
A C - 2 4 2 0    WESTERN DIGITAL
NO MORE PRODUCED                                      Native|  Translation
                                                      ------+-----+-----+-----
Form                 3.5"/SLIMLINE         Cylinders    2720|  989|     |
Capacity form/unform   425/      MB        Heads           4|   15|     |
Seek time   / track  13.0/ 4.0 ms          Sector/track     |   56|     |
Controller           IDE / AT              Precompensation
Cache/Buffer           128 KB STATIC RAM   Landing Zone
Data transfer rate    3.000 MB/S int       Bytes/Sector      512
                      5.740 MB/S ext
Recording method     RLL 1/7                        operating  | non-operating
                                                  -------------+--------------
Supply voltage     5/12 V       Temperature *C         5 55    |    -40 60
Power: sleep          0.3 W     Humidity     %         8 80    |      5 80
       standby        0.4 W     Altitude    km    -0.305  3.048| -0.305 12.192
       idle           2.1 W     Shock        g        10       |     70
       seek               W     Rotation   RPM      3314
       read/write     3.1 W     Acoustic   dBA        39
       spin-up       15.0 W     ECC        Bit   176,REED SOLOMON
                                MTBF         h     250000
                                Warranty Month        36
Lift/Lock/Park     YES          Certificates     CSA,FCC,IEC950,TUV,UL1950



**********************************************************************
                        L   A   Y   O   U   T
**********************************************************************
WESTERN  WDAC1210/AC2420  TECHNICAL REFERENCE MANUAL

  +---------------------------------------------------------+
  |                                                         |XX I
  |                                                         |XX N
  |                                                         |XX T
  |                                                         |XX E
  |                                                         |XX R
  |                                                         |*X F  J2
  |                                                         |XX A
  |                                                         |XX C
  |                                                         |XX E
  |                                                         |XX
  |                                                         |XX1
  |                                                         |6-5 J8
  |                                                         || |
  ++LED                                                     |2-1
  ++                                                        |XX J1
  |                                                         |XX Power
  +---------------------------------------------------------+







                         J2                    J8     J1
    +39------------------------------------1++5-3-1++-------+
    |o o o o o o o o o o o o o o o o o o o o||o o o||O O O O|
    |o o o o o o o o o o   o o o o o o o o o||o o o||4 3 2 1|
  --+40------------------------------------2++6-4-2+++-+-+-++----
                                                     | | | +12V
                   (Pin 20 keyed)                    | | +- GND
                                                     | +--- GND
                                                     +----- +5V



**********************************************************************
                      J   U   M   P   E   R   S
**********************************************************************
WESTERN  WDAC1210/AC2420  TECHNICAL REFERENCE MANUAL


 Jumper setting
 ==============

 J8  Master/Slave/Cable Select Configuration
 -------------------------------------------

    +5-3-1+ Single Drive              +5-3-1+ Master Drive
    |o o o| Configuration             |X o o| Configuration
    |o o o|                           |X o o| (Dual Drives)
    +6-4-2+                           +6-4-2+


    +5-3-1+ Slave Drive               +5-3-1+ Cable Select
    |o X o| Configuration             |o o X| Configuration
    |o X o| (Dual Drives)             |o o X| (Dual Drives)
    +6-4-2+                           +6-4-2+

 The Caviar can be assigned as either a single, master, or slave
 drive.


 Dual Installations
 ------------------
 Dual installations require a master/slave drive configuration,
 where one drive is designated as the promary (master) drive
 and the other is designated as the secondary (slave) drive. The
 Caviar drive is compatible in dual installations with other
 intelligent drives that supports a master/slave configuration.

 If your installation requires the use of an adapter card, it is
 useful to know that you may also be able to connect your floppy
 drive(s) to the adapter card.


 Single Drive Mode
 -----------------
 If you are installing the Caviar drive as the only intelligent drive
 in the system, you do not need install jumpers on the J8 connector.
 This is considered a standard single drive installation, and no
 jumpers are required. Note that even with no jumper installed, the
 Caviar checks the DRIVE ACTIVE/SLAVE PRESENT (DASP) signal to de-
 termine if a slave intelligent drive is present.

 If you have a dual installation (two intelligent drives), you must
 designate one of the drives as the master and the other as the slave
 drive. The jumper pins on the J8 connector need to be configured for
 the dual installation.


 Master Drive Mode
 -----------------
 To designate the drive as the master, place a jumper shunt on pins
 5-6. With the Caviar configured as the master drive, the Caviar
 assumes that a slave drive is present. The jumper on pins 5-6 is
 optional if the slave drive follows the same protocol (Common Access
 Method AT Bus Attachment) as the Caviar.


 Slave Drive Mode
 ----------------
 To designate the drive as the slave, place a jumper shunt on pins
 3-4. When the Caviar is configured as the slave drive, the Caviar
 delays spin up for three seconds after powerup reset. This feature
 prevents overloading of the power supply during power-up.


 Cable Select (CSEL)
 -------------------
 Caviar also supports the CSEL signal on the drive cable as a drive
 address selection. Place a jumper shunt on pins 1-2 to enable this
 option. When enabled, the drive address is 0 (Master) if CSEL is low
 or 1 (Slave) if CSEL is high.

 Do not install the CSEL jumper shunt when installing the Caviar drive
 in systems that do not support the CSEL feature.



**********************************************************************
                      I   N   S   T   A   L   L
**********************************************************************
WESTERN  WDAC1210/AC2420  TECHNICAL REFERENCE MANUAL

 Notes of Installation
 =====================

 Orientation
 -----------
 The Caviar can be mounted in many different ways depending upon the
 physical design of your system.


 Determining Your Configuration
 ------------------------------
 You can configure the Caviar in one of two ways:

 1. The drive is cabled directly to a 40-pin connector on the mother-
    board, or
 2. The drive is cabled to an adapter card mounted in one of the
    expansion slots in the computer.

 Both configurations use a 40-pin host interface cable.

 If you are using the Caiar drive as one of two hard disk drives in
 the computer (dual installation), you may use either configuration.
 In dual installations, you must use a 40-pin host interface cable
 with three connectors and daisy-chain the two drives to the mother-
 board or adapter card.


 Mounting the Drive
 ------------------
 For dual installations, it is usually easier to completely install
 one intelligent drive in the lower position first. The order of
 intelligent drives is unimportant if you are using to Western Digital
 drives. As explained previously, one must be jumpered as the master
 drive and the other as the slave drive. When installation is complete
 he drives are daisy-chained together.


 Cabling and Installation Steps
 ------------------------------
 Make sure your interface cable is no longer than 18 inches to
 minimize the noise which is induced on the data and control buses.
 Also, if you are connecting two drives together, you need a daisy-
 chain cable that has three 40-pin connectors.

 Caution: You may damage the Caviar drive if the interface cable is
 not connected properly. To prevent incorrect connection, use a cable
 that has keyed connectors at both the drive and host ends. Pin 20
 has been removed from J2 connector. The female connector on the
 interface cable shoul have a plug position 20 to prevent incorrect
 connection. Make sure that pin 1 on the cable is connected to pin 1
 on the connectors.


 Mounting Screws
 ---------------
 Mount the caviar drive bay using four 6-32 screws. Be sure to use the
 correct size screws. Do not install the screws past six threads
 (3/16 inch). Screws that are too long will damage the Caviar drive.


 Power Connectors and Cables
 ---------------------------
 Power Connector:           4-pin MOLEX P/N 15-24-4041 or equivalent
 Mating Connector:          Body AMP 1-480424-0 or equivalent
                            Pins AMP 60619-4 or equivalent
 Power Cable Wire Gauge     18 AWG


 Buffer RAM
 ----------
 A 128-Kbyte (optional 256-Kbyte) static RAM buffer enhances
 data throughput by buffering sector data between the Caviar and the
 AT system bus. The buffer is accessed by two channels, each having a
 separate 16-bit address and byte-count register. The channels operate
 simultaneously, accepting read and write operations from two data
 paths.


 Universal Translation
 ---------------------
 The Caviar implements linear address translation. The translation
 mode and translated drive configuration are selected by using the Set
 Drive Parameters command to issue head and sector/track counts to the
 translator. Caviar supports universal translation, therefore, any
 valid combination of cylinder, head and SPT can be assigned to the
 drive, as long as the total number of sectors is not greater than the
 physical limits. The product of the cylinder, head and sectors/track
 counts must be equal to or less than the maximum number of sectors
 available to the user. The maximum number of sectors per drive are:

 AC1210 - 415,380
 AC2420 - 830,760

 Each sector consists of 512 bytes.

 The minimum values for any translation parameter is one. The maximum
 value for any translation parameter is as follows:

 Sectors/Track    - 255
 Heads            -  16
 Cylinders/Drive - 2048



**********************************************************************
                      F   E   A   T   U   R   E  S
**********************************************************************
WESTERN  WDAC1210/AC2420  TECHNICAL REFERENCE MANUAL

 Zoned Recording
 ---------------
 The AC1210, and AC2420 drives employ Zoned Recording to in-
 crease the data density on the outer tracks of the drive. The outer-
 most tracks contain 71% more sectors than the innermost tracks,
 thereby increasing the total capacity of the drive.



 Advanced Defect Management
 --------------------------
 The Caviar is preformatted (low-level) at the factory and comes with
 a full complement of defect management functions. Extensively tested
 during the manufacturing process, media defects found during
 intelligent burn in are mapped out with Western Digital's high
 performance defect management technique. No modifications are
 required before installation.


 Embedded Servo Control
 ----------------------
 The Caviar festures an embedded servo concept as the means of
 providing sampled position feedback information to the head position
 servo system. Servo bursts are located along a radial path from the
 disk center,ensuring that head positioning data occurs at constant
 intervals. This high sampling rate supports the high frequency
 servo bandwidth required for fast access times as well as highly
 accurate head positioning. The embedded servo concept provides the
 means of generating accurate feedback information without requiring
 a full data surface as would a dedicated servo control concept.


 Seek Time
 ---------
 Average Seek           Sub-13 Milliseconds

 Track-to-Track Seek         4 Milliseconds

 Maximum Seek               26 Milliseconds

 Index Pulse Period         18 Milliseconds

 Average Latency             9 Milliseconds


 Voice Coil Assembly
 -------------------
 The voice coil assembly consists of an upper and lower magnetic
 plate, a flat rotary coil, a bidirectional crash stop and a pivot
 bearing. The pivot assembly fits in the actuator block bore.


 Defect Management
 -----------------
 Every Caviar undergoes factory-level intelligent burn in, which
 thoroughly tests for and maps out defective sectors on the media
 before the drive leaves the manufacturing facility. Following the
 factory tests, a primary defect list is created. The list contains
 the sector cylinder and head numbers for all defects. The purpose of
 the sector/track map is to manage the reallocation of spare sectors
 and tracks after they have been assigned.

 Defects managed at the factory are sector slipped. Grown defects that
 can occur in the field are handled by realocation to spare sectors on
 the inner cylinders of the drive.


 Format Characteristics
 ----------------------
 In order to be compatible with existing industry standard defect
 management utility programs, the Caviar supports logical format. When
 the host issues the Format Track command, the Caviar performs a
 logical version of this command in response to the host's interleave
 table request for good and bad sector marking or assign/unassign the
 sector to/from an alternate sector.

 If the host issues the Format Track Command during normal operating
 modes, the data fields of the specified track are filled with a data
 pattern of all zeros. The interleave table identifies any bad sectors
 on a given track. The interleave table must contain all appropriate
 number of bytes of data. There are two bytes per sector for each
 entry in the interleave table. The first byte marks the sector as
 good or bad.



**********************************************************************
                      G   E   N   E   R   A   L
**********************************************************************
WESTERN   ALLGEMEINES

 QUESTION
 --------
 Which hard drive specification is most important to overall system
 performance ?

 - Host Transfer Rate

 - Drive RPM (revolutions per minute)

 - Disk Transfer Rate (Media Rate)

 - Seek Time

 - Cache Size

 - PC Data Handling

 - All of the above

 Answer
 ------
 The correct answer is actually a combination of "all of the above,"
 keeping in mind most of the above specifications are interrelated
 when it comes to optimizing system performance.

 The pie chart illustrates the relative influence of factors affecting
 drive performance during a typical random I/O operation (reading
 and writing to a hard drive).

 The major determinate of hard drive performance is mechanical
 factors which are one hundred times slower than the high-speed
 electronics contained in a drive.


 Factors Affecting Hard Drive Performance
 (In their relative order of importance)

 MECHANICAL LATENCIES
 Mechanical Latencies include both Seek Time and Rotational
 Latency. The seek time is a measure (in milliseconds) of how
 fast the hard drive can move its read/write heads to a desired
 location. Rotational latency is a measure of the average time
 (also in milliseconds) the read/write heads must wait for the
 target sector on the disk to pass under them once the read/write
 heads are moved to the desired target track.

 Mechanical latencies are the main hindrance to higher performance
 in modern Enhanced IDE (EIDE) hard drives. The time delays of
 mechanical latencies are one hundred times higher than
 electronic (non-mechanical) latencies associated with the
 transferring of data. Therefore, reducing mechanical latencies
 (a lowering of seek time and rotational latency) should be the
 top consideration in improving hard drive performance.


 RPM
 ---
 This is the rotational speed of the media (disk), also referred
 to as the spindle speed. Hard drives only spin at one constant
 speed. Typical speeds are 3600 to 3880, 4500, and 5200 to 5400
 revolutions per minute. The slower the RPM, the higher the
 Mechanical Latencies. Disk RPM is a critical component of hard
 drive performance because it directly impacts the rotational latency
 and the Disk Transfer Rate explained below.


 DISK TRANSFER RATE
 ------------------
 The Disk Transfer Rate (sometimes called media rate) is the
 speed at which data is transferred to and from the disk media
 (actual disk platter) and is a function of the recording frequency.
 Typical units are bits per second (BPS), or bytes per second.
 Modern hard disks have an increasing range of Disk Transfer
 Rates from the inner diameter to the outer diameter of the disk.
 This is called a "zoned" recording technique.

 The key media recording parameters relating to density per platter
 are Tracks Per Inch (TPI) and Bits Per Inch (BPI). A track is a
 circular ring around the disk. TPI is the number of these tracks
 that can fit in a given area (inch). BPI defines how many bits
 can be written onto one inch of a track on a disk surface. To
 greatly simplify, the Disk Transfer Rate (the rate at which data
 is read and written to the disk) is dependent upon the speed of
 the disk (RPM) and the density of the data on the disk (BPI).
 Even most modern, high-speed, 5000 RPM hard drives are generally
 limited to a maximum Disk Transfer Rate of approximately 9 to 10
 MB per second. This specification is critical to performance and
 must be weighed carefully against such electronic latencies as
 Mode 3 PIO and Mode 4 PIO host transfer rates explained below.


 PC DATA HANDLING
 ----------------
 After the data moves down the IDE cable from the drive to the host
 interface, there are several factors that can affect drive
 performance over which the hard drive has no control. PC Data
 Handling is independent from the hard drive and very dependent
 upon the CPU type and speed, the BIOS overhead (how the system
 issues commands to the hard drive), speed and size of the system
 RAM and RAM cache, CPU-to-memory speed, and storage subsystem
 performance. PC Data Handling is also affected by the caching
 methods of such software applications as SMARTDRIVE, 32-bit
 disk access operating system drivers, etc.


 HOST TRANSFER RATE
 ------------------
 The speed at which the host computer can transfer data across the
 IDE or EIDE interface. Processor Input/Output (PIO) modes and
 Direct Memory Access (DMA) modes are defined in the ATA-2 industry
 specification as follows:

 Mode 3 PIO  11.1 MB/sec
 Mode 4 PIO  16.6 MB/sec
 Mode 1 DMA  13.3 MB/sec
 Mode 2 DMA  16.6 MB/sec

 Modern host computer systems usually support most of the above
 modes. Faster Host Transfer Rates in the future will use multi-word
 DMA modes as the industry will not support any future PIO mode
 standards beyond mode 4.

 The computer system manufacturer is responsible for implementing a
 Host Transfer Rate that is high enough to ensure that the host
 computer is not the performance bottleneck. Implementing
 increasingly higher Host Transfer Rates without corresponding
 increases in Disk Transfer Rates on the hard drive will not result
 in increased drive performance.


 Cache Buffer Size - Is Bigger Always Better ?
 A Cache Buffer is similar to a water glass. When you are writing
 to a hard drive, the host computer fills the glass and the disk
 media empties it. If you are reading data from a hard drive, the
 disk media fills the glass and the host computer empties it.

 The reason that a bigger cache buffer is not always better
 (or faster) is because the host computer (with Mode 4 PIO or
 Mode 2 DMA capabilities) can empty or fill the glass much faster
 than the hard drive can empty or fill it. When the host system can
 transfer data in or out of the cache buffer faster than the media
 rate, a larger buffer size becomes irrelevant because the host
 system is always "waiting" for the hard drive.

 Western Digital hard drives are designed with cache buffer sizes
 that are matched to the Disk Transfer Rate capabilities of the
 drive and the Host Transfer Rates of modern computer systems. All
 of our drives are benchmarked with various cache buffer sizes to
 verify that the most cost-effective and performance-effective
 cache size is implemented.


 Confusion Over Mode 4 and Mode 2 DMA
 ------------------------------------
 The Enhanced IDE program created the long-range road map for
 performance enhancements which included faster disk and host
 transfers, Mode 3, Mode 4, Mode 2 DMA, etc. Currently, computer
 systems and hard drive controller silicon have most of the elements
 needed to implement Mode 4 PIO or Mode 2 DMA (a 16.6 MB/sec Host
 Transfer Rate). However, to take advantage of these performance
 modes, physical drive architecture must also make some performance
 improvements in the area of Mechanical Latencies and Disk Transfer
 Rate (media rate) as defined earlier.

 Some competitors, in their eagerness to supply a new feature, are
 prematurely marketing Mode 4 and Mode 2 DMA. While their drive
 controller silicon supports these modes (which is very easy and
 inexpensive to implement), spindle speeds (RPM), rotational latency,
 bit density, and other factors have not yet been improved (these
 being very difficult and costly). The result is hard drives which
 have the electronic capability to do Mode 4 and Mode 2 DMA transfer
 rates, but can't take advantage of these modes due to the slower
 Disk Transfer Rate of the drive.

 Western Digital will not be implementing Mode 4 or Mode 2 DMA on
 older drive products as the host systems into which these drives
 are designed are not electrically capable of these data transfers,
 nor are the Disk Transfer Rates on these drives beyond current Mode
 3 capabilities. As next generation systems are introduced, they will
 be paired with next generation drives. Those drives will require
 and offer true Mode 4 / Mode 2 DMA capability from a total drive
 architecture standpoint.

 ====================================================================
 AC2540/2635/2700/2850/21000/31000/31200/31600

 Windows 95 Operating System Addendum
 ------------------------------------
 The information in this addendum supersedes that supplied in Windows
 95 section on pages 35 and 36 of this manual. Please refer to thos
 addendum for Windows 95 questions.

 Although Windows 95 is capable of recognizing the full capacity of
 hard drives larger than 528 MB in systems with a translating BIOS,
 some restrictions apply to systems without a translating BIOS.


 For Systems With a Translating BIOS
 -----------------------------------
 Enter your CMOS setup and select a drive type that will recognize the
 full capacity of your drive. This is usually done by selecting the
 auto config drive tape. The boot partition can be set up to be as
 large as the full capacity of your hard drive.


 For Systems Without a Translating BIOS
 --------------------------------------
 Enter your CMOS setup and select a user defined drive type. Enter
 these parameters: cylinders = 1024, heads = 16, sectors = 63. Your
 system's total disk space will be limited to a maximum of 528MB.

 If you want your system to utilize more than 528 MB of disk space,
 you must use Ontrack's Disk Manager software (or a similar third-
 party installation software).


 Installing Windows 95 on a Hard Drive with Ontrack Disk Manager
 Already Installed
 ---------------------------------------------------------------
 The Windows 95 installation program will analyze your computer
 system and install seamlessly with Ontrack Disk Manager.


 Computer Systems with Windows 95 Already Installed
 --------------------------------------------------
 If you are installing a Western Digital hard drive and Ontrack Disk
 Manager on a computer system with Windows 95 already installed, you
 must install Ontrack Disk Manager as described here.

 Enter your CMOS setup and select a user defined drive type. Enter
 these parameters for drives with capacities over 528MB:
         Cylinders = 1024, Heads = 16, Sectors = 63.

 Save these changes and reboot your computer.

 1. Select the Start icon from the Windows 95 main screen.
    DO NOT open an MS-DOS menu from Win 95 to install Ontrack Disk
    Manager.

 2. Choose the Shut Down option.

 3. Select Resatrt Computer in DOS mode. When your computer restarts,
    you should be at the DOS prompt.

 4. Install Ontrack Disk Manager.

 Windows 95 will noe recognize the full capacity of your hard drive
 and run in 32-bit disk access mode for optimum performance.


