6.3 FDD Interface and Cabling
The
FDD interface and power requirements are completely standardized, as
follows:
- Controller
-
PC-class systems used a separate FDD
controller card. XT- and AT-class systems and some early 386s used a
combination HDD/FDD controller card. Current systems use an embedded
FDD controller. These controllers differ only in their maximum data
rate, which determines the FDD types they support. Early controllers
run at 250 Kb/s, which supports only 360 KB 5.25-inch FDDs and 720 KB
3.5-inch FDDs. Later controllers run at 500 Kb/s, which supports any
standard FDD, or at 1 Mb/s, which is required for 2.88 MB 3.5-inch
FDDs. Run BIOS Setup to determine which FDD types a given system
supports.
 |
If you must install a higher-capacity FDD than the controller
supports—e.g., if you must salvage data from a hard drive in a
system whose old 5.25-inch 360 KB FDD has failed and you have only a
3.5-inch HD FDD to replace it—you have two alternatives:
Remove or disable the onboard FDD
controller, and replace it with a third-party FDD controller that
supports the higher-capacity FDD. Lie to the old system about what type
of FDD you are installing. For example, install a 1.44 MB FDD, but
tell the system that it is a 360 KB or 720 KB FDD. All FDDs run at
300 RPM, except 5.25-inch 1.2 MB FDDs, which run at 360 RPM. That
means that any ED, HD, or DD 3.5-inch FDD can emulate any
lower-capacity 3.5-inch drive, as well as the 5.25-inch 360 KB FDD.
Use blank DD diskettes, and format them in the new drive. Copy data
to the floppies and then attempt to read them on another system. Some
systems will happily read such oddities as a 3.5-inch 360 KB
diskette, but others will simply return an "unknown
media type" message. If the latter occurs, use BIOS
Setup on the good system to reconfigure the FDD temporarily to the
same settings as those on the older system.
|
|
- Data cable
-
FDD data
cables use a standard 34-pin pinout (see Table 6-2), but connectors vary. 5.25-inch drives use a
card-edge connector. 3.5-inch drives use a header-pin connector.
Older standard FDD cables have at least three connectors, one for the
FDD interface and two for drives. Many FDD cables have five
connectors, with redundant header-pin and card-edge connectors at
each of the two drive positions, allowing any type of FDD to be
connected at either position. Because many newer systems support only
one FDD, new data cables have only two connectors, one for the FDD
interface and one for the drive itself.
Table 6-2. Floppy disk drive cable pinouts|
|
Odd pins (1 - 33)
|
Ground
| |
20
|
Step Pulse
| |
2, 4, and 6
|
Not Used
| |
22
|
Write Data
| |
8
|
Index
| |
24
|
Write Enable
| |
10
|
Motor Enable A
| |
26
|
Track 0
| |
12
|
Drive Select B
| |
28
|
Write Protect
| |
14
|
Drive Select A
| |
30
|
Read Data
| |
16
|
Motor Enable B
| |
32
|
Select Head 1
| |
18
|
Direction (Stepper Motor)
| |
34
|
Disk Change
|
- Power
-
Obsolete 5.25-inch drives accept the larger Molex power connector.
Current 3.5-inch drives accept the smaller Berg power connector,
shown in Figure 6-2. A chassis that permits a
3.5-inch drive to be installed in a 5.25-inch bay typically includes
a Molex-to-Berg adapter. Pinouts and voltages for both of these power
connectors are covered in Chapter 26.
The BIOS identifies the drive as A: or B:
based on how the drive is jumpered and by the cable position to which
that drive connects. Older 5.25-inch drives have four drive
select (DS) jumper positions, labeled
DS0 through DS3 or DS1 through DS4. Later drives have only two
settings, labeled DS0/DS1 or DS1/DS2. Many recent 3.5-inch drives are
permanently set to the second DS position (DS1/DS2). The BIOS
recognizes a drive set to the first DS position (DS0/DS1) as
A: and a drive set to the second
DS position (DS1/DS2) as B:,
assuming that the drive is connected to the controller with a
straight-through cable.
But a standard two-drive FDD cable has wires 10 through 16 twisted
between the first (middle) drive connector and the second (end) drive
connector, which effectively reverses the jumper setting on the drive
connected to the end connector. In other words, a drive that is
jumpered as the second drive (DS1/DS2 or B:) and
connected to the end connector is seen by the system as the first
drive (DS0/DS1 or A:) because of the twist.
Because many recent chipsets support only a single FDD, many recent
FDD cables have only two connectors, one for the motherboard FDD
interface, and the second for the single FDD. This cable has a twist,
shown in Figure 6-3, which means that a drive
connected to it must be set to the second DS position if it is to be
recognized as A:.
|
Main Menu
|
