEND

DIAGNOSTIC command with the CHECK CONDITION status. If an error is detected by a

hardware function test at this time, the Fault LED lights up.

The INIT should issue the REQUEST SENSE command when the CHECK CONDITION

status is posted. The sense data collected by the REQUEST SENSE command indicates the

detail information of the error detected in the self-diagnostics.

The IDD status after the CHECK CONDITION status is posted differs according to the type

of the detected error.

a) When an error is detected in the seek or write/read test, the subsequent command can be

accepted correctly. When the command other than the REQUEST SENSE and NO

OPERATION is issued from the same INIT, the error information (sense data) is

cleared.

b) When an error is detected in the hardware function test, the IDD posts the CHECK

CONDITION status for all I/O operation request except the REQUEST SENSE

command. The error status is not cleared and the Fault LED continues lighting up even

if the error information (sense data) is read. Only when the SCSI bus is reset, the BUS

DEVICE RESET message is issued or the power is turned off or re-turned on, the status

can be cleared. When this status is cleared, the IDD executes the initial self-diagnostics

again (see item (1)).

Refer to Chapter 4 of Fibre Channel Interface Specifications for further details of the

command specifications.

CAUTION

Data loss

When the SEND DIAGNOSTIC command terminates with the

CHECK CONDITION status, the INIT must collect the error

information using the REQUEST SENSE command. The RECEIVE

DIAGNOSTIC RESULTS command cannot read out the error

information detected in the self-diagnostics.

6.1.2

Test programs

The basic operations of the IDD itself can be checked with the self-diagnostic function. However,

to check general operations such as the host system and interface operations in a status similar to

the normal operation status, a test program that runs on the host system must be used.

The structure and functions of the test program depend on the user system requirements.

Generally, it is recommended to provide a general input/output test program that includes devices

connected to the loop and input/output devices on other I/O ports.

Including the following test items in the test program is recommended to test the IDD functions

generally.

6 - 4

C141-E078-02EN

(1)

(2)

(3)

(4)

Interface test

The operations of the loop and data buffer on the IDD are checked with the WRITE BUFFER and

READ BUFFER commands.

Basic operation test

The basic operations of the IDD are checked by executing self-diagnosis with the SEND

DIAGNOSTIC command (see Subsection 6.1.1).

Random/sequential read test

The positioning (seek) operation and read operation are tested in random access and sequential

access modes with the READ, READ EXTENDED, or VERIFY command.

Write/read test

By using a data block in the internal test space, the write/read test can be executed with an

arbitrary pattern for a disk drive in which user data is stored.

6.2

Maintenance Information

6.2.1

(1)

Maintenance requirements

Preventive maintenance

Preventive maintenance such as replacing air filters is not required.

CAUTION

Damage

Do not open the DE in the field because it is completely sealed.

(2)

Service life

The service life under suitable conditions and treatment is as follows. The service life is

depending on the environment temperature. Therefore, the user must design the system cabinet

so that the average DE surface temperature is as possible as low.

•

DE surface temperature: 45°C or less

DE surface temperature: 46°C to 50°C

DE surface temperature: 51°C to 55°C

DE surface temperature: 56°C and more

5 years

4 years

3 years

Strengthen cooling power so that DE surface

temperature is 55°C or less.

Even if the IDD is used intermittently, the longest service life is 5 years.

C141-E078-02EN

6 - 5

Note:

The "average DE surface temperature" means the average temperature at the DE surface

throughout the year when the IDD is operating.

(3)

(4)

Parts that can be replaced in the field

The PCA cannot be replaced in the field. The DE cannot be replaced in the field.

Service system and repairs

Fujitsu has the service system and repair facility for the disk drive. Contact Fujitsu representative

to submit information for replacing or repairing the disk drive. Generally, the following

information must be included:

a) IDD model, part number (P/N), revision number, serial number (S/N), and date of

manufacturing

b) Error status

•

Date when the error occurred

System configuration

Environmental conditions (temperature, humidity, and voltage)

c) Error history

d) Error contents

•

Outline of inconvenience

Issued commands and specified parameters

Sense data

Other error analysis information

CAUTION

Data loss

Save data stored on the disk drive before requesting repair. Fujitsu

does not assume responsibility if data is destroyed during servicing

or repair.

6 - 6

C141-E078-02EN

See Section 5.1 for notes on packing and handling when returning the disk drive.

6.2.2

Revision numbers

The revision number of the disk drive is represented with a letter and a number indicated on the

revision label attached to the DE. Figure 6.1 shows the revision label format.

Machine revision

Figure 6.1 Revision label

(1)

(2)

Indicating revision number at factory shipment

When the disk drive is shipped from the factory, the revision number is indicated by deleting

numbers in the corresponding letter line up to the corresponding number with = (see Figure 6.2).

Changing revision number in the field

To change the revision number because parts are replaced or other modification is applied in the

field, the new level is indicated by enclosing the corresponding number in the corresponding

letter line with (see Figure 6.2).

C141-E078-02EN

6 - 7

IMPORTANT

When the revision number is changed after the drive is shipped

from the factory, Fujitsu issues "Engineering Change

Request/Notice" in which the new revision number is indicated.

When the user changes the revision number, the user should update

the revision label as described in item (2) after applying the

modification.

At shipment

Rev. A2

Revising at field

Rev. A3

Figure 6.2 Indicating revision numbers

6 - 8

C141-E078-02EN

APPENDIX A

LOCATIONS OF CONNECTORS

A.1 Locations of Connectors

This appendix shows the locations of connectors for 8- and 16-bit SCSIs.

C141-E078-02EN

A - 1

A.1

Locations of Connectors

(Rear view)

(MAF3364FC)

(Rear view)

(MAG series)

Figure A.1 Locations of connectors

A - 2

C141-E078-02EN

APPENDIX B

CONNECTOR SIGNAL ALLOCATION

B.1 Interface (FC-SCA) Connector Signal Allocation

This appendix describes the connector signal allocation.

C141-E078-02EN

B - 1

B.1

Interface (FC-SCA) Connector Signal Allocation

Table B.1 FC-SCA connector: CN1

Pin No.

Signal

–EN bypass port A

+12V

Signal

+12V charge

GND

Pin No.

+12V

GND

+12V

+PortA_in

–PortA_in

GND

–Parallel ESI

–Drive present

Active LED out

–Spindle sync

Start_1/Mated

Start_2/Mated

–EN bypass port B

+PortB_in

–PortB_in

GND

+PortA_out

–PortA_out

GND

12*

13*

14*

15*

SEL-6

SEL-5

SEL-4

SEL-3

–DSK_WR

–DSK_RD

–ENCL_ACK

D(3)

+PortB-out

–PortB-out

GND

Fault LED out

SEL-2

SEL-1

SEL-0

D(2)

D(1)

D(0)

36*

37*

38*

N.C

+5V

N.C

+5V charge

Note: *1) Signal names in the right column of the table are those in parallel ESI operation.

B - 2

C141-E078-02EN

APPENDIX C

MODEL NAMES AND PRODUCT NUMBERS

C.1 Model Names and Product Numbers

This appendix lists model names (types) and product numbers.

C141-E078-02EN

C - 1

C.1

Model Names and Product Numbers

Table C.1 MAF and MAG series model names and product numbers

Data block

length

(at factory

Total

storage

capacity

Model name

Mounting

screw

Part number

Remarks

(type)

shipment) (user area)

MAF3364FC

512B

36.4 GB

18.2 GB

9.1 GB

#6-32UNC

CA01776-B980

1.6-inch height

10,025 rpm

10 disks

19 heads

MAG3182FC

MAG3091FC

CA01776-B580

CA01776-B380

1-inch height

10,025 rpm

5 disks

10 heads

1-inch height

10,025 rpm

3 disks

5 heads

C - 2

C141-E078-02EN

APPENDIX D

FIBRE CHANNEL INTERFACE FUNCTIONS

D.1 Fibre Channel Interface Function Specifications

This appendix lists the fibre channel interface functions provided for the IDD. Refer to the Fibre Channel

Logical Interface Specifications for details of each functions.

C141-E078-02EN

D - 1

D.1

Fibre Channel Interface Function Specifications

Table D.1 Fibre channel interface function specifications (1 of 8)

: Provided ×: Not provided

Item

SIMPLE QUEUE TYPE

Specification

Task

attribute

message

HEAD OF QUEUE TYPE

ORDERED QUEUE TYPE

ACA TYPE

UNTAGGED

Task

TERMINATE TASK

CLEAR ACA

manage-

ment flag

message

TARGET RESET

CLEAR TASK SET

ABORT TASK SET

TEST UNIT READY

REZERO UNIT

(00)

(01)

(03)

(04)

REQUEST SENSE

FORMAT UNIT

FmtData (format data)

Interleave factor

Ο (No interleave)

Block address format defect listing

≠0

Block address format defect listing

Byte-distance-from-index format defect listing

Physical sector address format defecting listing =0

Physical sector address format defecting listing ≠0

CmpLst (complete list)

Command

(Group 0)

FOV (Format Options Valid)

DPRY (Disable Primary)

DCRT (Disable Certification)

STPF (Stop Format)

IP (Initialization Pattern)

DSP (Disable Saving Parameters)

Immed (Immediate)

REASSIGN BLOCKS

(07)

(08)

(0A)

(0B)

READ

WRITE

SEEK

D - 2

C141-E078-02EN

Table D.1 Fibre channel interface function specifications (2 of 8)

: Provided ×: Not provided

Item

Specification

INQUIRY

(12)

EVPD (Enable Vital Product Data)

Typical INQUIRY data

Ο (64 byte long)

VPD Page 0: VPD page code listing

VPD Page 80: Device serial number

VPD Page C0: Operation mode

READ DEVICE CHARACTERISTICS

PRIORITY RESERVE

[VU] *(13)

[VU] *(14)

(15)

MODE SELECT

PF=(page format)

Ο (Specified value

ignored)

Page 1: Read/write error recovery

Ο (12 B: Savable)

AWRE (Automatic Write Reallocation Enabled)

× (Specified value

ignored)

ARRE (Automatic Read Reallocation Enabled)

Ο (Changeable)

(Transfer Block)

Ο (Changeable)

(Read Continuous)

EER (Enable Early Recovery)

PER (Post Error)

Ο (Changeable)

Command

(Group 0)

DTE (Disable Transfer on Error)

× (Specified value

ignored)

DCR (Disable Correction)

Retry count at read

Ο (Changeable)

Correctable bit length

Ο (Not changeable)

Head offset count

Data strobe offset count

Retry count at write

Ο (Changeable)

Recovery processing time restriction

Page 2: Disconnection/reconnection

Buffer-full ratio

Ο (16 B: Savable)

Ο (Changeable)

Buffer-empty ratio

Ο (Changeable)

Bus inactivity restriction

Disconnection time restriction

Connection time restriction

Maximum burst length

DTDC (data transfer disconnect control)

EMDP (Enable Modify Data Pointer)

FARd, FAWrt, FAStat (Tair Arbitoration

READ/Write/Status)

Ο (Not changeable)

DImm (Disconnect Immediate)

*1 Fujitsu-specific function

C141-E078-02EN

D - 3

Table D.1 Fibre channel interface function specifications (3 of 8)

: Provided ×: Not provided

Item

MODE SELECT (continued)

Page 3: Format parameter

Number of tracks/zone

Specification

(15)

Ο (24 B: Savable)

Ο (Not changeable)

Ο (Changeable)

Ο (Not changeable)

Ο (Changeable)

Ο (No interleave)

Ο (Not changeable)

Ο (24 B: Savable)

Ο (Changeable)

Ο (Not changeable)

Number of alternate sectors/zone

Number of alternate tracks/zone

Number of alternate tracks/drive

Number of alternate sectors/track

Data byte length/physical sector

Interleave factor

Track skew factor

Cylinder skew factor

SSEC/HSEC (Soft Sector/Head Sector)

RMB (Removable)

SURF (Surface)

Page 4: Drive parameter

Number of cylinders

Command

(Group 0)

Number of heads

“Write Precompensation” start cylinder

“Reduced Write Current” start cylinder

Drive step rate

Landing zone cylinder

RPL (Rotational Position Locking)

Rotational synchronization offset

Medium rotational speed

Page 7: Verify error recovery

EER (Enable Early Recovery)

PER (Post Error)

Ο (Not changeable)

Ο (12 B: Savable)

Ο (Changeable)

DTE (Disable Transfer on Error)

× (Specified value

ignored)

DCR (Disable Correction)

Retry count at verification

Correctable bit length

Ο (Changeable)

Ο (Not changeable)

Recovery processing time restriction

D - 4

C141-E078-02EN

Table D.1 Fibre channel interface function specifications (4 of 8)

: Provided ×: Not provided

Item

Specification

MODE SELECT (continued)

(15)

Page 8: Caching parameter

Ο (20 B: Savable)

DISC (discontinuity)

MS (Multiple Select)

Ο (Not changeable)

WCE (Write Cache Enable)

RCD (Read Cache Disable)

Demand Read Retention Priority

Write Retention Priority

Ο (Changeable)

Prefetch suppression block count

Minimum prefetch

Maximum prefetch

Ο (Not changeable)

Ο (Changeable)

Maximum prefetch restriction block count

Number of segments

Buffer segment size

Command

(Group 0)

Page A: Control mode page

RLEC (Report Log Exception Condition)

Ο (12 B: Savable)

× (Specified value

ignored)

Queue Algorithm modifier

QErr (Queue Error management)

RAC (Report a Check)

SWP (Software Write Protect)

DQue (Disable Queuing)

RAEN

Ο (Changeable)

UAEN

EAEN

Ready AEN Holdoff period

C141-E078-02EN

D - 5

Table D.1 Fibre channel interface function specifications (5 of 8)

: Provided ×: Not provided

Item

Specification

Page C: Notch parameter

Page 19: Fibre channel control parameter

Ο (8 B)

DTOLI (Disable Target Originated Loop

Initialization)

Ο (Not Changeable)

DTIPE (Disable Target Initiated Port Enable)

Ο (Not changeable)

ALWLI (Allow Login Without Loop

Initialization)

Ο (Not changeable)

DSA (Disable Soft Address

DLM (Disable Loop Master)

DDIS (Disable Discovery)

Ο (Not changeable)

Page 21: Additional error recovery

RPR (Rounded Parameter Report)

Retry count at seek error

[VU] (*1)

Ο (4 B: Savable)

Ο (Changeable)

RESERVE

(16)

(17)

(18)

(1A)

RELEASE

COPY

Command

(Group 0)

MODE SENSE

DBD (Disable Block Descriptor)

Page 0 (Non-Parameter Transfer)

START/STOP UNIT

(1B)

(1C)

Immed (Immediate)

RECEIVE DIAGNOSTIC RESULTS

Page 00: Specifiable page code list

Page 01: Configuration

Page 02: Enclosure status

Page 03: Help text

Page 04: String in

Page 05: Threshold in

Page 06: Array status

Page 07: Element descriptor

Page 08: Short enclosure status

Page 40: Logical/physical address conversion

*1 Fujitsu-specific function

D - 6

C141-E078-02EN

Table D.1 Fibre channel interface function specifications (6 of 8)

: Provided ×: Not provided

Item

Specification

SEND DIAGNOSTIC

(1D)

PF (Page Format)

Ο (Specified value

ignored)

Self Test (Self Test)

Dev Ofl (Device Offline)

Unit Ofl (Unit Offline)

Page 0: Specifiable page code listing

Page 02: Enclosure control

Page 04: String out

Command

(Group 0)

Page 05: Threshold out

Page 06: Array control

Page 40: Logical/physical address conversion

Page 80: Mode setup state report

Page 81: Device-specific information

PREVENT/ALLOW MEDIUM REMOVAL

SEARCH BLOCK HIGH

SEARCH BLOCK EQUAL

SEARCH BLOCK LOW

READ CAPACITY

[VU]*1

(1E)

[VU]*1 (20)

[VU]*1 (21)

[VU]*1 (22)

(25)

PMI (Parial Medium Indicator)

READ EXTENDED

(28)

(2A)

(2B)

(2E)

WRITE EXTENDED

SEEK EXTENDED

WRITE & VERIFY

Command

(Group 1)

BytChk (Byte Check)

VERIFY

(2F)

By+Chk (Byte Check)

SEARCH DATA HIGH

SEARCH DATA EQUAL

SEARCH DATA LOW

SET LIMITS

(30)

(31)

(32)

(33)

(34)

(35)

(36)

PRE-FETCH

SYNCHRONIZE CACHE

LOCK/UNLOCK CACHE

*1 Fujitsu-specific function

C141-E078-02EN

D - 7

Table D.1 Fibre channel interface function specifications (7 of 8)

: Provided ×: Not provided

Item

Specification

READ DEFECT DATA

(37)

Block address format

Byte-distance-from-index format

Physical sector address format

COMPARE

(39)

(3A)

(3B)

COPY & VERIFY

WRITE BUFFER

Mode=‘000’ (Header & Data Mode)

Mode=‘001’ (Header & Data Mode with Address)

Mode=‘010’ (Data Mode)

Command

(Group 1)

Mode=‘100’ (Download Microcode)

Mode=‘101’ (Download Microcode and Save)

READ BUFFER

(3C)

Mode=‘000’ (Header & Data Mode)

Mode=‘001’ (Header & Data Mode with Address)

Mode=‘010’ (Data Mode)

Mode=‘011’ (Descriptor Mode)

READ LONG

CORRCT (Corrected)

WRITE LONG

(3E)

(3F)

(40)

(41)

CHANGE DEFINITION

WRITE SAME

LBdata (Logical Block Data)

PBdata (Physical Block Data)

LOG SELECT

(4C)

(4D)

Command

(Group 2)

LOG SENSE

MODE SELECT EXTENDED

RESERVE EXTENDED

MODE SENSE EXTENDED

DIAGNOSTIC WRITE DATA

DIAGNOSTIC READ DATA

FORMAT ID

(55)

(56)

(57)

(5A)

[VU] (*1) (C1)

[VU] (*1) (C2)

[VU] (*1) (C4)

[VU] (*1) (C6)

[VU] (*1) (C8)

[VU] (*1) (CA)

Command

(Group 6)

SPACE ID & READ DATA

DISPLACED ID

READ ID

*1 Fujitsu-specific function

D - 8

C141-E078-02EN

Table D.1 Fibre channel interface function specifications (8 of 8)

: Provided ×: Not provided

Item

DIAGNOSTIC FORMAT ID

DIAGNOSTIC READ ID

WRITE RAM

Specification

[VU] (*1) (CD)

[VU] (*1) (CE)

[VU] (*1) (D1)

[VU] (*1) (D2)

[VU] (*1) (D8)

[VU] (*1) (DA)

Command

(Group 6)

READ RAM

RECOVER DATA

RECOVER ID

Defective sector slip processing function

Command link function

Relative block addressing function

Untagged queuing function

Tagged command queuing function

Contingent Allegiance (CA)

Extended Contingent Allegiance (ECA)

Command

Processing

Asynchronous condition notification feature

(AEN: async. event notification)

Read-ahead cache feature

Cache control feature

DPO (disable page out)

FUA (force unit access)

Write cache feature

GOOD

(00)

(02)

(04)

(08)

(10)

(14)

(18)

(22)

(28)

CHECK CONDITION

CONDITION MET

BUSY

Status

INTERMEDIATE

INTERMEDIATE CONDITION MET

RESERVATION CONFLICT

COMMAND TERMINATED

QUEUE FULL

Non-extended format

Extended format

Sense data

Ο (48 bytes long)

Ο (Rev. 4.b)

CCS (common command set) conformity

*1 Fujitsu-specific function

C141-E078-02EN

D - 9

This page is intentionally left blank.

Glossary

Bus condition:

Bus phase:

Asynchronous condition for causing SCSI bus status transition. There are

two types of bus conditions, ATTENTION and RESET.

An SCSI bus state. The SCSI bus is in one of the following phases: BUS

FREE,

ARBITRATION,

SELECTION,

RESELECTION,

INFORMATION TRANSFER. The INFORMATION TRANSFER phase

is divided into DATA IN, DATA OUT, COMMAND, STATUS,

MESSAGE IN, and MESSAGE OUT phases depending on the type of

information being transferred.

CCS:

CDB:

Common Command Set. The standard SCSI logical specification

stipulated by a working committee of ANSI. Functions necessary for

direct access devices are defined.

Command Descriptor Block. A group of data that describes the command

for I/O and is transferred from an initiator to a target.

Command:

Disconnect:

Issued to a target to direct an input/output operation and written as CDB.

Operation performed by the target to free itself from the SCSI bus and the

initiator temporarily when SCSI bus operation becomes unnecessary

during command processing.

Initiator:

SCSI device that has initiated an input/output operation on the SCSI

device. This is abbreviated as INIT.

Logical unit:

Simple unit of equipment that can be directed to perform one I/O

operation on the SCSI bus.

LUN:

Logical unit number used to identify a logical unit.

Message:

Information that controls a series of bus phases and I/O sequence between

the initiator and the target on the SCSI bus.

Reconnect:

SCSI:

Operation performed by the target to reconnect itself with the initiator

when operation on the SCSI bus becomes necessary after disconnection.

Small computer system interface. An input/output interface standardized

by the American National Standards Institute (ANSI). [Standard

number: ANSI X3.131-1986]

SCSI device:

SCSI ID:

General term for a device (Input/output device, I/O controller, and host

adapter, etc.) connected to an SCSI bus.

Physical device address used to identify an SCSI device on the SCSI bus.

This number is specific to each SCSI device. SCSI IDs are #0 to #7, each

referenced by a unique bit on the data bus.

Sense code:

One byte of code added to the sense data to identify the type of detected

error.

C141-E078-02EN

GL - 1

Sense data:

Detailed information created by the target when any error is involved in

the command termination status. This information is transferred to

report the error.

Sense key:

Status:

Four-bit code added to the sense data to identify the class of detected

error.

One byte of information that is transferred from a target to an initiator on

termination of each command to indicate the command termination

status.

Target:

SCSI device which performs I/O initiated by an initiator. It is abbreviated

as TARG.

GL - 2

C141-E078-02EN

Abbreviations

DTE

Disable Transfer on Error

ACK

AEN

ALT

ACKnowledge

Asynchoronous Event Notification

ALTernated (block)

Automatic Read Reallocation

Enabled

ECC

EER

EVPD

Error Correction Code

Enable Early Recovery

Enable Vital Product Data

ARRE

ASCII

American Standard Code for

Information Interchange

ASiGned block

ASG

ATN

ATTeNtion

Frame Ground

AWG

AWRE

American Wire Gauge

Automatic Write Reallocation

Enabled

FIFO

First In First Out

FmtData Format Data

FOV

FUA

Format Options Valid

Force Unit Access

bpi

BSY

BytChk

bits per inch

BuSY

Byte Check

Gap

G list

Grown defect list

C list

C/D

Target Certification list

Control/data

HSEC

Height

Hard SECtor

CCS

CDB

CmpLst

CRC

CSS

Common command set

Common descriptor block

Customer Engineer

Complete List

Cyclic Redundancy Check

Contact Start Stop

CYLinder

I/O

IDD

ILBN

Immed

Input/Output

IDentifier

Intelligent Disk Drive

Ideal Logical Block Number

Immediate

CYL

INDX/SCT INDeX/SeCTor

ISG

Initialization Pattern

InterSector Gap

Depth

D list

DBD

Data Defect List

Disable Block Descriptor

Direct Current

DCR

DCRT

DEF

DevOfl

DPO

DPRY

DSP

Disable Correction

Disable CeRtificaTion

Disk Enclosure

DEFective block

Device Offline

Disable Page Out

Disable PRimarY

Disable Saving Parameters

Data Transfer Disconnect Control

LBdata

LBN

LED

Logical Block data

Logical Block Number

Light Emitting Diode

Logical Unit Number

LUN

Magnetro Resistive

Multiple Select

DTDC

C141-E078-02EN

AB - 1

MSG

MeSsaGe

TPI

TRM

Transfer Block

Tracks Per Inch

TeRMinator

OEM

Original Equipment Manufacturer

P list

P/N

Primary defect list

Parts/Number

UnitOfl

Unit Offline

PBdata

Physical Block data

PC board Printed Circuit board

PCA

PER

Printed Circuit Assembly

Post ERror

Page Format

VCM

VPD

Voice Coil Motor

Vital Product Data

Vendor Unique

PLOSync Phase Lock Oscillator Syncronous

PMI

PR4ML

Partial Medium Indicator

Partial Response class 4 Maximum

Likelihood

Width

WCE

Write Cache Enable

Write Protect

Read Continuous

Read Cache Disable

Request

Relative Humidity

ReMovaBle

RCD

REQ

RMB

RST

RSV

ReSeT

ReSerVed

S/N

SBd

SBi

SCSI

SCT

SEL

SelfTest

Serial/Number

Synchronized Byte data area

Synchronized Byte identifier area

Small Computer System Interface

SeCTor

SELect

Self Test

Signal Ground

Save Page

SPR

SPaRe block

Servo

SSEC

STPF

SURF

Soft SECtor

SToP Format

SURFace

C141-E078-02EN

AB - 2

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