This Hardware/OS/DBMS Design Document (HDD) for the WFCAM Science Archive (WSA) gives an overview of the hardware for data storage as well as for the data servers used for the WSA at the archive centre (WFAU at the IfA, Edinburgh). The reason for considering hardware, OS, and DBMS together is that the three are intimately linked; optimal DBMS operation is not always possible for a given hardware and OS configuration. Since copying the data from the data processing centre (CASU at the IoA, Cambridge) to WFAU plays a significant role, networking is also considered.
This HDD is intended to be a reference to software engineers and scientists working on the WSA project. A primary goal of the document is to specify the first phase WSA hardware in enough detail to enable orders to be placed with vendors to acquire the necessary equipment. This document will also discuss how we plan to move from V1.0 through the first year of data ingest to the V2.0 system.
In our developments for the WSA so far, we have had to deal with some tensions. The need for timely development work (eg. hands-on experience) has to be balanced against the general best practice of delaying hardware purchases as long as possible (eg. Moore's law). Further, the timescale for significant developments in computer hardware technology implies that over the WSA lifetime the archive hardware solution is likely to change and a migration from one system to another will almost certainly be needed (this is even more so for the overall VDFS). Hardware configuration has many complicated variables, and it is only via experimentation that most questions can be answered.
Fortunately, hardware manufacturers (eg. Sun MicroSystems, IBM, Compusys) are open to donation of discounts, money and/or hardware for what they see as big projects in R&D. Furthermore, many hardware suppliers are open to loan of high-specification kit, meaning that experimentation is possible with no outlay on hardware. The commercial hardware/software big players (ie. MicroSoft/SQLServer, IBM/DB2 and Oracle) are open to supplying expertise and advice to large database developers and, more importantly, to supplying licences that are heavily discounted or even free-of-charge. Finally, many of the hardware issues overlap with similar ones in other IT projects in the UK (eg. initiatives at the Edinburgh National e-Science Centre, within AstroGrid, etc.) and farther afield in Europe (eg. Astronomical Wide-field Imaging System for Europe, ASTRO-WISE ; and the ESO Next Generation Archive Systems Technologies, NGAST ).
In this document the hardware components that will be used to build the WSA are described. In Section 4 we describe the required storage hardware for the pixel data archive and the catalogue data archive, and also describe the servers needed: the load server to efficently upload all the data and the public servers, which will handle the access to the WSA. The backup system is described in Section 6. Finally, Section 7 discusses infrastructure (local area network, equipment accommodation etc).
Applicable documents are listed in Section 10.
The clear requirement to arise out of the SRAD (AD01) is for a phased approach so that a WSA with `standard' functionality is available at first light, enabling immediate science exploitation, and subsequently a fully functioning archive system is made available one year after survey operations begin in earnest. Furthermore, there is a clear split in the requirements for volume and access speed for catalogue and processed pixel data (hereafter, `pixel data' will mean processed pixels; note that there is no requirement on the WSA to store the raw pixel data). The WSA usages require user interaction with catalogue data (ie. complex queries returning results in as close to real time as is feasible) for data mining and data exploration while high volume pixel data usages are less time-critical (users would be prepared to wait for the results of operations on large pixel volumes since these would be executed relatively rarely).
The fundamental requirement on the WSA system hardware concerns the volume of data that will flow into the archive, and the rate at which that data flow occurs. In Appendix 8.1 we give an anlysis of data volumes and rates based around current knowledge and reasonable assumptions.
The outline hardware requirements are therefore as follows:
The phased approach and volume/speed split is reinforced in the light of the hardware considerations stated in the previous Section: we will implement two distinct hardware solutions to satisfy the user requirements. If one subsequently becomes a viable solution for both, but at the same time at reduced cost, then migration from one solution to the other will be straightforward. Furthermore, the phased approach maximises the possibility of exploiting the most recent advances in computer technology since we will not be wedded to one hardware solution from the start and will delay as long as possible each hardware upgrade acquisition.
The baseline requirements for the pixel storage are high capacity and expandability to the tune of 22 Tbytes per year. Low-cost, mass storage of pixel data is a solved problem: the ESO Next Generation Archive Systems Technologies  employs low-cost IDE disks connected to mid-range CPUs to provide multi-Tbyte capacity. We will implement an NGAST-like solution for WSA pixel storage; however we will implement RAID level 5 to include fault tolerance against individual disk failure - NGAST apparently does not currently use RAID. The operating system will be linux and FITS data will be stored as flat files in an observation-date driven directory structure. The FITS data stored will consist of images (and also catalogue FITS binary table files) produced by the CASU processing pipeline - for more details, see the ICD (AD02). The pixel server hardware will consist of a 2.4 Tbyte file server employing a 3Ware Escalade IDE RAID controller and 200 Gbyte IDE disks along with nine further cloned nodes in a rackmount unit yielding Tbytes of storage space after RAID overheads (see Figure 1). This system is modular and will be expanded/upgraded over the next few years of operation.
The V2.0 pixel storage hardware solution will be the same as the V1.0 system. We will add more file servers as and when needed, phasing purchase to maximise the return per unit cost and to take advantage of any new developments in storage technology (eg. we anticipate availability of 300 Gbyte IDE hard disk drives at some point during 2004).
The baseline requirements for the catalogue hardware are:
In the preliminary design phase of the WSA we suggested that the PC farm route may be a good option since as well as achieving high aggregate IO, the system automatically has at its disposal large processing power that may come in useful for advanced applications. However, the disadvantage of the PC farm is in expense and management, and it turns out that a trawl rate of s can be achieved, at least for moderately sized tables, using inexpensive RAID technology, eg. . In this study, by careful design with due regard to disk, disk controller and PCI bus bandwidth limits, aggregate IO rates of well over 300 Mbyte/s were achieved. This study used Ultra160 SCSI controllers along with SCSI disks, and matched the number of disks and their bandwidths to the measured saturation limits of the controllers; note that software striping across the disks was employed. A useful figure to come out of this and other similar studies is that the manufacturer's `burst' transfer specification for any device (eg. 160 Mbyte/s for Ultra160 SCSI controllers) will typically fall by 25% for sustained IO rates. So, for example, Ultra160 controllers are capable of sustaining IO rates of 120 Mbyte/s - hence a maximum of 3 disks, each giving 40 Mbyte/s, were attached to each controller in . The key point to note concerning optimising aggregate IO rates for a hardware system is that the saturation limits of each component in the IO chain - PCI bus, interface connection card, disk controller(s) and disk(s) - must be carefully considered and matched such that no one component limits the potential performance of the rest (the ultimate limit of a single CPU system is the CPU and PCI bus, which can typically shift data at rates of 0.5 to 1.0 Gbyte/s).
The disadvantages of the configuration in  as regards the WSA requirements are, for optimum performance:
Figure 2 shows our catalogue server design for the WSA, where we employ the IO advantages of  but using low cost IDE disks and RAID controllers to achieve the necessary storage capacity, fault tolerance and high aggregate IO, all at reasonable cost. The CPU will be a dual processor system employing Xeon Pentium IV 2.8 Ghz processors and a PCI-X (64 bit, 133 MHz) data bus. This design follows testing using our own, and borrowed hardware: we have tested the fibre-to-IDE solution trawl rate performance (and also some other hardware configurations - see Appendix 8.2) for one IDE RAID array unit using real-world astronomical queries and the OS/DBMS choice we will use for the WSA (see below; again, more details are given in Appendix 8.2). The results are shown in Figure 3, where several trawl-type queries were executed per disk array configuration (all RAID level 5) using a 5 Gbyte table to ensure no misleading results from caching anywhere in the system.
The performance of the fibre-to-IDE controllers used here is not as good as might be expected given that the single IDE disks are capable of reading at sustained rates of 40 Mbyte/s; additionally the saturation performance of one controller ( Mbyte/s) is not on its own up to the requirements. This needs a little more experimentation and optimisation before specifying and ordering the V1.0 hardware. We suspect (but do not yet have experimental evidence to support this suspicion) that the drop in per-disk performance to Mbyte/s and the saturation at Mbyte/s are inherent to the RAID controllers, and hence this is the price to be paid for high capacity and fault-tolerant inexpensive disk arrays. In the design illustrated in Figure 2, we will use software RAID0 striping over the logical volumes presented by two RAID controllers to further parallelise the IO up to Mbyte/s.
At the time of writing, we are borrowing Ultra320 SCSI hardware to compare the performance and cost of a configuration closer to  in order to inform the final V1.0 hardware decision; this comparison will include an investigation of the performance of the Ultra320 devices as hardware RAID controllers (for fault tolerance).
The baseline requirements for the catalogue OS/DBMS choice are flexibility (eg. provision of industry-standard SQL interface, ability to cope with Tbytes of data) and ease of use. Previously, we have implemented WFAU data services with ad hoc flat file systems, but such solutions are not flexible or scalable to large data volumes. Recently, we have been following SDSS science archive developments in order to benefit from the experience and software developed for the SDSS archive. We have used MS Windows and SQL Server to provide a flexible archive for the `6dF' database . We have designed a schema for an SQL Server implementation of our own SuperCOSMOS Sky Survey (SSS ) - for more details, see the Database Design Document AD04 and references therein. We have successfully ingested SSS data and exercised this database for records, or 1% of the total SSS size, in the SDSS-EDR regions (eg. the tests reported in Appendix 8.2). Our experience with all of the above indicates that Windows/SQL Server is an excellent choice for the V1.0 WSA. We will prototype the V1.0 WSA hardware solution by implementing the entire Tbyte SSS archive by the end of June 2003 to produce an externally queryable, Tbyte-scale archive for outside users to test prior to implementation of the V1.0 WSA (this service is to be known as the SuperCOSMOS Science Archive, or SSA).
Given our own experience of curating/serving the Tbyte-scale SSS, and on advice from our colleagues in the SDSS science archive group, we will implement a hardware design that consists of two independent SQL Servers: a `load' server and a publicly accessible `query' server. The main reasons for this are:
Security issues will be dealt with using solutions based on our experience in setting up secure web servers and data services. We require one other server for the purpose of data service connection to the outside world. Our existing SQL Server data services are isolated from the internet (it is not recommended to expose Windows database servers directly to the internet), and our existing online services (see, for example, the user interface document, AD05) are implemented on linux web servers connecting the users to the SQL Server via Apache/tomcat. We will follow this experience in implementing the WSA. The web server will be a mid-range linux PC; the local storage requirements will not be high so a 200 Gbyte hard disk drive will suffice; however some user access-time pixel manipulation will be necessary on this server so 2 Gbytes of physical memory will be required.
The V2.0 catalogue systems must be scalable to data volumes Tbytes and beyond. Currently, there is some uncertainty as to the suitability of SQL Server for this; maintaining rapid response for such large data volumes requires very high aggregate IO which in turn will probably require CPU parallelisation. Oracle or DB2 (running on unix/linux) may be a more suitable choice, but this needs more investigation. We have engaged academic database researchers in the University of Edinburgh, notably Profs. Peter Buneman and Malcolm Atkinson, who are both internationally regarded authorities in the indexing of large databases. We have established contacts with Ian Carney (Oracle) and Andy Knox (IBM/DB2) for technical advice concerning their respective DB management systems, and have instigated an R&D strand to the project to address scalability issues through V2.0 and beyond. At the time of writing, meetings are scheduled for April 8th and June 30th at the National e-Science Centre in Edinburgh with these external contacts and with Jim Gray (MS research) and Alex Szalay (SDSS at Johns Hopkins University) to progress this work. Our top level plan (see the Management and Planning document) shows how this strand fits into the overall project, and shows a review milestone at the end of Q1 2004 to examine the V2.0 hardware/OS/DBMS solution proposed.
Note that our V1.0 pixel solution is modular, scalable and limited in capacity only by physical accomodation issues - these are addressed in Section 7.2.
We do not anticipate any problems in achieving the required network bandwidth to routinely transfer processed data from CASU to WFAU.
The requirement for external network connectivity is 6 Mbytes/s continuous bandwidth. All UK HEIs and data centres, including WFAU and CASU, are interconnected using the Joint Academic Network (JANET;). We have tested the current, standard bandwidth between CASU and WFAU (see Appendix 8.4) and measured a bandwidth of Mbyte/s; we note that further tests  between CASU and the LEDAS data centre at Leicester University have achieved Mbyte/s while typical rates between any two JANET sites are Mbyte/s.
We have also consulted with our local networking experts within ATC/IfA computing support and Edinburgh University Computing Services, and we have investigated transfer protocols and have mapped out the network between WFAU and CASU (see Appendix 8.3). Noteworthy points are as follows:
The fundamental requirement for data security is that backups are essential for all data. Raw data are not a WFAU concern, but we note in passing that offline raw data copies of WFCAM data will be held at JAC and CASU (ESO will also have a raw data copy). Processed pixel data and standard catalogue detection products associated with those images will be stored on spinning disk and in an offline archive at CASU; processed pixel and catalogue data will of course be held online on spinning disk at WFAU on fault-tolerant RAID5 systems (see previously). We do not expect to make offline copies of the large volume processed pixel data because in the event of data loss, the affected files will be recoverable from the CASU backup. However, our experience is that catalogue product backups are highly advisable when wishing to provide a reliable service to users; for example, our SSS data have needed to be recovered from removable backup media once in the past, avoiding on online service interuption of several months. Hence we will use the latest high capacity system for removable media backups: `Ultrium' LTO-2 tape. There are several features of these systems that make them ideal for WSA catalogue backups:
We note that per Tbyte, tape is still the cheapest, most flexible, and most secure method of making removable media data copies.
We will isolate the WSA hardware from the site-wide LAN so as not to impact general on-site network performance with the heavy WFCAM data transfer load expected. To this end, a small, 1 Gbit/s LAN specifically for the WSA will be used. The mass storage pixel server and web server will be internally firewalled and connect to the SRIF connection and this WSA LAN. The resulting overall picture of the WSA hardware is shown in Figure 4.
Our present data service hardware are accomodated in a secure, air conditioned area protected by automatic fire extinguishing equipment. Sufficent power and space for the WSA V1.0 hardware are available in this same room; with some rearrangement we anticipate that additional V2.0 equipment will also be able to be accomodated in this room for the next 2 years. After this, we expect SuperCOSMOS plate scanning operations to be coming to an end, and anticipate being able to refurbish the existing computer area (which has the necessary air conditioning, automatic fire extinguishing, power and network infrastructure already in place) for the purposes of WSA hardware.
Effort for system set-up and management is available within the existing staff effort allocated to the WSA project (see the management and planning document, AD06). A small amount of additional computing support is available as part of the general allocation available to WFAU from the ATC/IfA computing support team. This includes staff experience in networking and management of both linux and Windows systems.
The following assumptions can be made about WFCAM; these are unlikely to change:
|LAS||183.4 nights||160 Gbyte per night =||29.3 Tbyte|
or an average over the science programme of Gbyte per full night.
This last item needs closer inspection. AD04 and references therein detail
the baseline set of parameters per detected object from CASU standard
pipeline processing. Assuming 4 bytes per parameter (they will be mainly
single precision floating point numbers) this is 80 parameters
4 bytes = 320 bytes per detection. Further, for the purposes of list-driven
co-located photometry (see the SRAD; ie. given a detection in one passband,
what are the object parameters at fixed positions using fixed apertures
and profiles in all other passbands) this value should be scaled appropriately
for UKIDSS passbands. So, to order of magnitude, the
catalogue record size is bytes per detected object. Now, the
number of detected objects per frame will vary enormously. For example, in the
UKIDSS GPS, towards the Galactic centre the surface density of sources is
likely to be per sq. deg. (or objects per pixel)
while in the lowest surface density regions of the LAS this is likely to
drop to per sq. deg. (or objects per pixel). If
we assume a typical surface density of sources as being per
sq. deg., or objects per pixel, then for a given amount of
pixel data the object catalogue overhead is
An estimate of the yearly rate can be made as follows. Nights per year are likely to be 80% UK time on UKIRT , the fraction of all UK time given over to WFCAM. Assume 110 Gbytes per night average, and for the likely range assume . Then, the average yearly data accumulation rate will be between 19 and 26 Tbytes.
In summary, data flow for the WSA will be:
An estimate of the final pixel storage requirement for UKIDSS at least is straightforward: assuming 4 bytes per pixel and microstepping (ie. 0.2 arcsec pixels); the areas of the LAS, GPS, GCS, are respectively 4000 sq. deg. filters; ; (stacked pixel data for the DXS and UDS are negligible for these purposes). This adds up to Tbytes; the final UKIDSS object catalogues and associated data will be Tbytes.
The uncertainties above (eg. detected objects per pixel; the amount of confidence array information needed to be stored, etc.) should not prevent progress on hardware design and acquisition, since storage for the final data volume does not have to be purchased up front. Provided sufficient storage is acquired for the first year of operation, it will become clearer during that time what the precise long term requirements are. In any case, the lifetime of the WSA project is significantly longer than the typical timescale of leaps in computer hardware design, so it should be expected that the initial hardware solution will not be the final one, and a phased approach (as is required from the science exploitation point of view; see the SRD) is implied.
Given the large range of possible hardware solutions and configurations that would be implemented for the WSA, we have been conducting a test programme using our existing, and also loaned hardware, to determine the best compromise between performance, cost, scalability and complexity. The tests have taken the form of employing 20 real-world astronomical queries  developed for the SQL Server implementation of the SuperCOSMOS Sky Survey, or SSA. These queries include several examples pertinent to expected usages of the WSA, eg. joint queries with the SDSS; however for the purposes of trawl benchmarking we have used a subset of 6 of the 20 queries that trawl the multi-epoch, multi-colour merged SSA catalogue corresponding to the SDSS-EDR regions. This catalogue is 4.87 Gbyte in size. The performance figures are summarised in Table 1.
The important point to note here is that the use of hardware RAID controllers appears to compromise the per-disk performance of the system: for example, the IDE disks used in configurations `merlin' 1 to 5 have been measured to be individually capable of sustained transfer rates of Mbyte/s whereas the 3 disk RAID5 set configured in `merlin1', for example, delivers only 24 Mbyte/s aggregate IO.
At the time of writing, our test programme is not quite finished. We are currently benchmarking Ultra320 SCSI controllers under otherwise identical conditions in order to compare the cost/performance trade-off before we finally place an order for the first V1.0 catalogue server.
Network morphology is illustrated in Figure 5. The circle in the top left shows the location of the current WFAU data servers on the network: cosaxp6 (SSS & 6dF web server) and grendel12 (current WFAU/AstroGrid linux/apache web server) is on the 100 Mbit/s LAN, wiglaf (Sloan EDR mirror) is on the 10 Mbit/s DMZ and grendel10 is being set up on the SRIF network (as srif112) to test its use (grendel10 only has a 100Mbit/s network card at the moment). The second router on the LAN is required to change from 100Mbit/s copper to Gbit/s fibre.
Network in and around the University is illustrated in the top right of Figure 5. The Strategic Research Infrastructure Fund upgrade to the Edinburgh network infrastructure is depicted in the softbox labelled SRIF. The core of the SRIF network can be thought of for present purposes as a set of four 1 Gbit/s fibres running between a pair of routers. One of these is connected to the University network, and the other is connected to a router (at the university King's Buildings) to which the ROE LAN attaches. That router is then connected to a router to which EaStMAN attaches, and that router, in turn, connects to the Edinburgh BAR (Backbone Access Router), which connects to the JANET backbone. All the connections shown here are 1 Gbit/s. A new Gbit/s link has been agreed from the SRIF router to which the ROE SRIF link attaches straight to the BAR, so that SRIF traffic can be sent to JANET on a separate route from UoE and EaStMAN traffic.
The rest of Figure 5 shows the basic morphology of JANET. Traffic from the Edinburgh BAR gets to Cambridge via the SuperJANET Core Routers (SCR) in Edinburgh, Leeds and London, and there is a 2.5Gbit/s link from the London SCR to the Cambridge BAR, which attaches to EastNet and the Cambridge University network (some of the links between SCRs are being upgraded to 10Gbit/s, and, indeed, our test results (see below) suggest that the Leeds-London link of our route to CASU is running at 10Gbit/s.
Most data transfer over the Internet proceeds through the use of TCP/IP, which is a suite of protocols.
IP (Internet Protocol) is a protocol for sending packets of data. It includes no notification of arrival, nor does it guarantee the order in which packets will arrive or when they will arrive.
TCP (Transmission Control Protocol) sits on top of IP, usually implemented in the kernel of Unix machines. Its operation can be best understood through a fiction in which there is a duplexed data stream (send & receive) running between applications sitting on the machines at each end of a data transfer: it is conventional to refer to one of these connections as `a TCP'. In this fiction, data either arrives in the correct order or the connection is broken. The sender numbers packets and requires acknowledgement of receipt of the packets. The sender buffers data packets until it receives an acknowledgement that the particular packet has been received, or until a time-out occurs due to a broken connection. So, clearly, if the sender's buffer is too small, it may fill up before the first acknowledgement is received, at which point it has to stop sending more packets. The acknowledgement is in the form of an indication of how much space is available in the buffer at the receiving end, and the sender acts conservatively on that information, so that, if the buffer space at the receiving end is decreasing, it slows down the speed at which it despatches more packets. So, a larger buffer at the receiving end is desirable, too (the obvious inference would be to try to have as large a buffer at either end as possible, and there would seem to be no reason to limit the buffer sizes, were it not for the fact that doing so would tie up possibly unnecessarily large amounts on memory in the two end-station machines). The receive buffer will be filled before the first acknowledgement is received by the sender if its size is less than the product of the data flow rate into the connection (assumed constant) and the round-trip delay time along the connection. This is called the Bandwidth-Delay Product (BDP), and it is a very useful quantity in analysing network performance.
The fundamental limit in the delay is the light-travel time between the end-stations, but in realistic systems the overall delay is significantly above this limiting value, due to processing delays, etc. As the distance between the end-stations increases, the delay time increases, more data is in flight and the receive buffer must be larger to cope with it. For example, given the delay time measured in tests between Edinburgh and Glasgow, 256KB buffers would be required for a Gbit/s link. Tests with a large-buffered system have attained transfer rates something like 450Mbit/s for this dedicated connection, which is close to the speeds of the internal buses in the machines, showing that, with correct configuration, the limiting factor can be the hardware at each end.
The default TCP buffer size is 64kB and the round trip light travel time between Edinburgh and Cambridge (1000km round trip) is about 3ms. This would suggest that the default buffer size could support a transfer rate of 6.4MB/s, which would be sufficient for WFCAM. However, tests record round trip travel times of 15ms, so the default buffer size cannot handle the sustained 5MB/s needed for WFCAM.
FTP is an application that runs on two TCP connections: it uses one for controls and another to send the data. However, a new application known as GridFTP can open parallel connections, and so can attain a higher aggregate bandwidth, by striping data transfer across them.
For completeness, UDP (User Datagram Protocol) is another protocol which sits on top of IP, but which has a much less functionality than TCP. In UDP, there are no acknowledgements and no error recovery; in essence, UDP just squirts lots of data into a connection, and whatever application is on the other end has to deal with whatever arrives. This is fine for things like video streams, where a lost frame is of no worth once the subsequent frame has been displayed, but, for something like FTP, where every packet is needed, the use of UDP necessitates that the application software handle everything that is otherwise done by TCP. This puts a lot of extra burden on the application code, so we do not consider UDP as a viable solution for transfer of WFCAM data.
Figure 6 shows the specified network bandwith between ROE and CASU at each hop in the chain represented in Figure 5; Figure 7 shows a similar picture when connecting to the JANET backbone via the SRIF network.
To test the data transfer and measure real transfer rates to compare with those specified in Figures 6 and 7, transfer of data was tracked with traceroute. The program pchar was used to measure the characteristics of the network path between the WFAU host wiglaf and cass39 (the Cambridge FTP server). It is an independently-written reimplementation of the pathchar utility, using similar algorithms. Both programs measure network throughput and round-trip time by sending varing-sized UDP (User Datagram Protocol) packets into the network and waiting for ICMP (Internet Control Message Protocol) messages in response. Table 2 summarises the results. It should be noted that the measured figures can be quite inaccurate as only small packets of data are being sent in these tests; further, as pointed out previously it would appear that the routers at the Cambridge end of JANET have been upgraded since the specifications were obtained. Anyway, the main point to note here is that there is a large available bandwidth between the Cambridge and Edinburgh BARs, and that a sustained transfer rate of 5 Mbyte/s can be achieved by upgrading connections at either end as detailed in the main text.
ADnn : Applicable Document No nn
BAR : Backbone Access Router
CASU : Cambridge Astronomical Survey Unit
DBMS : Database Management System
DMZ : De-militarised Zone
ICMP : Internet Control Message Protocol
IDE : Integrated Device Electronics
JANET : Joint Academic Network
LAN : Local Area Network
LEDAS : Leicester Data Archive Service
OS : Operating System
RAID : Redundant Array of Inexpensive Disks
SCR : SuperJANET Core Router
SCSI : Small Computer System Interconnect
SRAD : Science Requirements Analysis Document
SRIF : Science Research Investment Fund
UDP : User Datagram Protocol
VISTA: Visible and Infrared Survey Telescope for Astronomy
WFAU : Wide Field Astronomy Unit (Edinburgh)
|AD01||Science Requirements Analysis Document ||VDF-WFA-WSA-002
Issue: 1.3 (20/03/03)
|AD02||WSA Interface Control Document ||VDF-WFA-WSA-004
Issue: 1.0 (2/04/03)
|AD04||WSA Database Design Document ||VDF-WFA-WSA-007
Issue: 1.0 (2/04/03)
|AD06||WSA Management and Planning Document ||VDF-WFA-WSA-003
Issue: 1.0 (2/04/03)
|Issue||Date||Section(s) Affected||Description of Change/Change Request Reference/Remarks|
|Draft 1||07/03/03||All||New document|
|1.0||02/04/03||Minor changes||First issue (for CDR)|
|WFAU:||P Williams, N Hambly|
|CASU:||M Irwin, J Lewis|
|UKIDSS:||S. Warren, A. Lawrence|
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