rfc321.txt

著名的RFC文档,其中有一些文档是已经翻译成中文的的.

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the work.

3.3  Task III - Demonstrate Extensions to TICCIT System Capabilities
     ---------------------------------------------------------------
     That Are Possible by Drawing on ARPANET Resources
     -------------------------------------------------

     Many of the resources on the ARPANET were designed as stand

alone systems not intended for use over the network nor for facile

interfacing with other systems.  Thus we have found that more work

than initially was estimated is needed to use the selected CAI-related

systems over the network.  Therefore we plan to fulfill the goals of

each subtask by demonstrating the use of selected resources over the

network but will not attempt to interconnect the systems in any

fashion during FY1972.  A proposal to investigate the notion of a

distributed CAI system using ARPANET resources is under preparation.

     The status of our progress in using CAI-related resources over

the network is presented below.

     (a)  Demonstrate that the range of curriculum material
          can be extended.

The Culler-Fried (C-F) On-Line Graphics-Oriented system at UCSB was

selected to demonstrate its use in mathematics curriculum.  The system

has been used successfully in a variety of courses at UCSB, including

chemistry, mathematics, and economics(30,31,32,33,35).

     The Culler-Fried system's normal mode of operation is with two

keyboards and a Tektronics graphics display device. The keys on the

second keyboard are "function" keys; for example, by pressing a single

key the user can initiate complex actions such as displaying a plot




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of a convolution function(35). The system can also be used to provide

online access to the 360/75 system to remotely control the execution

of programs. The latter service is currently available on the network

through TELNET. Access to the system was made possible by defining a

mapping from ASCII characters (sent as the "network virtual terminal")

to characters expected by the OLS. Thus it is often necessary to type

a sequence of characters on a TTY-type device to invoke the action of

a single function key. Under the current implementation, graphics

output to the network is suppressed.

     We plan to demonstrate the use of the C-F system on an IMLAC

graphics device attached to our TIP. During the first phase of our

implementation, we will not simulate the C-F function keyboard but

will enter our graphics input using the procedures defined for use

via TELNET. For output, UCSB agreed to provide a new output processor

which will no longer suppress graphics output, but will map it into

the remote graphics capabilities as provided by IMLAC (Figure 3).

Such a system was implemented in early February but due to the

character-oriented nature of the IMLAC device available to us, the

resolution was unsatisfactory. We have now defined a low-level

graphics protocol.  UCSB has agreed to send graphics output to us

using this protocol.  We have had to program new processes for the

IMLAC and are now debugging the new programs.  Due to the limited

core available on the particular IMLAC that we are using (4K 16 bit

words) which limits the size of internal display lists, we will not




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be able to plot very complex graphs.  However, the software being

developed is general and can be moved to an IMLAC with larger core

capacity.  We currently send alphanumeric input from a TTY or 3300

and divert the graphics output to the IMLAC.

     When we can access the Culler-Fried system for graphics output

successfully via the network, we plan to modify the IMLAC programs to

permit alpha input from the IMLAC keyboard.  We also plan to investi-

gate the possibility of attaching a function keyboard to the IMLAC.

Lastly, we intend to investigate the use of TICCIT display devices

with the TIP.  A sample mathematics course will be designed to assist

in demonstration of the CAI applications of the Culler-Fried system.

We are currently studying the past uses of the system in a CAI mode.

     We have not yet investigated computer science curriculums.  We

plan to get inputs from the ACM Committee on Computer Science Educa-

tion(36,37) and to visit universities in the Washington area.  This

activity is scheduled to commence in April.

     (b)  Demonstrate that the TICCIT/CAI system can be supplemented
          with specialized CAI systems that use AI techniques.

The two network resources selected for demonstration are SCHOLAR and

LOGO.  Both systems are implemented in LISP and are currently avail-

able over the network on the TENEX system at BBN.  A version of LOGO

with a "display turtle" is available on the PDP-10 at MIT/AI, however,

they do not yet have their NCP implemented and thus are not currently

accessible over the network. There is also a version of LOGO on the

TENEX system at SRI/AI. They also are not currently connected to the



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network and we have not investigated their version.

     We used SCHOLAR over the network in January with a data base

provided by BBN to review the knowledge of a student in the geography

of South America(38,39).

     The LOGO system at MIT/AI is perhaps the most impressive system

for use in a demonstration due to the availability of a "display

turtle". The system is currently being used remotely by the Bridge

School in Lexington, Massachusetts. We visited the school and observed

a class in session. We also attended an undergraduate class in Applied

Math at MIT that was learning turtle geometry.

     Seymour Papert of MIT expects the MIT/AI PDP-10 to be up on the

network by the middle of April(40). He has agreed to modify his system

to interface with our IMLAC via the network using the low-level graphics

protocol that we specified. He has developed many courses and games

using LOGO(41,42,43,44,45) that provide sufficient material for use

in demonstrating the system. A real turtle may be available in early

summer to run from our TIP.

     We have used the LOGO system at BBN via the network. Since the

system is continually being modified, Dr. Feurzeig agreed to put a

clean version on the RAND TENEX for our use. BBN's LOGO does not

currently have a display turtle, however, they are willing to imple-

ment one. Even without the display turtle, courseware that has been

developed for teaching mathematics provides sufficient material for

us to work from(46,47). A radio controlled turtle has been designed




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at BBN. It may be possible to obtain the specifications and have one

built at MITRE to run from our TIP.

     (c)  Demonstrate that TICCIT system resources and capabilities
          can be augmented by using computing and storage resources
          available on the network.

Work has not begun on this subtask.  However, much of the software

developed for the data sharing experiments can be used to store and

retrieve data on a demand basis.

     We have received preliminary curriculum material from TICCIT

personnel. We expect to interact with them to determine more speci-

fically the format and requirements for curriculum material and student

records.

       [ This RFC was put into machine readable form for entry ]
       [ into the online RFC archives by BBN Corp. under the   ]
       [ direction of Alex McKenzie.                   12/96   ]


























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REFERENCES

30.  Ewig, C. S., Gerig, J. T., and Harris, D. P., "An Interactive
     On-Line Computing System and Its Use in Chemistry Education",
     Department of Chemistry, UCSB.

31.  Howard, J. A., and Wood, R. C., "Computer Assisted Instruction
     in Engineering Using On-Line Computation", _Journal_of_Engineering_
     _Education_.

32.  Sullivan, J. J., "Computer Based Instruction in Economics: A
     Report on Facilities and Applications at UCSB", paper presented
     at a conference on Computers in Undergraduate Curricula,
     University of Iowa, Iowa City, Iowa, 1970.

33.  Wood, R. C., and Bruch, J. C., Jr., "Teaching Complex Variable
     with an Interactive Computer System", article submitted for
     review and publication in _IEEE_Transactions_on_Education_, July
     1970.

34.  Wood, R. C., and Howard, J. A., "An Interactive Computer Class-
     room, _Educational_Research_and_Methods_Journal_, Vol. 2, No. 4,
     June 1970, pp. 29-31.

35.  "UCSB On-Line System Manual", NIC #6502, September 1971.

36.  "Curriculum 68", _Communications_of_the_ACM_. Vol. 11. No. 3.
     March 1968, pp. 151-197.

37.  Teichroew, D., ed., "Education Related to the Use of Computers
     in Organizations", _Communications_of_the_ACM_, Vol. 14, No. 8,
     September 1971, pp. 573-588.

38.  Carbonell, Jaime R., "AI in CAI: An Artificial Intelligence
     Approach to Computer-Assisted Instruction", _IEEE_Transactions_
     _on_Man-Machine_Systems_, Vol. MMS-11, No. 4, December 1970,
     pp. 190-202.

39.  Carbonell, Jaime R., "Mixed-Initiative Man-Computer Instructional
     Dialogues", BBN Report No. 1971, 31 May 1970.

40.  Williams, R. W., "LOGO Manual", MIT/AI, Draft memo, 9 April 1971.

41.  Papert, S., and Solomon, C., "Twenty Things To Do with a Computer",
     MIT Artificial Intelligence Laboratory internal report, June 1971.

42.  Papert, S., "A Computer Laboratory for Elementary Schools",
     MIT/AI Memo No. 246, LOGO Memo No. 1, October 1971.



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43.  Papert, S., "Teaching Children Thinking", MIT/AI Memo No. 247,

     LOGO Memo No. 2, October 1971.

44.  Papert, S., "Teaching Children to be Mathematicians vs. Teaching
     About Mathematics", MIT/AI Memo No. 249, LOGO Memo No. 4,
     July 1971.

45.  Papert, S., and Solomon, C., "NIM: A Game-Playing Program",
     MIT/AI Memo No. 254, LOGO Memo No. 5, January 1970.

46.  INFORMATION PROCESSING MODELS AND COMPUTER AIDS FOR HUMAN
     PERFORMANCE

     Final Report, Section 3: Feurzeig, W., and Lukas, G., "Program-
     ming Languages as a Tool for Cognitive Research", BBN Report
     No. 2187, 30 June 1971.

47.  PROGRAMMING-LANGUAGES AS A CONCEPTUAL FRAMEWORK FOR TEACHING
     MATHEMATICS, BBN Report No. 2165, 30 June 1971.

          Volume 1, Part 1: Feurzeig, W., Lukas, G., "An Introductory
             LOGO Teaching Sequence".

             Part 2: Lukas, J. D., and Lukas, G., "LOGO
                Teaching Sequence on Logic".

             Part 3: Feurzeig, W., Lukas, G., and Grant, R.,
                "LOGO Reference Manual".

          Volume 2, Part 1: Grant, P., Falflick, P., and Feurzeig, W.,
             "LOGO Teaching Sequences on Numbers".

             Part 2: Feurzeig, W., Lukas, G., and Grant, R.,
                "LOGO Functions and Equations".

          Volume 3, Part 1: Lukas, G., Falflick, P., and Feurzeig, W.,
             "LOGO Strategy in Problem-Solving".

             Part 2: Lukas, G., and Feurzeig, W., "LOGO
                Story Problems in Algebra".

          Volume 4: Weiner, W. B., Morgan, C. R., and Feurzeig, W.,
             "The LOGO Processor, A Guide for System Programmers".







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