** ** ****** ** ** ******** ** ** ***** ** ** ** * ** ** ** *** ** ** ** ** ** * ** ** ** * **** **** ** * ** ** ** ** ** **** ** ** ** ** ** *** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** * ** ** ** ** ** ****** ** ** ** ***** ***** ** ** ** ****** ****** ***** ** **** ******** ****** ****** ** ** ** ** * ** ** * ** ** ** ** ****** **** ** ** ** ** **** ****** ** ** ** ** **** ** ** ** ** ** ** ** ** ** ** ** ** * ** ** ** ** ** ** ** ****** ***** ** **** ** ****** ** ** **** KY REGISTER **** KY REGISTER **** KY REGISTER **** KY REGISTER *** APRIL 1989 TABLE OF CONTENTS VIEW: Your Information Service. . . . . . . . . . . . . . . . . . . 51 CCS Spring Seminar Series . . . . . . . . . . . . . . . . . . . . . 76 INFO/EXPO. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 96 Preventing Microcomputer Virus Attacks . . . . . . . . . . . . . . . 111 Common Computer Diseases . . . . . . . . . . . . . . . . . . . . . . 241 Holiday Schedule . . . . . . . . . . . . . . . . . . . . . . . . . . 296 Binary Operations in Computers . . . . . . . . . . . . . . . . . . . 306 New Versions on CMS . . . . . . . . . . . . . . . . . . . . . . . . 457 DI3000 Enhancements . . . . . . . . . . . . . . . . . . . . . . . . 478 New Graphics Software . . . . . . . . . . . . . . . . . . . . . . . 519 Suggestions . . . . . . . . . . . . . . . . . . . . . . . . . . . . 588 Service Directory . . . . . . . . . . . . . . . . . . . . . . . . . 670 ************************************************************************* VIEW: YOUR INFORMATION SERVICE VIEW is almost a year old, and it's turned into one of the UKCC's most successful services. Primarily designed for campuswide news and announcements, VIEW also offers news from various networks on such subjects as astronomy, desktop publishing, laser printers, risks, space, vector processing, veterinary medicine, video technology, and viruses. It's easy to use VIEW. Just enter VIEW from your CMS userid, and VIEW will display a menu. Move the cursor to an item, and press ENTER to select it. If you know the name of an item, you can bypass the menus. For example, to see the campus news, you could enter VIEW NEWS and go directly to it. If your department has campus news suitable for VIEW, contact Dave Elbon at 257-2230, SYSDAVE@UKCC.UKY.EDU, 211B McVey Hall. ************************************************************************* CCS SPRING SEMINAR SERIES All of the following seminars are free and open to the public. Unless otherwise noted, all seminars will be held on Wednesdays, 4:00 p.m. in 137 Chemistry-Physics Building. Refreshments at 3:30. April 5 Imaging the Earth's Interior by Supercomputer Larry Brown, Cornell University April 12 Computational Fluid Dynamics Philip M. Gresho, Lawrence Livermore Laboratory April 19 Seismic Modeling of the Earth's Interior Freeman Gilbert, University of California, San Diego ************************************************************************* INFO/EXPO Info/Expo will be held April 24 and 25 in the Student Center. Twenty departments throughout UK will be giving exhibits and demonstrations of their electronic information products, including university and national databases, CD databases, electronic archives, computer bulletin boards, electronic mail, and networking. UKCC's Academic User Services is planning to provide demonstrations of BITNET, the Kurzweil Scanner, PHOENIX, and various graphics applications. For more information, contact Stephanie Allen of the Medical Center Library at 233-6567. ************************************************************************* PREVENTING MICROCOMPUTER VIRUS ATTACKS Since the early 1980s when the term was first coined, computer viruses have generated unprecedented degrees of paranoia among computer users and have resulted in a great deal of media attention. However, not all users are equally susceptible to becoming infected with a virus. If you've cultivated good computer working habits, work in a single-machine environment, and don't trade software with other users, you're probably safe. If you have sloppy habits, work in a network environment, or access bulletin boards you may be in a more vulnerable position. To help you avoid contaminating your microcomputer with a virus and to help you deal with a virus in case your computer becomes infected, this article explains what a computer virus is, the damage potential of a virus, how to detect whether you have a virus, what to do if you get a virus, and tips for establishing good work habits so your computer can stay virus-free. What Is a Virus? A computer virus is a small segment of executable code which has been inserted into a computer's operating system or application program. A virus can duplicate and transmit itself to other computers or applications over a network or through storage devices such as floppy disks. A virus usually enters a computing system without the computer owner's awareness and begins to give unauthorized commands to the computer. If left unchecked, a virus can be passed on whenever the host computer communicates with other computers through a network or whenever uninfected software comes in contact with the virus. A virus will usually remain dormant for a time, during which it may continue to infect other programs or computers. The dormancy period may end when a designated event occurs, such as the arrival of a particular date or after a certain number of infections. The virus may then perform some action specified by its human creator. This could simply be the flashing of a harmless message on the computer screen (such as the peace message that appeared on March 2, 1988 on Macintosh computers infected with the MacMag virus) or destructive actions such as reformatting hard disks or destroying data files. Usually, viruses are written only for certain types or models of computers and so are brand specific. Damage Potential Since they are essentially executable code, viruses have almost unlimited power in your computing system. The extent of a virus's damage will depend, in large part, on how malicious the human creator of the virus was. Some viruses can inflict not only software or data file damage, but hardware damage as well by speeding up the movement of disk drives or hard disk heads so that moving parts wear out faster. Usually, however, viruses are relatively benign and pose only varying degrees of annoyance and inconvenience. Detecting a Virus You can have a virus in your computer system for weeks or even months without suffering any major symptoms or serious harm. However, the sooner you detect one and get rid of it, the fewer applications and other computer systems you'll infect. The best indicator of a viral presence is anything unusual in your computer's behavior, such as: system crashes excessive access times printing glitches odd noises extra beeps longer times in booting up changes in the size, name, or date of files While many of these symptoms can be traced to causes other than virus, you should nonetheless be wary if your system is behaving more erratically than usual. Not all viruses, however, are detected easily. Many viruses are much more elusive and can implant themselves in existing files without overtly affecting a computer's operation or notifying you about changes in file lengths or modification dates. What To Do If You Get a Virus If you suspect your computer might be contaminated with a virus, you can obtain one of a number of virus-detection or vaccine programs currently available from authorized dealers. However, keep in mind that commercial vaccine products generally don't provide long-term protection and many quickly become a nuisance in daily usage. For example, some virus-detection programs examine the operating system every time you boot up and warn you of changes that can be construed as a possible virus infection -- this means legitimate changes such as upgrades, additions, and so on. Also, vaccines only work against certain existing viruses and many can be easily defeated. Most vaccines don't protect you from other viruses or any new viruses that may be created in the future. While some vaccine programs may be successful in removing a virus, the simplest eradication method may be to shut the computer off and load it up again with uninfected backups of your files. If you have a hard disk, you should completely erase its contents by reformatting (reinitializing) it. Here's one way to get rid of a virus: Turn off the computer to purge its temporary memory (RAM), then turn it on. Boot up machine with a clean operating system. Reformat the hard disk. Restore system files and applications from backups of the original master disks. Restore data files. Check any other disks you may have used. Destroy all infected disks. Establishing Good Work Habits For this method to be effective, you must have clean backups of all your programs and data files. You can ensure you have clean copies of all your programs and files by backing them up each time you work on them. Backups can then be archived for a period of time. How long to archive them depends on how often you use your microcomputer and how important you consider your files to be. Keep in mind that if your computer does become infected with a dormant virus, even your later backups might be infected. However, if you have been practicing good microcomputer working habits such as backing up your files often and archiving them, you can significantly reduce the potential for serious damage and the inconvenience and the annoyance of having your microcomputer infected with a computer virus. To keep informed about the latest information concerning viruses and related topics, refer to an e-mail discussion forum called VIRUS-L, available to all CMS users. Enter VIEW NETNEWS VIRUS-L. -- Jim Powlesland Editor's Note: This article was adapted from the February 1989 issue of "The Micro Byte," University of Calgary. ************************************************************************* COMMON COMPUTER DISEASES If your computing system becomes infected by a computer disease, don't panic! There are methods available to eradicate the intruder and to help you prevent future infections. The common ground all computer disease programs share is that they must write to a disk and change files. Computer diseases can attack in a variety of ways, including displaying unsolicited messages or graphics, destroying data files, or monopolizing all available disk and memory space, to name just a few. These programs attack both Macintosh and IBM PC-compatible microcomputers, as well as larger mainframe systems. Some specific examples of computer disease programs commonly found on microcomputers are detailed below. For Macintosh Systems Scores attacks the system file and replicates itself for a few days. After a brief period of dormancy, the Scores virus then reactivates itself to interfere with saving data and cause system crashes. This virus alters the system's notepad and scrapbook files by changing them from Macintosh icons to generic document icons. If your system doesn't have notepad and scrapbook files the virus will create them and then do the changes. The nVIR virus has many varieties, but the most common attacks the system and causes applications to beep upon launching or at other odd moments. The "Universal Message of Peace" virus was of the nVIR variety as well. For IBM-PC Compatible Systems The Command Virus attaches itself to the COMMAND.COM file and scrambles the file allocation table, thus causing the system to be unable to find any of the data stored on the disk. The Friday the 13th Virus infects every .COM file and deletes whatever program is executed on a Friday the 13th. The Lehigh Virus infects the COMMAND.COM file, replicates itself four times (onto other disks), and then destroys all the data on the resident hard disk. The Jerusalem Virus infects .COM or .EXE files in order to scramble data and destroy file allocation tables. The Pakistani Brain infects the boot sector of a hard disk and then replicates itself onto every floppy diskette used. This program doesn't actually destroy information, but because it continues to replicate itself it can cause your computing system to operate at substantially reduced speeds. If you suspect your computer system is infected by a computer virus, or if you'd like additional information, contact Brenda Ghaelian, BRENDA@UKCC, 257-2203. -- Marilyn Everingham Editor's Note: This article was adapted from the Mid-Winter Issue of "Acronyms," Michigan State University. ************************************************************************* HOLIDAY SCHEDULE Monday, May 29 is an official UK holiday. The UKCC offices, Consulting Room, and Micro Lab will be closed. The Data Center and Users' Rooms in 103 and 111 McVey Hall will be open from Noon until 12:30 a.m. The IBM and PRIME systems will be in operation, as usual. ************************************************************************* BINARY OPERATIONS IN COMPUTERS Mechanical devices have been used to aid in calculation for centuries, yet none of these devices have had anywhere near the speed and power of the modern digital computer. Many attempts were made to optimize mechanical computers, but they were always limited by speed, size, and accuracy. It took a fundamental design change to allow computers to use numbers in a different way. Later, a unique group of components would allow miniaturization and greater speed. Mechanical computers are analog devices that measure and compare corresponding quantities. A good example of an analog calculator is a slide rule. Linear or logarithmic number scales are inscribed on adjacent sliding surfaces. By aligning a set of quantities, such as adding the length represented by one logarithm to the length of another, the sum of the two representing the multiplication of the two numbers, may be read directly from the scale. Analog devices have many uses, but it is difficult and expensive to increase their precision. For instance, to increase the precision of a slide rule ten times it must be made ten times longer. The precision of digital devices, on the other hand, may be increased by adding facilities for more digits. A simple analogy of a digital device is a bowling alley. Whether one pin or ten are knocked down, only a discrete number of pins are counted (no fractional amounts). Position of the pins and the difficulty of a roll are not scored; that is, one single quantity of a system is measured. If one person bowls, one lane is used. If a league bowls, many lanes are used, and the total number of pins goes up (more significant digits are used), without a change in the number of pins in each lane (the basic counting unit is unchanged). Mechanical computers are slow, compared to electronic computers. They rely on physical movement of an object through distance and are restricted by the size of the object and mechanical friction. Electronic devices are limited by the speed of electrical current, and their friction (or resistance) does not have an effect we can notice directly. Electronic computers can also perform operations at speeds far beyond what is possible on a mechanical computer. The conceptual leap that paved the way for electronic computers was to change the way computers count. Rather than using the base ten system to represent numbers internally, computers use base two. In the base two system, numbers are represented with only two digits, one and zero. Each place represents a power of two, just as each place in our decimal system represents a power of ten. 11001 (base 2) = 25 (base 10) 16+8+0+0+1 = 20+5 Base two results in a much simpler internal arrangement. A number can be represented in binary by a row of switches turned on and off. Binary Operations Binary operations are operations involving only two operating states. These states can represent on and off, yes and no, true and false, one and zero, and so on. Decimal numbers can be converted to binary numbers and can be manipulated with binary operations. This provides several advantages, which can best be understood by examining some of the attributes of binary systems. An English mathematician, George Boole (1815-1864), laid the foundations for the modern study of binary logic. He explored the logical relationships possible when a number system is composed only of zeros and ones. These relationships are called Boolean algebra, and they underlie most of the circuits used in modern computers. Mathematical logic is the same logic that we use in everyday life, except that it is applied to numbers. A logical statement can be in the form: If something, then something else. For example, If I hear pattering on the roof, then it is raining. If the engine stops, and the gas gauge is on E, then the car is out gas. If it rains or it snows, then we won't go to the park. If it is not raining, and the day is warm, then we will go to the park. If it is neither raining nor cold, then we will go to the park. Computers deal with these same kind of decisions: if, then, and, or, not, nor. Their logical circuits make decisions and perform operations on the numbers they're given. An operation on logic units involves testing whether a condition is met according to a rule. At the most basic level, computers have only two types of conditions to consider: is current on at a lead, or is it off? For example, a decision to go to the beach has the following conditions: If it is hot and it is not raining, we will go to the races. This can be put in the form of a rule with A being the temperature (hot or cold), B being the presence of rain, and C being the action of going to the races. The rule then is: If A and not B, then C. Here are the possible combinations of weather and temperature, with a yes or no decision about going to the races. rain not rain cold no no hot no yes Of the four possible outcomes, one is positive (going to the races). This example illustrates several properties of logical statements. Given a set of conditions, a logical sentence can be constructed which permits a unique rule regarding the desired outcome. This rule can be implemented in a repeatable way so that the same outcomes occur each time we apply the rule to a set of conditions. We are choosing to apply these rules to binary conditions, that is, conditions which have a yes or no answer. The answers, or outcomes, are also in the form of a binary condition. This means the outcomes can be used as input to some future decision. Boole's analysis of binary number systems can be applied to different systems, depending upon the empirical interpretation given to the logical symbols. If the symbols represent the numbers zero and one, Boolean algebra results, which defines binary arithmetic processes. Finally, if the symbols represent on-off states, they can be used as a guide to building electronic circuitry. Binary Circuitry Binary logic in a circuit needs switches to provide on-and-off states. Vacuum tubes were used in the first computers, but transistors now provide this function in electronic computers. A transistor is an electronic component which controls the flow of electricity in a circuit. It has three leads, or connections. One lead controls the flow of electricity across the other two, allowing the transistor to turn on or off. Think of the leads as input, output, and control. A transistor can be made to switch on with a voltage applied to the control lead. This trigger voltage can be a signal sent from another circuit. Combining transistors in the right ways make logic circuits that will react the same way each time to a given set of conditions. Logic circuits are designed to perform the tasks of data input, storage and transfer of data, binary arithmetic, and control of all the devices connected to a computer. Each collection of components can be represented by a logic building block called a gate, because it only passes current if some conditions are met. Other gates are the NOT gate, the NAND, and NOR gates. The NOT gate simply reverses the state of an input. When combined with an AND gate, the NOT-AND combination is called a NAND gate. A NOR gate is a NOT-OR combination. Binary logic not only provides a means of counting but provides the ability to hardwire logic, or deductive reasoning, into the computer. In one sense, the logic circuits are mechanized, valid, arguments. They can perform comparisons, examine conditional statements, and make decisions. In this sense, computers are built to think deductively. Binary operations are well suited to the nature of computer components. Punched cards either have a hole in a particular spot or they don't. Magnetic tapes and disks are magnetized in a spot or they are not. In computer circuits, semiconductor chips pass information in a relay of on-and-off pulses. Because the information passed through a computer depends only on the presence or absence of a carrier current, and not on the power of that current, computer circuits can be made as small as physically practical, and as quick as technology allows. This discussion of computer operations will continue with a look at how logic building blocks are used in a computer. -- Tom Faller ************************************************************************* NEW VERSIONS ON CMS The latest version of the PL/I compiler is now available on all CMS systems. To access the PL/I compiler, GRAB PLI To get online help after you've GRABbed the disk, enter HELP PLI X-MENU 1.9 and SYNCSORT 6.1f have also been installed. They are primarily maintenance releases with no new features. If you have any problems or questions about any of these software applications, contact Trent Fraebel at 257-2277, 206 McVey Hall, SYSTRENT@UKCC.UKY.EDU. -- Trent Fraebel ************************************************************************* DI3000 ENHANCEMENTS Several enhancements have been made to DI3000 version 5.1.1 using VS FORTRAN 2.3, allowing you to use several device drivers at the same time. This linkage method allows you to create a module and save it, linking the driver you need at the moment the module is run to generate a display. This means that the rather lengthy process of loading the text files need only go on once and can be avoided for subsequent runs. The dynamic linking module will prompt you if you haven't specified a device driver by presenting a list of drivers to choose from before displaying anything. To gain the last advantages you must retain your program module on disk, and this may pose problems with storage space. However, the START option can be used to re-link and load your program each time it is run. There are a few changes in the syntax of the command. For example: DI3000 MYPROG (START runs your program with the default options. You will be prompted for your choice of drivers. GRAB IMSL DI3000 MYPROG (G LIBS IMSL10SA IMSL10SB builds a module using GRAFMAKER and IMSL libraries. DI3000 MYPROG (D DRV5080 E selects the IBM5080 as driver and runs the MYPROG module created in the previous example. It isn't necessary to specify TXTLIBS since the module is already built. Enter HELP DI3000 after GRABbing DI3000 198 for more information. If you need more help with DI3000, contact Chuck Fisher at 257-2268, 206 McVey Hall, SYSCHUCK@UKCC.UKY.EDU. -- Charles Fisher ************************************************************************* NEW GRAPHICS SOFTWARE Two significant new graphics software systems from Precision Visuals are now available on the IBM 3084 and 3090: PicSure Plus and GK-2000. The first, PicSure Plus, is intended for a wide range of applications, including reduction and analysis of data, plotting of trends, projections and relationships, and generation of publication-quality illustrations for technical journals or management reports. PicSure Plus is an interactive presentation graphics system with both menu- and command-driven modes. Novices can produce their own charts and graphs quickly, with a prompting menu interface called "PicQuick." More experienced users can build tailored menu interfaces for specific applications or environments with a powerful command language called "PicTools." To access PicSure, GRAB DI3000 392 GRAB VSF2 230 and type PICSURE A banner and > will appear. To get into the menu-driven (PicQuick) mode, type MENU. The system will prompt you for all necessary responses, including an output device driver name. If the device name is known at the beginning of the session, type PICSURE devicename where devicename is one of the currently implemented DI-3000 device drivers. The second new system is a graphics subroutine library called GK-2000. It is similar in concept to the DI-3000 family of routines but is based upon the GKS (Graphical Kernel System) standard adopted several years ago. DI3000 is based upon the proposed CORE standard. Precision Visuals describes GK- 2000 as a "tools package that meets and exceeds the international GKS Level 2b specifications, enabling 2D application development utilizing optional productivity extensions. GK-2000 is structured as a modular, hierarchical software network of 230 user-callable FORTRAN subroutines. It is machine and device independent and designed as the foundation for graphics application development. GK-2000 is used by scientists, researchers, and engineers in fields ranging from aerospace and engineering to oil and energy exploration and development. Typical uses include finite element analysis, scientific data display, simulation, prototyping, fluid flow modeling, cartography, contouring, civil engineering, process control, architectural design, and site planning." To access GK-2000, GRAB DI3000 391 GRAB DI3000 198 GRAB VSF2 230 To run a compiled FORTRAN program type GKRUN77 textfile driver X where textfile is the compiled (with VSF2 230) program and driver is the selected output device (see DRVLIB MENU for choices). X designates the extended version of GK-2000. If you'd like more information about either of these systems, contact Bob Williamson, 257-2227, 207 McVey Hall, ROBERTT@UKCC.UKY.EDU. -- Bob Williamson ************************************************************************* SUGGESTIONS 1. Make the Micro Lab bigger; we're running out of room in there. Put a women's restroom on the first floor, and how about a small study lounge with a couple of couches and table? >>>Renovation plans have been developed to significantly improve the public service areas of McVey Hall. We're hoping funding will be available over the next two years to accomplish the necessary work. 2. I think the UKCC staff is great! >>>Thanks! We think our users are special, too. 3. I did a WHOIS guess Jane Smith and got pages and pages of WHOIS output, it would say some- thing like "more than 20, try more restrictive search," then it would give me another screen of output and repeat the same message. I had to detach and re-IPL to stop it. >>>Thanks for reporting the problem. Re-IPLing won't affect incoming messages. Anytime you find yourself receiving an excess of messages from any source you can stop them by waiting for the screen to fill, typing #CP SET MSG OFF, and pressing Enter. Clear the screen and the messages should stop soon. This won't affect whatever is sending the messages (it's unlikely there is anything you can do to affect the sender), but it will stop the display. You can SET MSG ON again later. 4. Yesterday afternoon and again this afternoon the IBM 3084 has been running extraordinarily slowly. This was especially noticeable today when I logged onto ISAAC at the University of Washington via telnet. Our machine was so slow that I was waiting sometimes five minutes for a response to a single command or keystroke. Of course, it's impossible to use the system under these circumstances. Even ordinary mail transactions were taking a minute or more in some cases. Why was this happening, and what can be done about it? >>>We're not sure what the problem is, but we've been working on it. 5. Who should I call about dial-up problems? The Consultant told me to use 4861 instead of 9200, but that number hasn't been in service for months. Should I call Communications, or does the UKCC still handle the phone lines and modems? >>>Sorry you got outdated information. When you have a dial-up problem call the Communications Department at 257-2229. 6. I'm getting mail from ISUVAX which is somehow hooked into BITNET. The problem I'm having is that their mailer appends a .BITNET to the node name ISUVAX and whenever I use the reply key, which I do quite often, I get returned mail from the UKCC mailer because it doesn't know where ISUVAX.BITNET is. From what I've understood of domain addressing, the .BITNET is an incorrect appendage for an internet address. Could you please fix our mailer or give me the name of someone else I can gripe to at ISUVAX? >>>First, although the .BITNET suffix is not technically correct in the domain naming scheme, it is widely used by many BITNET nodes. It's the MAILER on UKCCS that is rejecting the files with the .BITNET suffix in the address. We're testing a new version of the MAILER on UKCC, and it seems to handle such addresses correctly. Sorry for the inconvenience. 7. Tonight there are several people waiting for printouts because a PRIME user is printing several copies of a Dungeons & Dragons manual in excess of 14,000 lines. No wonder these printers are falling apart. >>>The services and facilities of the UKCC are available to all UK students, faculty, and staff. Since many of our facilities, such as the printers, are public access, it's important that all users respect the rights and interests of others. In the event repeated, flagrant abuse of the facilities is detected, user privileges can and will be suspended. 8. While using NODE UHVAX1 I could not find it in the database, but examining the database shows it to be there. >>>Thanks for reporting this; we're investigating. ************************************************************************* UKCC SERVICE DIRECTORY McVey Service E-Mail Address Phone Hall Vice President, Information Services Eugene R. Williams DPS128@UKCC 257-3609 Director, University Computing Services Dr. Douglas Hurley HURLEY@UKCC 257-2900 128 Director, Communications & Distributed Systems Doyle Friskney DOYLE@UKCC 257-6225 Director, Computational Sciences Dr. John Connolly CONNOLLY@UKCC 257-8737 324 Academic Consulting Services Lavine Thrailkill UKC105@UKCC 257-2257 121 CMS Consulting Bob Crovo CROVO@UKCC 257-2258 109 Complaints Carol Lotz LOTZ@UKCC 257-2213 129 Consultant for Remote Sites Wanda Dixon Spisak WANDA@UKCC 257-2206 115 Consulting Consultant on Duty SUGGEST@UKCC 257-2249 110 Contingency Planning & Security Jack L. Coffman UKA051@UKCC 257-2273 218 Database - IDMS Rick Chlopan DBA003@UKCC 257-2211 230E Data Center 257-2222 61 Data Entry Frank McCormick OPFRANK@UKCC 257-2216 72 Disk Rental Janet Hyatt HYATT@UKCC 257-2212 130 Larry Johnson JOHNSON@UKCC 257-2217 130 Facilities Operations Joe Williams UKA048@UKCC 257-2231 122 Graphics Consultation Bob Williamson ROBERTT@UKCC 257-2227 207 Information Center Judy Kisil UKA041@UKCC 257-2241 222 Information Resources Dr. Jon Hesseldenz UKA045@UKCC 257-3904 230D Instructional Software Wayne Beech WAYNE@UKCC 257-2238 100 Machine Room 257-2222 59 Management Information Systems Forrest Hahn UKA006@UKCC 257-2260 123 Memos and Manuals Consulting Room 257-2249 110 Micro Lab 257-2207 107 Network/Telecommunications UKT101@UKCC 257-2229 New Accounts Janet Hyatt HYATT@UKCC 257-2212 130 Larry Johnson JOHNSON@UKCC 257-2217 130 Numerical Analysis Consulting Anne Leigh ANNE@UKCC 257-2205 109B Optical Scanner - NCS Chris Corman CHRIS@UKCC 257-2243 109 Bob Crovo CROVO@UKCC 257-2258 109 Passwords Janet Hyatt HYATT@UKCC 257-2212 130 Larry Johnson JOHNSON@UKCC 257-2217 130 PRIME Information Peggy Akridge PEGGY@UKCC 257-2237 100 Program Documentation/Libraries Consulting Room 257-2249 110 Publications Office Marguerite Floyd EDITOR@UKCC 257-2219 200 Refunds Consulting Room 257-2249 110 SAS and SPSS Consulting Steve Thomson STEVE@UKCC 257-2259 120 Lorinda Wang UKC333@UKCC 257-2204 109B Statistical Consulting Steve Thomson STEVE@UKCC 257-2259 120 Tapes to Borrow, Tape Storage Data Center 257-2222 61 Tours of UKCC Lavine Thrailkill UKC105@UKCC 257-2257 121 User Account Services Janet Hyatt HYATT@UKCC 257-2212 130 Larry Johnson JOHNSON@UKCC 257-2217 130 Vectorization Consulting Tom Faller TOMFAL@UKCC 257-2236 314 ************************************************************************* UNIVERSITY COMPUTING ADVISORY COMMITTEE Douglas E. Hurley, Central Administration H. Clay Owen, Central Administration A.J. Hauselman, Community Colleges James W. Phillips, Community Colleges Raphael Finkel, Lexington Campus Leonard K. Peters, Lexington Campus N. Clare Detraz, Medical Center David A. Nash, Medical Center T. Earle Bowen, Ex Officio Ben W. Carr, Ex Officio Wimberly C. Royster, Ex Officio Donald E. Sands, Ex Officio Eugene R. Williams, Ex Officio *************************************************************************