High Speed Network Connectivity to a Telescope: Bringing the Electronic Universe to the Classroom

A Proposed NERO Demonstration Project

Gregory D. Bothun, Department of Physics , University of Oregon

David M. Meyer, Network Services, University of Oregon

Cliff Fairchild, Department of Physics, Oregon State University

Proposal Contents:

• 1.0 Project Overview

• 2.0 The Need for High Bandwidth

• 3.0 The Pine Mountain Observatory

• 4.0 Educational Underpinnings

• 5.0 Proposed Network Structure

• 6.0 Summary Remark

• 7.0 Project to Date

• 8.0 Project Budget

1.0 Project Overview:

Most all scientific research is now done from the desktop WorkStation of the individual scientist. In many cases, this includes the acquisition of the data itself, across the INTERNET. An excellent example of this process is provided by modern day astronomy and digital imaging devices ( CCDs ). We propose to use a real telescope, with digital camera, as a network device which will allow students in a remote classroom to acquire and analyze real data. In this way, students can go through the same set of procedures that a scientist does in the analysis and eventual publication of the data. This program would be unique in the nation and would clearly show the educational power that high speed networking can provide. Some aspects of this project have received preliminary support from the NERO project. These are detailed in Section 7.0 below. This proposal is to upgrade our preliminary configuration by providing better ON line facilities and T1 connectivity to the Internet.

2.0 The Need for High Bandwidth

Modern Image Processing in astronomy makes use of a powerful set of programs under the IRAF (Image Reduction Analysis Facility) Package which has been developed by the National Observatories. The IRAF package itself is some 200 Mbytes big and is the only sensible package to use when trying to analyze a CCD picture that itself is 8 Mbytes big. Fortunately, IRAF can be made to have a very intuitive interface and various procedures can be easily scripted and followed by students. Hence, using professionally acquired images and excellent image processing programs, we have the capability of leading students towards discovering the same things that professional astronomers can discover, from data, and which form the foundation of the science. Use of this image processing software through X-windows would also demand high bandwidth connectivity as the image file, which are painted on a remote screen, are still quite large. Note that this mode of observing and image acquisition is now routinely used by the PI when he has time on telescopes in Chile. All the observing is done from Eugene, using the INTERNET. The connectivity between the Chilean Observatory and the telescope is maintained and funded by NASA.

3.0 The Pine Mountain Observatory

The Friends of Pine Mountain represent a unique resource which serves as a valuable conduit for the purposes of public education and awareness of astronomy in particular and science in general. Due to dramatic decreases in the cost of computing and digital imaging devices, a greatly expanded program in public education in Astronomy is now possible. Currently at the observatory we offer an Electronic Universe program in which members of the public can actually take a digital image home with them.

This existing program could be effectively coupled with the high bandwidth network connectivity to make possible remote observing at any centrally located facility which has an INTERNET connection. Such a service would have great educational value for both the general public and the students in the state of Oregon. The University of Oregon is willing to offer this resource as a testbed for the educational aspects of the NERO project. The Department of Physics has already committed $50,000 (of which $20,000 has been spent) towards modernizing the facility, including the purchase and fabrication of an advanced CCD camera system (a paper letter of suppport from the Department Chairman is available upon request).

4.0 Educational Underpinnings

There is a tremendous potential offered by a high speed network to deliver real science to a remote audience. The ability to perform unbiased and accurate observations is crucial to scientific advancement. If we are to develop a scientifically informed public that has the ability to objectively analyze important issues (such as environmental ones) we need to promote awareness of how science is done and cultivate the spirit of inquiry in people of all ages as well as skepticism. Moreover, failure to understand this central concept obscures the real nature of science as being a discovery process. Rather, science becomes a collection of 'facts' which we have learned about the physical world. This serves to perpetuate the common misconception of science; namely that it is a collection of rigorous facts, boring in its methodology, with little relevance to society. Such a total misrepresentation of science to the general public easily leads to gullibility in terms of accepting scientific data/theory as truth. This also leads to an unfortunately high level of public acceptance of pseudo-science (astrology, scientology, etc) or outrageous scientific claims (cold fusion). Without an informed public that appreciates science as a search for knowledge and not just the obtainment of knowledge, how can we ever increase public support for its practice?

It is clearly in the National interest to formulate and practice an effective strategy for deterring this view of science and revealing the true nature of science as a discovery process. One effective strategy is to make science more exciting and hands-on. All of us, regardless of our level of intellectual sophistication are intrinsically excited and curious when we discover (see or observe) something for the very first time. This excitement generally translates into motivation to learn and it is a skill which we should never lose. Children enter this world wide-eyed with excitement about discovering everything that is in it. Why should such excitement for discovering the natural world diminish over time? With the proposed high bandwidth connection to what is essentially now a digital astronomical camera, we can indeed serve science as it really is, a discovery of the unknown. Indeed, imagine the excitement this project can generate when some classroom can watch the moon literally drift across their X-windows screen.

5.0 Proposed Network Structure

The various components of this connectivity are the following:

• The telescope control computer (TCC). Currently this is a 486 PC which is hooked directly to the drive system of the telescope and receives TTL pulses from digital encoders in order to control positioning and tracking. This is a DOS based program.

• The instrument control computer (ICC). This is another 486 PC which directly controls the CCD camera electronics. Images are acquired and initially downloaded to this computer.

• The TCC and ICC are connected with Ethernet. A remote control protocol called ReachOut (from Ocean Isle Software) effectively simulates a LAN. With these components we can dial in to the ICC with a modem, switch to the TCC, position the telescope, switch back to the ICC and acquire an image. That image, when downloaded, then appears on the remote screen at the other end of the modem connection.

• We can effectively replace the slow speed modem connection (which is not a hindrance for actually moving the telescope) with a T1 with IPX running over it. This will allow direct access to the Reachout LAN. Note, that in the very near future we expect, using new communications protocol packages, to be able to run IP directly over the PC LAN.

• The data processing computer (DPC). This will be a Sparcstation 20 running IRAF. Data from the ICC will go directly to the DPC for processing. Data transfer will be over the local ethernet via FTP running under LAN Workplace for DOS. The DPC will be the main point of remote access as it will act as the X-server. This computer will also have at least a 2 Gbyte SCSI disk to store the image archive.

• On a scheduled basis, this entire system can then be accessed, using T1 connectivity over the INTERNET from a PC which doubles as an X-terminal (by running X-windows emulations such as Exceed/W). The telescope can be controlled and the data can be acquired using IPX over the T1 line as the remote PC can now communicate with the TCC and ICC. By turning the PC into an X-terminal, the DPC can then be accessed and manipulation of the data can be occurred via a menu driven system. This system will successfully reproduce what is done at a modern, professional, astronomical facility. We propose to offer this as an educational facility 50% of the time (between first and third quarter lunar phases). The other 50% will be used for research and the development of a large image archive to serve as a full time educational data base.

6.0 Summary Remark:

7.0 Progress to Date:

• Installation of Frame Relay service at the 57 Kbaud level. Montly cost is 73.11 per end (146.22 total)

• A Router + DSU/CSU for this 57 Kbaud Connection

• A SUN Workstation to serve as the initial DPC. This is currently a Sparc 1+ which has been donated (on long term loan) by SUN

• Purchase of a 2 Gigabyte Disk to serve as the initial data archive

8.0 Project Budget:

• Installation of T1 Circuit --> $5000

• Monthly Leased Line Charges --> $282.61 per month per end

• Sparc 20 for X-server --> $8750

• DSU/CSU for T1 --> $3000

• 4 Gigabytes of Local Disk --> $2000

• Improvements to Mountain LAN --> $2000

• Various Administrative Costs --> $7500 per year
  • Upfront Equipment Costs = $20750

  • On going costs = $14283 per year

  • Total Project Cost for 2 Years = $49316

• Cost Sharing:
  • UO Physics Department $30,000

  • UO Network Services $5,000