Dell PowerVault 110T LTO2 (Tape Drive) spécification

Taper
spécification
www.dell.com | support.dell.com
Dell™ PowerVault™ Systems
Performance Considerations
for Tape Drives and Libraries
____________________
Information in this document is subject to change without notice.
© 2005 Dell Inc. All rights reserved.
Reproduction in any manner whatsoever without the written permission of Dell Inc. is strictly forbidden.
Trademarks used in this text: Dell, the DELL logo, and PowerVault are trademarks of Dell Inc.; EMC and PowerPath are registered trademarks
of EMC Corporation.
Other trademarks and trade names may be used in this document to refer to either the entities claiming the marks and names or their products.
Dell Inc. disclaims any proprietary interest in trademarks and trade names other than its own.
June 2005
Contents 3
Contents
Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
General Host Backup Considerations
. . . . . . . . . . . . . . . . . . . . . . . 5
Tape Drive and Data Considerations
. . . . . . . . . . . . . . . . . . . . . 5
Hard Drive and RAID Array Configuration
. . . . . . . . . . . . . . . . . . 6
General Performance Considerations When Using Multiple Drives
in Tape Libraries
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
SCSI Configurations
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
SAN Configurations
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
4 Contents
Performance Considerations for Tape Drives and Libraries 5
Introduction
W
ith recent improvements in tape drive transfer rates,
many host-side factors, such as RAID
(Redundant Array of Inexpensive [or Independent] Disks) configuration and hard-drive
specifications, must be considered when determining whether the host server and tape drive can
process data at the same rate. General configurations and attributes that may limit throughput
from the host server to the tape drive are discussed in "General Host Backup Considerations."
As multiple drives are placed into tape libraries, greater host bandwidths are needed to keep pace
with the potential throughput of multiple tape drives. Potential fibre limitations for multidrive
units, as well as recommended cabling configurations, are discussed in "General Performance
Considerations When Using Multiple Drives in Tape Libraries."
General Host Backup Considerations
The considerations in this section apply to both SCSI and storage area network (SAN) tape backup
configurations.
Tape Drive and Data Considerations
The following issues should be considered when evaluating performance:
Overhead from SCSI commands.
Command overhead on the SCSI bus restrict
all
SCSI devices
in achieving theoretical maximum transfer speeds. Tape backup software does not account for this
overhead; instead, the software only measures the rate at which data is written to the tape. For
example, the drive may be processing 80 MB/sec of data, but only writing 77 MB/sec of data.
The latter rate is what the backup software will report.
Tape block sizes.
64 Kb block sizes are optimal for most tape drives. However, some backup
applications allow the user to change block size, even though a larger size will not enhance
performance. Using block sizes less than 64 Kb can actually hinder performance. See your backup
software User's Guide for information on adjusting the block size of your tape device.
Backup software buffer size.
For optimal backup performance, backup software buffers should be
as large as possible. Some applications allow users to change the buffer size, which can help
maintain a steady stream of data to and from the drive and significantly increase transfer rates,
especially of small files. The larger the buffer, the more data it can hold and the less time the disk
spends seeking the data; however, this can affect memory and CPU performance. See your tape
backup application User’s Guide for specific details.
Drivers and firmware.
Always ensure that the SCSI or fibre controller and tape drive have the latest
drivers and firmware installed. Visit
support.dell.com
to download the latest drivers and firmware
for your Dell PowerVault tape product.
6 Performance Considerations for Tape Drives and Libraries
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Attach tape drives and hard drives on separate controllers (internal or external) on separate host
bus adapters (HBAs).
This depends somewhat on the performance capabilities of your controller,
but best practice is to keep the tape drive HBA separate from the hard drive HBA to ensure
maximum throughput. Most onboard dual-mode SCSI/RAID controllers share one processor,
which must share bandwidth between the RAID array and tape drive. Thus, one controller is
handling reads and writes between the hard disks and the tape drive, as well as calculating and
writing any necessary parity information to the hard drives. See "Hardware RAID Configuration
Considerations" for specific information on RAID arrays and parity bytes.
Dirty drive heads or old media.
A dirty tape drive head or old media can cause high error rates and
a corresponding reduction in read/write speeds. Each time a drive attempts to rewrite or reread a
block on a tape, performance is degraded. Once a certain threshold of read/write errors is reached,
the drive will usually request cleaning. It is important to clean the drive heads on regular intervals,
or when requested.
The chance of encountering a bad block increases as media ages or is excessively used. The typical
lifecycle of a piece of LTO media is approximately 75 full tape read/writes.
Speed matching.
Newer LTO drives will match the speed of the data being provided to the drive,
down to approximately one-half of the maximum uncompressed data transfer speed. If data is
provided to the drive at less than the lower speed matching limit, the drive must stop, wait for the
buffer to fill, rewind, and then attempt to write the buffer (this is known as "back hitching").
For example, the Dell PowerVault 110T (LTO2 and LTO3) tape drive matches speed down to
30 MB/sec while writing to LTO-3 media. If the host server can only provide data at 20 MB/sec, the
drive will "back hitch" while waiting for its buffers to fill. In this situation, the effective throughput
will be something less than 20 MB/sec (probably closer to 15 MB/sec).
Confirming Performance of Your Tape Drive
Certain tape drive manufacturers have a performance diagnostic mode built into the drive that can
be used to confirm throughput. The PowerVault 110T LTO-2 and LTO-3 (firmware 53
XX
or later)
offer a diagnostic mode "F," which performs a quick read/write performance test on the drive and
media. If the performance rate is not within 6 percent of the maximum specified drive speed, the
test fails with an error message. No error message is displayed if the test passes. Consult your tape
drive User’s Manual for specific details on diagnostic mode "F."
NOTICE: Diagnostic mode "F" requires media that can be safely overwritten as part of the diagnostic test.
Do not use media containing critical data. Any data residing on the media used in the diagnostic test will
be lost.
Hard Drive and RAID Array Configuration
Several hard drive and disk array (both internal and external) attributes can affect backup or restore
performance. These attributes, as well as recommended configurations that help achieve
maximum backup and restore speeds, are discussed in the following subsections. If the tape drive’s
sustainable throughput exceeds that of the disk array, then the tape drive’s peak performance will
not be realized.
Performance Considerations for Tape Drives and Libraries 7
General Hard Drive Configuration Considerations
Data/operating system (OS) on different LUNs.
Backing up data on a logical unit number (LUN)
separate from the OS LUN ensures that the hard drive is not splitting access and overhead between
OS operations and backup operations. This can be accomplished by having one hard drive or disk
array contain the OS and a physically separate hard drive or disk array contain the data
to be backed up.
Figure 1-1. Single-Channel vs. Two-Channel Bandwidth
Hard Drive Performance
By design, tape drives write data sequentially and require a constant data feed to keep the drive
operating sequentially (avoiding back hitching). Conversely, hard drives are random access devices.
Therefore, hard drives can sometimes struggle to provide sequential data to tape drives if that data
is spread out over the drive platter. This forces the drive to continuously seek small blocks of data.
Additionally, other hard drive attributes can further affect the throughput of data to the tape drive.
Spindle speed.
Typically measured in RPMs (revolutions per minute), the hard drive's spindle
speed determines how many times per minute the drive platter assembly can perform a full
revolution. This has a direct effect on both random access times and sequential transfer rates.
The higher the spindle speed, the faster the drive can access data.
Single Shared LUN Separate LUNs
Single LUN with
Backup data
and OS
OS LUN
SCSI or RAID
Controller
Tape Drive
Backup Data
LUN
SCSI or RAID
Controller
Tape Drive
8 Performance Considerations for Tape Drives and Libraries
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Random access time or seek time.
Usually measured in milliseconds, seek time is the length of
time a drive's heads take to find a piece of data on the disk. The seek time of a hard disk measures
the amount of time required for the read/write heads to move between tracks on the surface of the
platters. Because hard disks are random access devices, data can be stored on virtually any sector of
the disk. The longer it takes to access that data, the slower the overall throughput of the drive. This
attribute is very significant when a hard drive contains many small files. The smaller the files, the
more "seeks" the drive must make to read or write the file to disk; therefore, disks tend to read or
write very slowly when many small files are being transferred.
Sequential/sustained transfer rates (STR).
STR measures how fast a drive actually reads data from
and writes data to its platters. If the data being backed up is one large contiguous file, the sustained
throughput will be close to the drive's maximum STR. However, in real-world applications, data
becomes more scattered about the platter as data is deleted and written. Defragmenting a hard
drive can help the drive reach its maximum STR.
Buffer (cache).
The buffer is the amount of memory on the drive that holds the most recently
written or stored data. The bigger the buffer, the more data it can hold, resulting in less time
seeking data on the disk.
Hardware RAID Configuration Considerations
General overview of RAID
This section presents an overview of typical RAID configurations and how they affect backup and
restore rates. A RAID array is a set of hard disks that act as a single storage system or LUN. Data can
be potentially transferred through the channel of each hard drive at once, allowing for total
throughput to be a multiple of the total number of drives in the array, minus overhead and any
redundancy as described in the following sections.
In the case of a RAID configuration, the speed of the interface becomes important because the
drives share the bandwidth of the interface. For example, a single Ultra160 drive may only sustain
40 MB/sec. Thus, a five-disk RAID 0 array consisting of the same drive type should be able to
read/write at 200 MB/sec. However, the Ultra160 interface will limit the array to a maximum of
160 MB/sec.
External disk arrays, particularly in SANs, may offer significant levels of cache memory to improve
I/O performance. This cache will greatly improve performance when writing to the array and may
store frequently accessed data to improve read performance. With respect to its impact on tape
performance, the cache will mask most RAID limitations when restoring data to the array or
backing up data from the array. However, backup operations from external arrays with cache may
still feel the impact of RAID configuration limitations because the data still needs to be read from
the disks.
Performance Considerations for Tape Drives and Libraries 9
RAID 0
Commonly known as striping, RAID 0 allows two or more disks to be joined to create one virtual
drive in the fashion of a single LUN. It is referred to as striping because data is written across all of
the disks in the array, not just to one disk at a time. Thus, the throughput is spread across
n
channels (
n
being the number of hard drives in the array) instead of a single channel for a single
hard disk. This results in excellent read/write performance, but no fault tolerance.
Figure 1-2 shows four hard drives in a RAID 0 configuration. Data is striped across all four hard
drives, resulting in four channels for reading and writing to the array.
Figure 1-2. Example RAID 0 Configuration
SCSI or RAID
Controller
Tape Drive
D1
D5
D9
D13
D17
D2
D6
D10
D14
D18
D3
D7
D11
D15
D19
D4
D8
D12
D16
D20
Hard Drive 1 Hard Drive 2 Hard Drive 3 Hard Drive 4
D = Data Byte
10 Performance Considerations for Tape Drives and Libraries
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RAID 1
Also known as mirroring, RAID 1 means data is written twice across two disks simultaneously. If
one drive fails, the system switches to the other drive without losing data. During tape drive
backups, the read rate from the RAID 1 array is approximately the same as a single drive because it
is reading from the primary drive. However, restore performance from the tape drive writing to the
RAID 1 array can be slower due to error checking/correction (ECC) included in writing to the
primary and mirrored disks. Much of this inefficiency is due to the fact that the mirroring is often
performed on the CPU or RAID controller. Thus, newer RAID controllers tend to be faster due to
newer and more capable processors.
Figure 1-3. Example RAID 1 Configuration
D1
D2
D3
D4
D5
M1
M2
M3
M4
M5
Tape Drive
SCSI or RAID
Controller
Write OnlyRead/Write
Read/Write
Hard Drive 1 Hard Drive 2
D = Data Byte
M = Mirrored Byte
Performance Considerations for Tape Drives and Libraries 11
RAID 5
With a RAID 5 array, data is striped across the disk array at the byte level and error correction data,
or parity data, is also striped across the disk array. RAID 5 arrays tend to have very good random
read performance; this read performance generally improves as the number of disks in the array
increases. With the larger disk arrays, read performance can actually outperform RAID 0 arrays
because the data is distributed over an additional drive. In additional, parity information is not
required during normal reads.
Restores from tape to a RAID 5 array tend to be nominal because it involves additional overhead
for calculating and writing the parity information.
Figure 1-4. Example RAID 5 Configuration
P1
D4
D7
D10
D13
D1
P2
D8
D11
D14
D2
D5
P3
D12
D15
D3
D6
D9
P4
D16
SCSI or RAID
Controller
Tape Drive
Read/Write
Read/Write
D = Data Byte
Hard Drive 1 Hard Drive 2 Hard Drive 3 Hard Drive 4
P = Parity Byte
12 Performance Considerations for Tape Drives and Libraries
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In conclusion, RAID 0 tends to be the best overall configuration for read and write performance,
but does not allow for redundancy. RAID 1 is the worst performer overall, as all data written to
the array is mirrored and reads come from a single disk. RAID 5 tends to be a good read performer
but average write performer; however, RAID 5 improves if more disks are added to the array. If
the RAID is within an enclosure that offers significant levels of cache memory, then performance
limitations during restore operations may be abated. Backup operations will still be subject to
limitations of the RAID configuration.
In addition, the characteristics of the array still depend
heavily on the specific hard drive characteristics listed in "Hard Drive Performance."
General Performance Considerations When Using Multiple
Drives in Tape Libraries
When multiple tape drives are utilized simultaneously to perform data backups (such as in tape
libraries), additional aspects of the hardware configuration must be considered. By employing
simple performance-minded methods in setting up hardware and cabling configurations, additional
throughput bottlenecks can be limited.
SCSI Configurations
The latest high-performance tape drives offered in tape libraries support the Ultra160 specification
of the SCSI interface standard. Therefore, to achieve maximum performance, backup servers
utilizing SCSI must have an HBA installed that supports data speeds of Ultra160 or higher. A SCSI
HBA that meets this requirement will allow each tape drive to communicate with the host at a rate
of 160 MB/sec on the SCSI bus. The higher data rate of the SCSI bus compared to tape drive
speeds allows multiple devices to be connected to the same bus without sacrificing device
performance. But only to a point.
The 160 MB/sec data rate of an Ultra160 bus is the maximum possible data throughput rate to all
devices connected to the bus. Therefore, a single tape drive will not consume the full bandwidth of
the bus because it can read or write data to tape at up to 80 MB/sec (native). Multiple tape drives,
however, can combine to consume the full 160 MB/sec offered by the bus if each is operating at its
maximum native performance. Each additional drive connected to the same bus after this point
will reduce the average performance of each drive.
Therefore, to achieve maximum performance from a tape library, it is recommended to connect
no more than two tape drives to each SCSI bus. See "Recommended Cabling Configurations" for
specific details and illustrations. A SCSI HBA supporting at least Ultra160 should be used, but
upgrading to an Ultra320 HBA will not lead to an additional improvement in performance if the
tape drive's specification is Ultra160.
Performance Considerations for Tape Drives and Libraries 13
SAN Configurations
Fibre Channel (FC) offers many advantages over SCSI. First, it overcomes the distance limitations
of SCSI (12 meters for LVD SCSI versus 300 meters for a short-wave 2-Gb FC link)
and allows for
the transmission of data at higher speeds. As a serial network protocol rather than a bus-based
architecture like SCSI, FC has also become the protocol of choice for the implementation of SANs,
allowing for the consolidation of data storage resources. In addition, each FC connection is made
up of a transmit link and a receive link, allowing for full-duplex operation. This means that data can
be transmitted in two directions simultaneously. Therefore, during a backup operation across a
single FC connection, data can be read from a source and written to tape without taking turns in
communication, effectively doubling the bandwidth of a connection. See Figure 1-5.
Figure 1-5. Fibre Channel Link Diagram
When setting up tape libraries in a SAN, performance can still be affected by various factors. These
factors include FC link speeds, data flow between the source and tape library, and performance
limitations of external storage arrays. With an understanding of the overall setup and management
of the solution, many of these factors can be avoided.
Even with the high data bandwidth offered by the FC protocol in SANs, proper considerations
must be made for tape drives in order to avoid a situation in which the FC link may limit
performance. The data rate of a 2-gigabit (Gb) FC link is 200 MB/sec (that is, 200 MB/sec on the
transmit link and 200 MB/sec on the receive link). Therefore, attempting to operate multiple tape
drives across the same link can potentially exceed the full bandwidth of a link. If the host is
operating with a legacy 1-Gb adapter, backing up data to two drives may be sufficient to reveal
significant performance limitations.
Therefore, when using three or more tape drives simultaneously on a 2-Gb link, you may need to
distribute the backups across a number of connections, rather than relying on a single link. This is
where understanding the SAN solution's topology is beneficial. Following the data path during a
backup operation as it is read from the source and then written out to tape will help administrators
recognize any potential bottlenecks. If any bottlenecks are identified, measures may be taken
depending on the configuration. For example, if the backup solution requires multiple drives to be
in operation at once, splitting the tape hardware across separate fabrics may improve performance
by splitting the connections. See Figure 1-6.
HOST
Fibre
Channel
Device
Transmit
Receive
Receive
Transmit
2 Gb = 200 MB/sec
2 Gb = 200 MB/sec
14 Performance Considerations for Tape Drives and Libraries
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Figure 1-6. Single vs. Split Data Flow to Tape Library
At the same time, if a bottleneck exists in the data being read from an external FC disk array, the
use of I/O management software such as EMC
®
PowerPath
®
with an additional fabric connection
will automatically load-balance the data across multiple paths and increase availability through
path failover. See Figure 1-7. The left side of the figure represents a SAN disk array in which all of
the data is forced through a single link, creating a bottleneck that slows data flow to the tape
hardware. The right side shows how load balancing doubles the I/O bandwidth coming out of the
array by allowing the data to transmit across two links.
HOST
Fibre Channel
Switch
Fibre Channel
Disk Array
Fibre Channel
Switch
Fibre Channel
Switch
HOST
Fibre Channel
Disk Array
Tape Library Tape Library
Performance Considerations for Tape Drives and Libraries 15
Figure 1-7. Bottlenecked Data Flow vs. Load-Balanced Disk Array
Finally, FC disk arrays on the SAN can also experience the same performance limiters described in
"Hard Drive and RAID Array Configuration." Therefore, improving the performance characteristics
of the disk arrays will also have a direct effect on backup speed across the SAN.
SAN Configurations Utilizing the Library Fibre Channel Bridge
Certain tape libraries may be connected to a SAN by way of a Fibre Channel bridge module. The
module acts as a bridge between the SCSI and FC protocols and provides additional management,
security, and operational features unavailable in most native FC libraries. For details on these
features, see the Fibre Channel bridge User's Guide for your tape library.
In some tape library configurations, the Fibre Channel bridge module may act as a bottleneck and
decrease performance of tape drives. This is because the processing capability in the Fibre Channel
bridge module required to bridge the SCSI and FC communication cannot meet the aggregate
data throughput offered by certain multidrive configurations. Despite this, most data backup
solutions will not experience the Fibre Channel bridge module as the primary limiting factor in
tape performance. Dedicated backup servers will frequently encounter a situation where the
limitations at the host will be compounded by the exertion of feeding data to multiple tape drives.
This results in average drive performance below the level where the Fibre Channel bridge module
becomes a factor.
Fibre Channel
Switch
Fibre Channel
Switch
HOST
HOST
Fibre Channel
Switch
Fibre Channel
Switch
Fibre Channel
Disk Array
Fibre Channel
Disk Array
Tape Library Tape Library
16 Performance Considerations for Tape Drives and Libraries
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Recommended Cabling Configurations
SCSI Cabling to the Host
Tape Library With up to Six Tape Drives
When the tape library is SCSI-attached to a host, ensure that no more than two drives are on a
single bus. Additional SCSI controllers are required for libraries with five or six tape drives to
ensure that no SCSI bus becomes a barrier to maximizing throughput.
Figure 1-8. SCSI Cabling for Library With up to Six Tape Drives
Tape Library With up to Two Tape Drives
The drives in a fully configured two-drive tape library can be cabled to a host on the same SCSI bus
without encountering significant limitations to backup performance. The backup rates for two
drives on a single SCSI bus will match the backup rates for two drives on separate buses. However,
customers who enable the verify feature in backup applications may wish to improve the verify
performance by splitting two drives onto two SCSI buses. By doing so, verify performance may
improve by up to 25 percent.
library-to-host
SCSI cable
library-to-host
SCSI cable
drive-to-library
controller SCSI
cable
terminator
terminator
Performance Considerations for Tape Drives and Libraries 17
Figure 1-9. SCSI Cabling for Library With up to Two Tape Drives
Cabling Drives to the Fibre Channel Bridge
Figures 1-10 through 1-17 illustrate how a tape library with up to six drives should be configured
with a Fibre Channel bridge module in order to optimize tape performance over FC.
terminator
18 Performance Considerations for Tape Drives and Libraries
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Figure 1-10. Fibre Channel Bridge Cabling With One Tape Drive
library SCSI
interface
SCSI 1
terminator
drive 1
Performance Considerations for Tape Drives and Libraries 19
Figure 1-11. Fibre Channel Bridge Cabling With Two Tape Drives
library SCSI
interface
SCSI 1
SCSI 2
terminator
terminator
drive 1
drive 2
20 Performance Considerations for Tape Drives and Libraries
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Figure 1-12. Fibre Channel Bridge Cabling With Three Tape Drives
library SCSI
interface
SCSI 1
SCSI 2
terminator
terminator
drive 1
drive 2
drive 3
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Dell PowerVault 110T LTO2 (Tape Drive) spécification

Taper
spécification