XS Server Hardware: Difference between revisions

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This is a description of the first dedicated hardware implementation of the [[School server]].
This is a description of the first dedicated hardware implementation of the [[School server]].
An overview of the services provided by the [[School server]] is provided by the [[XS_Server_Services|Server Services]] document, with an accompanying [[XS_Server_Discussion|discussion of desired services]]. Also available is a [[XS_Server_Software|description of the first software implementation]].
An overview of the services provided by the [[School server]] is provided by the [[XS_Server_Services|Server Services]] document, with an accompanying [[XS_Server_Discussion|discussion of desired services]]. Also available is a [[XS_Server_Software|description of the first software implementation]].

=Introduction=


Unlike the current laptop, there will be a number of [[School server]] hardware platforms. OLPC, in order to support the deployment of laptops, especially in environmentally hostile or off-the-grid locations, is designing a reference platform in collaboration with our manufacturing partner, Quanta. We are also supporting efforts by candidate countries (such as Brazil) to manufacture a school server platform locally.
Unlike the current laptop, there will be a number of [[School server]] hardware platforms. OLPC, in order to support the deployment of laptops, especially in environmentally hostile or off-the-grid locations, is designing a reference platform in collaboration with our manufacturing partner, Quanta. We are also supporting efforts by candidate countries (such as Brazil) to manufacture a school server platform locally.
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* XS - An environmentally rugged, very low power school server for up to 150 students. Should be available in November.
* XS - An environmentally rugged, very low power school server for up to 150 students. Should be available in November.


==XS Specifications==
=XS Specifications=


This is a [[School server]] hardware platform designed with low power consumption and operation in environmentally challenging conditions as goals.
This is a [[School server]] hardware platform designed with low power consumption and operation in environmentally challenging conditions as goals.


===Processor===
==Processor==


This hardware platform may be based on any processor architecture supported by the mainstream Linux kernel and libc software trees. We encourage the use of processors supported by Fedora Core 7.
This hardware platform may be based on any processor architecture supported by the mainstream Linux kernel and libc software trees. We encourage the use of processors supported by Fedora Core 7.
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For the XS Server, the processor is a PowerPC, the MPC7447A from Freescale, with AltiVec support. Apple calls it a G4.
For the XS Server, the processor is a PowerPC, the MPC7447A from Freescale, with AltiVec support. Apple calls it a G4.


===Network Interfaces===
==Network Interfaces==
The following are the integrated networking interfaces on XS. Additional interfaces may be added to the system using the [[#Peripheral_Interfaces|peripheral interfaces]].
The following are the integrated networking interfaces on XS. Additional interfaces may be added to the system using the [[#Peripheral_Interfaces|peripheral interfaces]].


====Wireless Mesh====
===Wireless Mesh===
The School server will have two or three [[Active Antenna]], an 802.11b/g [http://en.wikipedia.org/wiki/Wi-Fi WiFi] wireless mesh networking interface. Each one of these serves as a mesh portal point operating on one of the three non-overlapping 802.11b channels (1, 6, and 11).
The School server will have two or three [[Active Antenna]], an 802.11b/g [http://en.wikipedia.org/wiki/Wi-Fi WiFi] wireless mesh networking interface. Each one of these serves as a mesh portal point operating on one of the three non-overlapping 802.11b channels (1, 6, and 11).


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These are not integrated physically into the XS school server. This allows them to be located optimally for RF transmission/reception, while the server is in a more accessible location. It also allows for greater separation of the three antennas, operating simultaneously at neighboring frequencies.
These are not integrated physically into the XS school server. This allows them to be located optimally for RF transmission/reception, while the server is in a more accessible location. It also allows for greater separation of the three antennas, operating simultaneously at neighboring frequencies.


====Wired Networking====
===Wired Networking===
Providing at least two [http://en.wikipedia.org/wiki/100baseT wired ethernet] interfaces allows for reliable, high-bandwidth connection between a [[school server]] and its internet connection (if through a [http://en.wikipedia.org/wiki/DSL DSL] or [http://en.wikipedia.org/wiki/Satellite_modem satellite modem]), other school servers, and any non-laptop computer equipment.
Providing at least two [http://en.wikipedia.org/wiki/100baseT wired ethernet] interfaces allows for reliable, high-bandwidth connection between a [[school server]] and its internet connection (if through a [http://en.wikipedia.org/wiki/DSL DSL] or [http://en.wikipedia.org/wiki/Satellite_modem satellite modem]), other school servers, and any non-laptop computer equipment.


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Each port will be provided with two LEDs indicating link status, simplifying network debugging.
Each port will be provided with two LEDs indicating link status, simplifying network debugging.


===Peripheral Interfaces===
==Peripheral Interfaces==
The following peripheral interfaces are provided for expanding the capabilities of the school server.
The following peripheral interfaces are provided for expanding the capabilities of the school server.


====USB 2.0====
===USB 2.0===
At least six [http://en.wikipedia.org/wiki/USB Universal Serial Bus] (USB) 2.0 interfaces should be provided for extending the storage and communication capabilities of a [[School server]].
At least six [http://en.wikipedia.org/wiki/USB Universal Serial Bus] (USB) 2.0 interfaces should be provided for extending the storage and communication capabilities of a [[School server]].


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The total amount of power consumed by the USB devices will be clamped to 2.5 A at 5 Volts (12.5 W) total, aggregrated across all devices. Any single device may pull up to 1.5 A (7.5 W).
The total amount of power consumed by the USB devices will be clamped to 2.5 A at 5 Volts (12.5 W) total, aggregrated across all devices. Any single device may pull up to 1.5 A (7.5 W).


====PCI-Express Slot====
===PCI-Express Slot===
A short, full height PCI-Express (4 channel) expansion slot is provided internally in the XS. This slot is intended for the addition of a DVB-S receiver and demodulator, but may be used for other purposes as well.
A short, full height PCI-Express (4 channel) expansion slot is provided internally in the XS. This slot is intended for the addition of a DVB-S receiver and demodulator, but may be used for other purposes as well.


The power consumption of this expansion slot limited to 15 W. Exceeding this will lower the maximum ambient operating temperature of the server, and may also prevent the use of a second disk drive.
The power consumption of this expansion slot limited to 15 W. Exceeding this will lower the maximum ambient operating temperature of the server, and may also prevent the use of a second disk drive.


===Non-Volatile Storage===
==Non-Volatile Storage==


====Internal Disk Drive====
===Internal Disk Drive===
One internal 3.5 in. disk drive will be provided. The disk interface will be SATA (version 1 or 2). The capacity of this disk drive WILL vary, with a minimum size of 300 GB at this time.
One internal 3.5 in. disk drive will be provided. The disk interface will be SATA (version 1 or 2). The capacity of this disk drive WILL vary, with a minimum size of 300 GB at this time.


A second 3.5 in. disk drive will be supported in the XS, primarily for onsite drive replacement, but also allowing storage expansion. Use of a second disk drive will lower the maximum ambient operating temperature of the server.
A second 3.5 in. disk drive will be supported in the XS, primarily for onsite drive replacement, but also allowing storage expansion. Use of a second disk drive will significantly increase the power consumption of the server.


====External Disk Drives====
===External Disk Drives===


Additional disks may be added using the external USB 2.0 ports.
Additional disks may be added using the external USB 2.0 ports.


====Flash====
===Flash===


A fair amount (512 MB) of NAND Flash (solid state non-volatile) memory is provided on the server to allow the operating system and minimal services to continue operation even though the primary disk drive has failed.
A fair amount (512 MB) of NAND Flash (solid state non-volatile) memory is provided on the server to allow the operating system and minimal services to continue operation even though the primary disk drive has failed.
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A smaller amount (512KB) of NOR Flash will be provided for storage of configuration information and boot firmware.
A smaller amount (512KB) of NOR Flash will be provided for storage of configuration information and boot firmware.


===Power===
==Power==


The power specifications of the [[School server]] are important. Many schools do not have adequate, or regular, power. While the power consumption should be minimized (30W is a good
The power specifications of the [[School server]] are important. Many schools do not have adequate, or regular, power. While the power consumption should be minimized (30W is a good
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Possible methods of obtaining power are summarized in [[Battery_and_power]].
Possible methods of obtaining power are summarized in [[Battery_and_power]].


===Environmental===
==Environmental==


====Temperature====
===Temperature===
The [[school server]] should meet the same environmental specifications for temperature as the laptop. This is 50 C ambient.
The [[school server]] should meet the same environmental specifications for temperature as the laptop. This is 50 C ambient.


====Water, Dust, and Salt Fog====
===Water, Dust, and Salt Fog===


The server should be resistant to water spray from all directions, but does not have to survive immersion. It should be capable of long-term operation in a constantly humid (100%) environment, with salt fog and dust.
The server should be resistant to water spray from all directions, but does not have to survive immersion. It should be capable of long-term operation in a constantly humid (100%) environment, with salt fog and dust.
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Connectors and buttons should be resistant to water and dust intrusion. Buttons should be sealed against water, and connectors located and cables dressed to prevent water intrusion.
Connectors and buttons should be resistant to water and dust intrusion. Buttons should be sealed against water, and connectors located and cables dressed to prevent water intrusion.


====Mounting====
===Mounting===


While the school server should be designed to sit on a flat surface, it should probably
While the school server should be designed to sit on a flat surface, it should probably
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This shouldn't cause a problem unless the server includes batteries for a optional/modular UPS...
This shouldn't cause a problem unless the server includes batteries for a optional/modular UPS...


====Drop and Shake====
===Drop and Shake===


The [[school server]] should meet higher drop and shake specifications than standard consumer
The [[school server]] should meet higher drop and shake specifications than standard consumer
desktop PCs, to account for rough transport in the delivery.
desktop PCs, to account for rough transport in the delivery.


==XSX Specifications==
=XSX Specifications=


This is a version with a target date of mid-March. The primary goal is to support development of the School server/laptop software, including early trials. As this is a very limited production model (12-40 ?) and the design criteria are still undefined, flexibility wins out over cost. Off-the-shelf consumer PC hardware is being used for this platform. See the [[XSX Server Implementation]] for details.
This is a version with a target date of mid-March. The primary goal is to support development of the School server/laptop software, including early trials. As this is a very limited production model (12-40 ?) and the design criteria are still undefined, flexibility wins out over cost. Off-the-shelf consumer PC hardware is being used for this platform. See the [[XSX Server Implementation]] for details.

Revision as of 04:06, 25 August 2007

  This page is monitored by the OLPC team.

This is a description of the first dedicated hardware implementation of the School server. An overview of the services provided by the School server is provided by the Server Services document, with an accompanying discussion of desired services. Also available is a description of the first software implementation.

Introduction

Unlike the current laptop, there will be a number of School server hardware platforms. OLPC, in order to support the deployment of laptops, especially in environmentally hostile or off-the-grid locations, is designing a reference platform in collaboration with our manufacturing partner, Quanta. We are also supporting efforts by candidate countries (such as Brazil) to manufacture a school server platform locally.

Current platforms include:

  • XSX - A short-term prototype, available now using OTS parts
  • An XO laptop - Equipped with an external disk drive, a laptop should be capable of performing as a school server for small (less than thirty laptop) schools.
  • XS - An environmentally rugged, very low power school server for up to 150 students. Should be available in November.

XS Specifications

This is a School server hardware platform designed with low power consumption and operation in environmentally challenging conditions as goals.

Processor

This hardware platform may be based on any processor architecture supported by the mainstream Linux kernel and libc software trees. We encourage the use of processors supported by Fedora Core 7.

Processor performance is difficult to characterize with a single number. We are looking for between 1200 and 1600 MIPs, capable of 120K+ interrupts/sec, with at least 1 GB/sec of memory throughput. At least 256KB of L2 cache should be provided.

For the XS Server, the processor is a PowerPC, the MPC7447A from Freescale, with AltiVec support. Apple calls it a G4.

Network Interfaces

The following are the integrated networking interfaces on XS. Additional interfaces may be added to the system using the peripheral interfaces.

Wireless Mesh

The School server will have two or three Active Antenna, an 802.11b/g WiFi wireless mesh networking interface. Each one of these serves as a mesh portal point operating on one of the three non-overlapping 802.11b channels (1, 6, and 11).

While connected to the school servers using detachable five meter USB cables, the Active Antennas are considered integrated as there must always be at least one of these connected for proper server operation. In the future, higher numbers (four or five) of more advanced (directional) Active Antennas may be used.

These are not integrated physically into the XS school server. This allows them to be located optimally for RF transmission/reception, while the server is in a more accessible location. It also allows for greater separation of the three antennas, operating simultaneously at neighboring frequencies.

Wired Networking

Providing at least two wired ethernet interfaces allows for reliable, high-bandwidth connection between a school server and its internet connection (if through a DSL or satellite modem), other school servers, and any non-laptop computer equipment.

The current plan for XS is to provide two 1000baseT ports and four 100baseT ports on the server. The two high speed ports allow multiple servers in a school to form a high speed backbone, and the four additional ports on each server provide school network expansion without using external switches. External switches are not encouraged, due to unknown quality and the requirement of external power.

Each port will be provided with two LEDs indicating link status, simplifying network debugging.

Peripheral Interfaces

The following peripheral interfaces are provided for expanding the capabilities of the school server.

USB 2.0

At least six Universal Serial Bus (USB) 2.0 interfaces should be provided for extending the storage and communication capabilities of a School server.

This assumes that up to three external ports will be used for Active Antenna, another for an external CD/DVD RW, another for a possible WAN connection, and one last one for temporary USB key or external USB drive attachment.

The total amount of power consumed by the USB devices will be clamped to 2.5 A at 5 Volts (12.5 W) total, aggregrated across all devices. Any single device may pull up to 1.5 A (7.5 W).

PCI-Express Slot

A short, full height PCI-Express (4 channel) expansion slot is provided internally in the XS. This slot is intended for the addition of a DVB-S receiver and demodulator, but may be used for other purposes as well.

The power consumption of this expansion slot limited to 15 W. Exceeding this will lower the maximum ambient operating temperature of the server, and may also prevent the use of a second disk drive.

Non-Volatile Storage

Internal Disk Drive

One internal 3.5 in. disk drive will be provided. The disk interface will be SATA (version 1 or 2). The capacity of this disk drive WILL vary, with a minimum size of 300 GB at this time.

A second 3.5 in. disk drive will be supported in the XS, primarily for onsite drive replacement, but also allowing storage expansion. Use of a second disk drive will significantly increase the power consumption of the server.

External Disk Drives

Additional disks may be added using the external USB 2.0 ports.

Flash

A fair amount (512 MB) of NAND Flash (solid state non-volatile) memory is provided on the server to allow the operating system and minimal services to continue operation even though the primary disk drive has failed.

A smaller amount (512KB) of NOR Flash will be provided for storage of configuration information and boot firmware.

Power

The power specifications of the School server are important. Many schools do not have adequate, or regular, power. While the power consumption should be minimized (30W is a good target), consideration should be given to an integral (or optional modular) uninterruptible power supply (UPS). This is nothing more than a larger version of the laptop power supply!

In some test schools with minimal power, we are already deploying multiple (gang) battery chargers with integral UPS.

Possible methods of obtaining power are summarized in Battery_and_power.

Environmental

Temperature

The school server should meet the same environmental specifications for temperature as the laptop. This is 50 C ambient.

Water, Dust, and Salt Fog

The server should be resistant to water spray from all directions, but does not have to survive immersion. It should be capable of long-term operation in a constantly humid (100%) environment, with salt fog and dust.

While the server will contain fans, they will externally accessible for easy replacement and under software control to conserve power.

Connectors and buttons should be resistant to water and dust intrusion. Buttons should be sealed against water, and connectors located and cables dressed to prevent water intrusion.

Mounting

While the school server should be designed to sit on a flat surface, it should probably also be mountable (hangable) from a wall or post.

This shouldn't cause a problem unless the server includes batteries for a optional/modular UPS...

Drop and Shake

The school server should meet higher drop and shake specifications than standard consumer desktop PCs, to account for rough transport in the delivery.

XSX Specifications

This is a version with a target date of mid-March. The primary goal is to support development of the School server/laptop software, including early trials. As this is a very limited production model (12-40 ?) and the design criteria are still undefined, flexibility wins out over cost. Off-the-shelf consumer PC hardware is being used for this platform. See the XSX Server Implementation for details.

Selection criteria are:

  • 1GHz+ x86 processor
  • 1 GB main memory
  • four to six USB interfaces, with power for three Marvell Wifi nodes and an external disk drive.
  • one 300GB+ 3.5in SATA drive
  • power and space for a second disk drive
  • two 100baseT network interfaces
  • minimal fans

There are no power consumption targets for this device. A separate UPS is suggested for trial deployments in areas of uncertain power.