Download SCSI Termination Tutorial

SCSI Termination Tutorial
INTRODUCTION
The purpose of this white paper is to help understand common field issues that you might
run into when connecting a SCSI drive (or drives) to various kinds of SCSI buses,
whether cable or backplane. The paper is organized into three sections: background and
history of SCSI including terminology, termination basics and field issues. There are
seven field scenarios discussed, each with a checklist of things to look for, and several
actual case studies:
1. Connecting NARROW drives to a NARROW bus (50 pin to 50
pin)
2. Connecting WIDE drives to a WIDE bus (68 pin to 68 pin)
3. Connecting NARROW drives to a WIDE bus (50 pin to 68 pin)
4. Connecting WIDE drives to a NARROW bus (68 pin to 50 pin)
5. Connecting WIDE SCA-2 drives to a WIDE bus (80 pin to 68
pin)
6. Connecting WIDE SCA-2 drives to a NARROW bus (80 pin to
50 pin)
7. Connecting WIDE SCA-2 drives to a WIDE bus (80 pin to 80 pin
or proprietary)
This tutorial is intended for an audience familiar with conventional IDE/SCSI terms, PC
operation and understanding of the basics of SCSI technology. While every attempt has
been made to make this tutorial as comprehensive as possible, an individual may be
confronted with a situation which is not addressed within the text.
BACKGROUND
As the SCSI interface has evolved from the original 50 pin connection to 68 and even 80
pins, so has the speed and complexity of the devices that now connect to the bus.
Connecting any SCSI device, let alone ‘wide’ devices to ‘narrow’ buses and vice-versa
requires a careful understanding of SCSI terminology, termination practices, terminators
and adapters, and drive specific requirements. Let’s start with an overview of SCSI and
the rather confusing terminology that is in current use (see Table 1).
(back)
HISTORY
The original SCSI interface used a 50 pin connector; the SCSI "bus" therefore, was 50
conductors and was typically implemented either in a flat ribbon cable or a backplane.
Eight of the conductors were allotted for data lines (plus one for a parity bit), and
therefore became known as an "8-bit wide" bus; the bus speed and therefore the data rate
was limited to 5Mhz (5Mbytes/sec). Both Single Ended (SE) and differential versions
(two different means of electrically driving the bus) were available but because they used
different pinouts, could not be interchanged. Differential signaling is less sensitive to
noise, and can be used over longer distances, at higher bus speeds. This first version of
SCSI is based on an ANSI standard, which is now called "SCSI 1" and is also known as
"narrow" SCSI. The differential version is known today as "high voltage differential", or
HVD, since they had not yet invented the low voltage differential in use today.
To increase bandwidth, i.e. move more data on the bus faster, the bus speed was
increased to 10Mhz and called "Fast SCSI". A new ANSI standard, called "SCSI 2"
defined this interface.
Now it becomes slightly more confusing. As the SCSI documentation began to get
unwieldy, the next ANSI standard, or "SCSI 3", was broken up into a series of smaller
documents, each covering a ‘layer’ of the interface. The layer that covers the electrical
connectors, pin assignments, etc. is now called "SPI", or ‘SCSI Parallel Interface’ (other
layers cover the commands, protocols, etc.). So the main point here is that SCSI 1, SCSI
2 and SCSI 3 refer to the documentation, or specs, that further define the interfaces, not
necessarily drive performance, although the latest version, SCSI 3, covers all of the latest
features.
Then 8 more data bits (and another parity bit) were added to the bus so that two bytes at a
time could be transferred. This became "Fast Wide SCSI" which doubled the data rate
(not the bus speed) to 20 Mbytes/sec. This new "wide" SCSI required more conductors,
which led to a 68 pin connector; both Single Ended and differential versions were
available.
For easier connection to a backplane and to allow ‘hot plugging’, the SCA-2 (Single
Connector Attachment 2) 80 pin connector was developed, which is used on wide bus
versions, only. It is not designed for direct cable attachment, due to the combination of
power and bus signals in the connector.
The next performance increase is "Ultra SCSI" also known as Fast-20, which uses a bus
speed of 20 Mhz; for a narrow bus, this is equivalent to a data rate of 20Mbytes/sec.
"Wide Ultra SCSI", for a wide bus, is equivalent to 40 Mbytes/sec.
As speed increased, maximum allowable cable length decreased, so to move up to the
next performance level and keep a reasonable cable length, a new signaling method was
developed called ‘Low Voltage Differential’, or LVD. This allows the bus speed to
double again, and is called "Ultra2 SCSI", which is equivalent to 40 Mbytes/sec. for a
narrow bus, and "Wide Ultra2 SCSI" is equivalent to 80 Mbytes/sec for a wide bus, also
known as "Fast 40" define in SPI-2.
Next comes "Ultra3 SCSI", which, according to the spec, defines as many as 63 different
variations of features! A specific set of these features has been agreed upon within the
industry and named "Ultra 160" and doubles the data rate to 160 Mbytes/sec (wide bus
only), also known as Fast-80DT defined in SPI-3. These new features are: Double
Transition Clocking, CRC, Domain Validation, Packetization and Quick Arbeitrate select
(QAS). See Table 1. below for a summary of current bus speeds and SCSI terminology,
as endorsed by the SCSI Trade Association.The next iteration, now in development, is
"Ultra 320" also known as Fast-160 paced data transfer defined in SPI-4.
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Table 1. STA-Endorsed Terms & Terminology for SCSI
STA Terms
Bus Speed,
Bus
MBytes/Sec. Width,
Max.
bits
Max. Bus Lengths, Meters (1)
Singleended
(SE)
LVD
HVD
Max.
Device
Support(7)
5
8
6
(3)
25
8
Fast SCSI (2)
10
8
3
(3)
25
8
Fast Wide SCSI
20
16
3
(3)
25
16
Ultra SCSI (2)
20
8
1.5
(3)
25
8
Ultra SCSI (2)
20
8
3
-
-
4
25
16
SCSI - 1 (2)
Wide Ultra SCSI
40
16
-
(3)
Wide Ultra SCSI
40
16
1.5
-
-
8
Wide Ultra SCSI
40
16
3
-
-
4
8
(4)
12
25
8
12
25
16
12
(5)
16
12
(5)
16
Ultra2 SCSI
(2,4)
40
Wide Ultra2 SCSI (4)
80
16
(4)
Ultra 160 SCSI (6)
160
16(6)
(4)
320
(6)
(4)
Ultra320
(6)
16
Notes:
(1) The listed maximum bus lengths may be exceeded in point-to-point and engineered applications.
(2) Use of the word "narrow", preceding SCSI, Ultra SCSI or Ultra2 SCSI is optional.
(3) LVD was not defined in the original SCSI standards for this speed. If all devices on the bus support
LVD, then 12-meters operation is possible at this speed. However, if any device on the bus is Single-Ended
only, then the entire bus switches to Single-Ended mode and the distances in the Single-Ended column
apply.
(4) Single-Ended is not defined for speeds beyond Ultra.
(5) HVD (Differential) is not defined for speeds beyond Ultra2.
(6) After Ultra2 all new speeds are wide only.
(7) Why are there multiple entries for the Ultra SCSI interface? The answer has to do with the inherent
difficulties of transmitting high speed parallel data over cable or backplane. Assuming that the SCSI bus is
properly terminated, there are three factors that can still degrade performance on the SCSI bus: a) high
frequency attenuation, which causes the pulses to be rounded off and gets worse with longer cable length.
b) skew, which is the difference in propagation times from one data line to another, which also gets worse
with longer cable length. c) stubs, which are SCSI devices attached to the cable. So, with a longer cable,
there must be less stubs, i.e. fewer drives. With a shorter cable, more stubs (drives) can be tolerated. This is
shown in the Max Device Supported column in the table.
(back)
TERMINATION - basics
Why terminate?
A pulse propagating along the SCSI bus will ‘reflect’ from any part of the bus that is
different from the rest of it. These reflections add and subtract in odd combinations and
cause the original pulse to be distorted and corrupted, thereby causing data loss. To
prevent or minimize reflections from the ends of the bus, terminators are added to
"absorb" the energy from the pulses.
The terminators on the SCSI bus hold the bus in a negated state, any one of up to 16
drivers could be driving the bus or none. The bus is held in the negated state as required
by the SCSI protocol. The original drivers on a SCSI bus only asserted (Open collector)
and the terminators were used to negate the bus. Drivers that assert and negate the bus are
known as active negation drivers. The negation is less current than the assertion, the
drivers are designed for 2 terminators negating the bus.
Where do you terminate the bus?
[Terminate: from the latin terminus meaning "the end".]
Termination must be present at two and only two positions on the SCSI bus, at the
beginning of the bus, and at the end, and must occur within 4 inches of the physical ends
of the SCSI bus. Often, the host will be installed at one end of the bus, and will provide
one of the two terminations required.
When do you terminate the bus?
Always. Period. Whenever you want the SCSI bus to operate reliably!
How are terminators powered?
Terminators are powered from the "term power" line on the SCSI bus. Term power can
come from any device on the bus, and is provided by either the host, a drive on the bus,
the backplane, or any combination thereof. Term power is provide through a diode and
fuse - historically - the drop accross the diode and cable allows for a term power range of
4.0 to 5.25 volts.
What kinds of terminators are available?
Internal: some SCSI drives (pre-LVD) had passive terminators installed
in the drive, and could
be enabled/disabled by setting a jumper or inserted/removed from a
socket. Drives with
LVD interface do not have internal termination due to reduce bus loading,
and the fact that in a multi-drive
environment, only one drive needs to be terminated.
External:
In-line (also called ‘feed-through’) terminators connect in series with a
SCSI device.
Close-ended terminators plug into a bus connector or may be crimped on
the cable.
Passive: resistor networks driven directly by the term power on the bus.
Active: resistor networks driven by voltage regulators inside the
terminator. All LVD
terminators can be assumed to be ‘active’.
What is the difference between passive and active termination?
Passive termination is a resistor network, 330 ohms from ground to the signal line and
220 ohms from the signal line to termpower, which is an equivalent impedance of around
132 ohms. Since typical characteristic impedance of most cable is between 85 and 110
ohms, this is not a great match. The negation current varies with the term power voltage
which can be from 4.0 to 5.25 volts, the pull up current would range from 16.5 to 24 mA.
This would often required multiple steps to insure the voltage reached the 2.0 volt at the
receiver. An active termination incorporates a small voltage regulator which generates a
stable termination voltage from the raw Term Power (which may fluctuate) and allows
the termination resistance to be lowered to 110 ohms, more closely matching the cable
impedance. Active termination is recommended for all Single Ended buses at any speed,
and is required for Single Ended Ultra SCSI speeds and above. New systems with active
terminates may be powered from a 3.3 volt source, termpower can be from 2.7 to 5.25
volts.
Other important terminology related to termination, for the discussion that follows:
Active Negation. Asserting a signal on a Single Ended SCSI bus requires driving the
signal low; de-asserting (negation) is the opposite, allowing the signal to be pulled high
by the terminator. For fastest bus speeds, the signal may be ‘driven’ high by a driver in
either the host or SCSI device, thus ‘active negation’. Active terminators must not
prevent active negation. Active negation is required for Ultra SCSI (Fast-20).
High Byte. The upper data byte (bits 8-15) on a wide bus. This includes eight data and
one parity bit, for a total of nine bits.
Low Byte. The lower data byte (bits 0-7) on the SCSI bus. This includes eight data and
one parity bit, for a total of nine bits.
Multidrop. A SCSI bus with more than two devices on it.
Multimode LVD/MSE. LVD devices respond to the voltage on the DIFFSENS line on
the bus, and can switch modes from LVD to Single Ended. Active terminators must drive
the diffsense line with 1.3 volts with low current, and therefore be able to respond to the
DIFFSENS line, such that if the voltage is < 0.7v, the terminator will be in the Single
Ended mode; > 0.9 and < 1.9v is the LVD mode. Should the DIFFSENS line see > 2.4v,
the terminator should tri-state off the bus as it is seeing HVD (High Voltage Differential).
Point-to-point. A SCSI bus with only two devices on it; one at each end.
Stub length. The distance from the drivers/receivers on the SCSI device to the bus where
it is plugged in. This may include the traces on the drive pcb, inline terminator, etc.
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FIELD ISSUES RELATED TO CONNECTING SCSI DRIVES
The following seven scenarios represent common field interconnect issues encountered
when connecting SCSI devices to various buses. Typically the drive either won’t be
recognized by the host system, may not spin up, or the performance may be degraded.
1. Connecting NARROW drives (50 pin) to a NARROW bus (50 pin).
A narrow bus by definition is 50 conductors, but may be either Single Ended (SE) or
differential (HVD). They cannot be mixed on the same bus. There are 3 50 pin
connectors defined in the SCSI standards; 50 pin internal (0.1 inch spacing), 50 pin low
density (Centronics) and 50 pin high density (0.05 inch spacing). 25 pin connectors are
often used, but are not defined in the SCSI standards, there are a limited number of
ground connections which often cause problems if used on fast or Ultra SCSI speeds.




Check for the presence of term power on pin 26 or 38 (center of
the connector second row) of the bus, provided by the host, any
drive or the backplane.
Check for two terminators, one at each physical end of the bus.
Many 50 pin drives are internally terminated; check jumper
settings to enable/disable.
Active terminators are required if Ultra SCSI speeds (20
Mbytes/sec) or higher are being used.
No more than 8 devices are supported in this configuration; see
Table 1.




Check maximum bus (cable) length, as described in Table 1.
Check maximum stub length does not exceed 0.1m (4").
Check SCSI IDs. Each device must have a unique ID, typically
set by jumper.
Check for remote start/start delay jumpers and remove if
necessary.
(back)
2. Connecting WIDE drives (68 pin) to a WIDE bus (68 pin).
A wide bus can run in Single Ended (SE), High Voltage Differential (HVD) or Low
Voltage Differential (LVD) mode. Single Ended and LVD drives can be mixed, however
the bus will revert to the slower Single Ended speeds (Ultra SCSI) and mode of operation
when mixed, which is determined by the DIFFSENS level on the bus. Although rare,
there are some wide bus applications still running in the HVD mode, which are not
compatible with LVD or SE.





Check for the presence of term power on pins 17, 18, 51, 52,
provided by the host, any drive or the backplane.
Older backplanes designed for SE operation may have signal
ground lines sunk directly into the backplane ground, which
will not allow them to work in the newer LVD mode, where the
signal grounds have been redefined to become the +side of a
differential pair. If this is the case, LVD drives will only operate
in SE mode.
Check for two terminators, one at each physical end of the bus.
The terminators must be capable of SE and/or LVD modes (i.e.
multimode operation).
Active terminators are required if Ultra SCSI speeds (20
Mbytes/sec) or higher are being used and the bus is in Single
Ended mode.
Check the DIFFSENS level on pin 16. If any device is Single
Ended, the level will be <0.7v. If all devices are operating in
LVD mode, the level must be >0.9 and < 1.9v for the bus to run
in the LVD mode.





Check maximum bus (cable) length and number of devices
supported, as described in Table 1, for LVD or SE mode.
Check maximum stub length does not exceed 0.1m (4").
Check SCSI IDs. Each device must have a unique ID, typically
set by jumper.
Check for remote start/start delay jumpers and remove if
necessary.
Check for ‘Force SE’, ‘Disable Wide’, ‘Disable U160’ jumpers
and remove if necessary.
(back)
3. Connecting NARROW drives (50 pin) to a WIDE bus (68 pin).
A wide bus can run in Single Ended (SE) or Low Voltage Differential (LVD) modes,
however certain older narrow drives could be differential, or HVD, which is not
compatible with LVD or SE (be careful not to mix LVD and HVD). If a narrow drive,
running in the SE mode, is mixed with LVD drives, the entire bus will run in Single
Ended mode.

A cable adapter is required to convert the 50 pin narrow
interface to the 68 pin wide bus. If this is a transition point wide
bus to narrow, the high byte must be terminated if there is
more than the wide adapter and the last device on the single
ended bus must terminated the bus. If this is a single device
with and adapter to wide, the wide bus should be terminated at
both ends of the bus, the adapter should not terminate the high
byte.

Check for the presence of term power on pins 17, 18, 51, 52,
provided by the host, any drive or the backplane.
Check for two terminators, one at each physical end of the bus.
The terminators must be capable of SE mode. Some 50 pin
drives are internally terminated; check jumper settings to
disable as a narrow drive cannot terminate a wide cable.







Active terminators are required if Ultra SCSI speeds (20
Mbytes/sec) or higher are being used and the bus is in Single
Ended mode.
Check the DIFFSENS level on pin 16 of the bus. The narrow
drive interface adapter will normally ground this pin due to the
presence of a narrow (SE) drive. Alternately, there are special
adapters that are designed to allow a Single Ended drive to be
attached to an LVD bus. These adapters act as a bridge between
Single Ended and LVD devices and allow the bus to stay in the
LVD mode. With such an adapter installed, the DIFFSENS level
should remain >0.9v and < 1.9v.
Check maximum bus (cable) length and number of devices
supported, as described in Table 1, for SE mode (unless the
bridge adapter mentioned above is installed).
Check maximum stub length does not exceed 0.1m (4").
Check SCSI IDs. Each device must have a unique ID, typically
set by jumper.
Check for remote start/start delay jumpers and remove if
necessary.
(back)
4. Connecting WIDE drives (68 pin) to a NARROW bus (50 pin).
A narrow bus by definition is 50 conductors, but may be either Single Ended (SE) or
differential (HVD). The two have identical looking connectors and cannot be mixed on
the same bus. A wide drive can only be added to a narrow bus if the bus is Single Ended
(SE).


Check for the presence of term power on pin 26 or 38 of the bus,
provided by the host, any drive or the backplane.
An adapter is required to convert the wide drive interface to
the narrow 50 pin bus connector; the upper byte, or ‘high byte’
of the wide connector must be terminated with +5volts inside
the adapter, because a floating (not connected) data line is an
undefined signal level and will cause parity errors and
arbitration problems.








Check for two terminators, one at each physical end of the bus.
Many 50 pin drives found on a narrow bus are internally
terminated; check jumper settings to enable/disable.
Active terminators are required if Ultra SCSI speeds (20
Mbytes/sec) or higher are being used.
No more than 8 devices are supported in this configuration; see
Table 1.
Check maximum bus (cable) length, as described in Table 1.
Check maximum stub length does not exceed 0.1m (4").
Check SCSI IDs. Each device must have a unique ID, typically
set by jumper.
Check for remote start/start delay jumpers and remove if
necessary.
Check for ‘Force SE’, ‘Disable Wide’ jumpers and apply as
required.
Case study: a Customer connected WD Vantage drive to narrow bus, using Customer
supplied 68 to 50 pin adapter. Drive would not spin up. Bus was properly terminated,
externally. Problem: upper data byte was not terminated with +5v. Solution: WD
provided special firmware (available from WD by special request) that internally
terminates the upper data byte. When downloaded, the drive worked OK. An alternative
solution would be to use a different 68 to 50 pin adapter that provides the necessary upper
byte termination.
(back)
5. Connecting WIDE SCA-2 (80 pin) drives to a WIDE bus (68 pin).
A wide bus can run in Single Ended (SE), High Voltage Differential (HVD) or Low
Voltage Differential (LVD) mode. Single Ended and LVD drives can be mixed, however
the bus will revert to the slower Single Ended speeds and mode of operation when mixed,
which is determined by the DIFFSENS level on the bus. Although rare, there are some
wide bus applications still running in the HVD mode, which are not compatible with
LVD or SE. There is no term power line on the 80 pin connector, termination must be
provided in the adapter or backplane. The 80 pin connector is designed for hot plugging,
providing sequenced power. Power must be provide by the adapter or backplane. The
adapter has the ID switches, there are no ID settings on the SCA-2 drives, the backplane
position determines the device ID.
The SCA-2 connector is designed for hot plug systems for minimum bus loading. The
used of an adapter for each drive doubles the bus loading, it is recommended that 2
adapters maximum be used on a system. It is better to use a backplane or 68 pin drives.










Check for the presence of term power on the bus on pins 17, 18,
51, 52, provided by the host, any drive or the backplane.
Older backplanes designed for SE operation may have signal
ground lines sunk directly into the backplane ground, which
will not allow them to work in the newer LVD mode, where the
signal grounds have been redefined to become the +side of a
differential pair. If this is the case, LVD drives will only operate
in SE mode.
An adapter is required to convert the SCA-2 80-pin interface to
the wide 68-pin bus connector; check the adapter to make sure
that it supports both LVD and SE. See case study, below. Pin 46
on the 80 pin side is the DIFFSENS line; check that it is at the
correct level for either SE (<0.7v) or LVD (>0.9v and <1.9v)
operation.
Check for two terminators, one at each physical end of the bus.
The terminators must be capable of SE and/or LVD modes (i.e.
multimode operation).
Active terminators are required if Ultra SCSI speeds (20
Mbytes/sec) or higher are being used.
Check maximum bus (cable) length, as described in Table 1.
Check maximum stub length does not exceed 0.1m (4").
Check SCSI IDs. Each device must have a unique ID, typically
set by jumper.
Check for remote start/start delay jumpers and remove if
necessary.
Check for ‘Force SE’, ‘Disable Wide’, ‘Disable U160’ jumpers
and remove if necessary.
Case study: a Customer attempted to attach a WD Vantage 80 pin LVD drive to a 68 pin
bus, and the drive was not recognized by the host. The system was a PC with host
adapter, 68 pin cable properly terminated at both ends of the cable. The Customer used an
unknown 68 pin to 80 pin adapter purchased at a local electronics store, which worked on
some drives, but not all. Term power was present on the bus without the drive present, so
the issue was not termination. The problem was determined to be that the adapter card’s
signal ground lines were all tied together, and grounded, thus forcing the drive to operate
only in the SE mode. However, the DIFFSENS line (pin 46 on the 80 pin side) was left
floating, not connected to anything. This caused some drives to try to enter the LVD
mode, however the adapter card only supported SE mode, so the drive was unable to
communicate with the host. A few drives using this adapter worked because a floating
DIFFSENS signal (an illegal state) caused them to enter the SE mode. Solution: Change
adapters to one with a grounded DIFFSENS line for SE operation.
(back)
6. Connecting WIDE SCA-2 (80 pin) drives to a NARROW bus (50 pin).
A narrow bus by definition is 50 conductors, but may be either Single Ended (SE) Low
Voltage Differential (LVD) or differential (HVD). HVD devices cannot be mixed SE or
LVD devices on the same bus. A wide drive can only be added to a narrow bus if the bus
is Single Ended (SE).









Check for the presence of term power on pin 26 of the bus,
provided by the host, any drive or the backplane.
An adapter is required to convert the SCA-2 80-pin interface to
the narrow 50-pin bus connector. The upper byte, or ‘high byte’
of the wide connector, must be terminated with +5volts inside
the adapter, because a floating (not connected) data line is an
undefined signal level and may cause parity errors. The
DIFFSENS line, pin 46 on the 80 pin side, should be grounded
for SE operation.
Some SCA-2 adapters also provide bus termination; if the drive
is not at the end of the bus check that the termination can be
disabled on the adapter.
Check for two terminators, one at each physical end of the bus.
Many 50 pin drives found on a narrow bus are internally
terminated; check jumper settings to enable/disable.
Active terminators are required if Ultra SCSI speeds (20
Mbytes/sec) or higher are being used.
No more than 8 devices are supported in this configuration; see
Table 1.
Check maximum bus (cable) length, as described in Table 1.
Check maximum stub length does not exceed 0.1m (4").
Check SCSI IDs. Each device/adapter must have a unique ID,
typically set by jumper.


Check for remote start/start delay jumpers and remove if
necessary.
Check for ‘Force SE’, ‘Disable Wide’ jumpers and apply as
required.
(back)
7. Connecting WIDE SCA-2 (80 pin) drives to a WIDE bus (80 pin or proprietary).
A wide bus can run in Single Ended (SE), High Voltage Differential (HVD) or Low
Voltage Differential (LVD) mode. Single Ended and LVD drives can be mixed, however
the bus will revert to the slower Single Ended speeds and mode of operation when mixed,
which is determined by the DIFFSENS level on the bus. Although rare, there are some
wide bus applications still running in the HVD mode, which are not compatible with
LVD or SE.





Check for the presence of term power at the terminators, the
SCA-2 connector does not have term power, the devices are not
allowed to terminate the bus. Term power must be provided by
the host, or the backplane.
Older backplanes designed for SE operation may have signal
ground lines sunk directly into the backplane ground, which
will not allow them to work in the newer LVD mode, where the
signal grounds have been redefined to become the +side of a
differential pair. If this is the case, LVD drives will only operate
in SE mode.
An adapter may be required to convert the SCA-2 80-pin
interface to the backplane connector; check the adapter to make
sure that it supports both LVD and SE. See case study, below.
Pin 46 on the 80 pin side is the DIFFSENS line; check that it is at
the correct level for either SE (<0.7v) or LVD (>0.9v and <1.9v)
operation.
Check for two terminators, one at each physical end of the bus.
The terminators must be capable of SE and/or LVD modes (i.e.
multimode operation).
Active terminators are required if Ultra SCSI speeds (20
Mbytes/sec) or higher are being used.





Check maximum bus (cable) length, as described in Table 1.
Check maximum stub length does not exceed 0.1m (4").
Check SCSI IDs. Each device must have a unique ID, typically
set by the backplane position.
Check for remote start/start delay jumpers and remove if
necessary.
Check for ‘Force SE’, ‘Disable Wide’, ‘Disable U160’ jumpers
and remove if necessary.
Case study: a Customer uses a backplane with proprietary ‘DIN’ connectors; a small
paddle card is connected between the WD Vantage 80 pin drive and the DIN connector.
A standard 68 pin connector is provided on backplane for plug-in terminator. Terminator
has LED showing term power present. System is running in SE mode. Problem: WD
Vantage 80 pin drive won’t spin up. The problem was determined to be that pin 46
(DIFFSENS) on the SCA-2 side of the paddle card was open, not connected. This allows
the drive to go into the LVD mode, not the SE mode. Solution: Customer grounded pin
46 on the paddle card.
(back)
Allan Hughes, 01/17/00