The LGP-30, standing for Librascope General Purpose and then Librascope General Precision, is an early off-the-shelf computer. It was manufactured by the Librascope company of Glendale, California (a division of General Precision Inc.), and sold and serviced by the Royal Precision Electronic Computer Company, a joint venture with the Royal McBee division of the Royal Typewriter Company. The LGP-30 was first manufactured in 1956,[1][2][3] at a retail price of $47,000, equivalent to $530,000 in 2023.[4]

Librascope LGP-30
An LGP-30 in use at Manhattan College in 1965
LGP-30 at The Computer Museum, Boston with cover removed. Control panel is at top center, to the left of the memory drum.

The LGP-30 was commonly referred to as a desk computer. Its height, width, and depth, excluding the typewriter shelf, was 33 by 44 by 26 inches (84 by 112 by 66 cm). It weighed about 800 pounds (360 kg),[5] and was mounted on sturdy casters which facilitated moving the unit.

Design

edit
 
The LGP-30 control panel
 
German control panel

The primary design consultant for the Librascope computer was Stan Frankel, a Manhattan Project veteran and one of the first programmers of ENIAC. He designed a usable computer with a minimal amount of hardware.[6] The single address instruction set had only 16 commands. Magnetic drum memory held the main memory, and the central processing unit (CPU) processor registers, timing information, and the master bit clock, each on a dedicated track. The number of vacuum tubes was minimized by using solid-state diode logic, a bit-serial architecture[7] and multiple use of each of the 15 flip-flops.

It was a binary, 31-bit word computer with a 4096-word drum memory. Standard inputs were the Flexowriter keyboard and paper tape (ten six-bit characters/second). The standard output was the Flexowriter printer (typewriter, working at 10 characters/second). An optional higher-speed paper tape reader and punch was available as a separate peripheral.

 
Console typewriter of an LGP-30 at the Computer History Museum. Note that, as was common in typewriters of the time, there is no key for the number 1 (lower case L was used instead).

The computer contained 113 electronic tubes and 1450 diodes. The tubes were mounted on 34 etched circuit pluggable cards which also contain associated components. The 34 cards were of only 12 different types. Card-extenders were available to permit dynamic testing of all machine functions. 680 of the 1450 diodes were mounted on one pluggable logic board.

The LGP-30 required 1500 watts operating under full load. The power inlet cord could plug into any standard 115 volt 60-cycle single-phase line. The computer incorporated voltage regulation suitable for powerline variation of 95 to 130 volts. In addition to power regulation, the computer also contained circuitry for a warm-up stage, which minimized thermal shock to the tubes to ensure longer life. The computer contained a cooling fan which directed filtered air through ducts to the tubes and diodes, to extend component life and ensure proper operation. No expensive air conditioning was necessary if the LGP-30 was operated at reasonable temperatures.

There were 32 bit locations per drum word, but only 31 were used, permitting a "restoration of magnetic flux in the head" at the 32nd bit time. Since there was only one address per instruction, a method was needed to optimize allocation of operands. Otherwise, each instruction would wait a complete drum (or disk) revolution each time a data reference was made. The LGP-30 provided for operand-location optimization by interleaving the logical addresses on the drum so that two adjacent addresses (e.g., 00 and 01) were separated by nine physical locations. These spaces allowed for operands to be located next to the instructions which use them. There were 64 tracks, each with 64 words (sectors). The time between two adjacent physical words was about 0.260 millisecond (ms), and the time between two adjacent addresses was 9 x 0.260 or 2.340 ms. The worst-case access time was 16.66 ms.

Half of the instruction (15 bits) was unused. The unused half could have been used for extra instructions, indexing, indirect addressing, or a second ( 1) address to locate the next instruction, each of which would have increased program performance. None of these features were implemented in the LGP-30, but some were realized in its 1960 successor, the RPC-4000.

 
The LGP-30 register display, which used an oscilloscope behind this mask.

A unique feature of the LGP-30 was its built-in multiplication, despite being an inexpensive computer. Since this was a drum computer, bits were processed serially as they were read from the drum. As it did each of the additions associated with the multiplication, it effectively shifted the operand right, acting as if the binary point were on the left side of the word, as opposed to the right side as on most other computers. The divide operation worked similarly.

To further reduce costs, the traditional front panel lights showing internal registers were absent. Instead, Librascope mounted a small oscilloscope on the front panel that displayed the output from the three register read heads, one above the other, allowing the operator to see and read the bits. Horizontal and vertical size controls let the operator adjust the display to match a plastic overlay engraved with the bit numbers. To read bits the operator counted the up- and down-transitions of the oscilloscope trace.

Unlike other computers of its day, internal data was represented in hexadecimal instead of octal, but being a very inexpensive machine it used the physical typewriter keys that correspond to positions 10 to 15 in the type basket for the six non-decimal characters (as opposed to the now normal A – F) to represent those values, resulting in 0 – 9 f g j k q w, which was remembered using the phrase "FiberGlass Javelins Kill Quite Well".

Specifications

edit
 
A look inside the LGP-30 at the Stuttgart Computer Museum. Drum memory is on the left, CPU on the right.
 
LGP-30 drum memory
  • Word length: 31 bits, including a sign bit, but no blank spacer bit
  • Memory size: 4096 words
  • Speed: 0.260 milliseconds access time between two adjacent physical words; access times between two adjacent addresses 2.340 milliseconds.
  • Addition time: 0.26 ms excluding access time
  • Multiplication or division time: 17 ms excluding access time
  • Clock rate: 120 kHz
  • Power consumption: 1500 Watts
  • Heat dissipation: 5,000 BTU/h (1,500 W)
  • Arithmetic element: three working registers: C the counter register, R the instruction register and A the accumulator register.
  • Instruction format: Sixteen instructions using half-word format
  • Technology: 113 vacuum tubes and 1350 diodes.
  • Number produced; 320~493
  • First delivery: September 1956
  • Price: $47,000
  • Successor: LGP-21
  • Achievements: The LGP-30 was one of the first desk-sized computers offering small-scale scientific computing. The LGP-30 was fairly popular with "half a thousand" units sold, including one to Dartmouth College where students implemented Dartmouth ALGOL 30 and DOPE (Dartmouth Oversimplified Programming Experiment) on the machine.

Programming

edit

Instruction set

edit

The LGP-30 has 16 instructions. Each instruction occupies a 31-bit word though about half the bits are unused and set to zero. An instruction consists of an "order" such as the letter b for "bring from memory" and an address part such as the number 2000 to designate a memory location. All instructions have a similar appearance in an LGP-30 word. The order bits occupy positions 12 through 15 of the word and the address bits occupy positions 18 through 29 of the word. The address bits are further divided by track and sector. Although all instructions have an address, some do not use the address. It is customary to enter an address of 0000 in these instructions.[8]

00 11 12 15 16 17 18 23 24 29 30
000000000000 Order 00 Track Sector 0
Example Order Operation
b 2000 0001 Bring from Memory: Replace the contents of the accumulator with the contents of memory location 2000. The contents of memory location 2000 is unaffected.
h 2000 1100 Hold and Store: Replace the contents of memory location 2000 with the contents of the accumulator. The contents of the accumulator is unaffected.
c 2000 1101 Clear and Store: Replace the contents of memory location 2000 with the contents of the accumulator and replace the contents of the accumulator with zero.
y 2000 0010 Store Address: Replace the contents of the address portion of the word in memory location 2000 with the contents of the address portion of the word in the accumulator. The contents of the accumulator is unaffected. The LGP-30 has no index register. Y can be used to self-modify code to index an array.
u 2000 1010 Unconditional transfer: Replace the number in the (program) counter register with the contents of the address portion of the unconditional transfer instruction.
r 2000 0011 Return address: Add one to the contents of the (program) counter register and replace the address portion of memory location 2000 with the contents of the counter register. This instruction is used to patch an unconditional transfer instruction at the end of a subroutine to direct it to return to the caller. R is followed immediately with a branch instruction to the beginning of the subroutine. R can also be used to patch a Test instruction to create a conditional return.
t 2000 1011 Test: (Conditional transfer) If a one is in the sign bit of the word in the accumulator, the test instruction has the effect of an unconditional transfer. If a zero is in the sign bit of the word in the accumulator, the next following instruction in normal sequence is executed.
z 0000 0000 Stop: Stop computation. If computation is to stop, the address portion of the stop instruction is usually of no significance. However, the stop order has a special characteristic. If there is a one in the third bit from the right hand end of the track portion of a stop instruction, computation does not stop if break point switch 4 on the console of the computer is depressed. Four break point switches are supported by the z instruction.
p 2000 1000 Print: Execute the typewriter keyboard function indicated by the 6 track bits. The print order has no effect on the contents of any memory location, the accumulator, or the counter register. For example, p 2000 has 010100 in the track bits which is the code for a back space on the typewriter. The execution of p 2000 results in the typewriter back spacing.
i 0000 0100 Input: The address portion of the instruction constructed from this order is always 0000. It is always preceded by the instruction p 0000. After a p 0000 instruction starts the tape reader, an i 0000 instruction transfers into the last 4 bit positions of the accumulator the first 4 bits of the typewriter code for the first character read on the tape. When the second character is read, the bits representing the first character are shifted left into the next to last four bit positions of the accumulator and the first four bits of the typewriter code of the second character on tape are placed in the last four bit positions of the accumulator. This process continues up to eight times to fill the entire accumulator until a stop code (100000) appears on the tape. The stop code stops the tape reader and sends a start signal to the computer so that the instruction following i 0000 in memory is executed. Often this next instruction is a h or c instruction so that the characters read into the accumulator can be stored in some memory location.
a 2000 1110 Add: Add the contents of memory location 2000 to the contents of the accumulator and place the result in the accumulator. The contents of memory location 2000 is unaffected.
s 2000 1111 Subtract: Subtract the contents of memory location 2000 from the contents of the accumulator and place the result in the accumulator. The contents of memory location 2000 is unaffected.
m 2000 0111 Multiply upper: Multiply the number in the accumulator by the number in memory location 2000 and place the most significant thirty bits of the product in the accumulator. The contents of memory location 2000 is unaffected.
n 2000 0110 Multiply lower: Multiply the number in the accumulator by the number in memory location 2000 and place the least significant thirty-one magnitude bits of the product in the sign bit and thirty magnitude bits of the accumulator. The contents of memory location 2000 is unaffected.
d 2000 0101 Divide: Divide the number in the accumulator by the number in memory location 2000 and place the quotient rounded to thirty bits in the accumulator. The contents of memory location 2000 is unaffected.
e 2000 1001 Extract: Place zeroes in the word in the accumulator wherever there are zeroes in location 2000 but otherwise leave the word in the accumulator unchanged. The contents of location 2000 is unaffected. This is the equivalent of an AND instruction on most computers.

ACT-III programming language

edit

The LGP-30 had a high-level language called ACT-III. Every token had to be delimited by an apostrophe, making it hard to read and even harder to prepare tapes:[9]

s1'dim'a'500'm'500'q'500''
index'j'j 1'j-1''
daprt'e'n't'e'r' 'd'a't'a''cr''
rdxit's35''
s2'iread'm'1''iread'q'1''iread'd''iread'n''
1';'j''
0'flo'd';'d.''
s3'sqrt'd.';'sqrd.''
1'unflo'sqrd.'i/'10';'sqrd''
2010'print'sqrd.''2000'iprt'sqrd''cr''cr''
...

ALGOL 30

edit

Dartmouth College developed two implementations of ALGOL 60 for the LGP-30. Dartmouth ALGOL 30 was a three-pass system (compiler, loader, and interpreter) that provided almost all features of ALGOL except those requiring run-time storage allocation. SCALP, a Self Contained Algol Processor, was a one-pass system for a small subset of ALGOL (no blocks other than the entire program), no procedure declarations, conditional statements but no conditional expressions, no constructs other than while in a for statement, no nested switch declarations (nested calls are permitted), and no boolean variables and operators. As in ACT-III, every token had to be separated by an apostrophe.[10]

DICTATOR

edit

DICTATOR is a painful acronym for DODCO Interpretive Code for Three Address with Technical Optimum Range. DICTATOR, introduced in 1959, is an interpreter designed to hide the LGP-30 machine details from the programmer. The programming language resembles three-operand assembly code with two source operands and one destination operand. All numbers are in floating point with an eight digit mantissa and two digit exponent. Natural logs and exponents are supported along with sin, cos, and arctan. Up to four nested loops are supported. Table look-up and block memory move operations are implemented. A bit more than half the total LGP-30 memory is used by the interpreter; it takes about 30 minutes to load the paper tape via the Flexowriter. Floating point add, subtract, multiply, and divide take less than 455 milliseconds each. Cosine is calculated in 740 milliseconds.[11]

Starting the machine

edit

The procedure for starting, or "booting" the LGP-30 was complicated. First, the bootstrap paper tape was snapped into the console typewriter, a Friden Flexowriter. The operator pressed a lever on the Flexowriter to read an address field and pressed a button on the front panel to transfer the address into a computer register. Then the lever on the Flexowriter was pressed to read the data field and three more buttons were pressed on the front panel to store it at the specified address. This process was repeated, maybe six to eight times, and a rhythm was developed:

burrrp, clunk, 
burrrp, clunk, clunk, clunk, 
burrrp, clunk, 
burrrp, clunk, clunk, clunk,
burrrp, clunk, 
burrrp, clunk, clunk, clunk, 
burrrp, clunk, 
burrrp, clunk, clunk, clunk, 
burrrp, clunk, 
burrrp, clunk, clunk, clunk, 
burrrp, clunk, 
burrrp, clunk, clunk, clunk.

The operator then removed the bootstrap tape, snapped in the tape containing the regular loader, carefully arranging it so it would not jam, and pressed a few more buttons to start up the bootstrap program. Once the regular loader was in, the computer was ready to read in a program tape. The regular loader read a more compact format tape than the bootstrap loader. Each block began with a starting address so the tape could be rewound and retried if an error occurred. If any mistakes were made in the process, or if the program crashed and damaged the loader program, the process had to be restarted from the beginning.[12]

LGP-21

edit

In 1963,[13] Librascope produced a transistorized update to the LGP-30 named the LGP-21.[14][15] The new computer had about 460 transistors and about 375 diodes. It cost only $16,250, one-third the price of its predecessor. However, it was also about one-third as fast as the earlier computer.

The central computer weighed about 90 pounds (41 kg),[16] the basic system (including printer and stands) about 155 pounds (70 kg).[17]

RPC 4000

edit

Another, more-powerful successor machine, was the General Precision RPC 4000, announced in 1960.[18] Similar to the LGP-30, but transistorized, it featured 8,008 32-bit words of memory drum storage. It had 500 transistors and 4,500 diodes, sold for $87,500 and weighed 500 pounds (230 kg).[19][20][21]

Notable uses

edit

Edward Lorenz used the LGP-30 in his attempt to model changing weather patterns. His discovery that massive differences in forecast could derive from tiny differences in initial data led to him coining the terms strange attractor and butterfly effect, core concepts in chaos theory.[22] The RPC-4000 (successor to the LGP-30) is also remembered as the computer on which Mel Kaye performed a legendary programming task in machine code, retold by Ed Nather in the hacker epic The Story of Mel.[23]

Simulation

edit

A software simulation of the LGP-30 and LGP-21 are supported by SIMH, a free and open source, multi-platform multi-system emulator.

See also

edit

Further reading

edit
  • Kaisler, Stephen H. (2017). "Chapter Two – Royal McBee/Librascope Machines". Birthing the Computer: From Drums to Cores. Cambridge Scholars Publishing. LGP-30: pp. 25-34, LGP-21: pp. 34-43. ISBN 9781443896252.
  • "RPC 4000, LGP 30" (PDF). AUERBACH Standard EDP Reports. 3. RPC-4000: pp. 570-649; LGP-30: pp. 651-741.

References

edit
  1. ^ "1950-1959 Librazettes". www.librascopememories.com. Librazette: July, 1956 – Royal Precision Plans – LGP-30 Promotion; November, 1956 – LGP-30, Flow Computer Spearhead – Commercial Sales and Production – They're In Production and Paul Coates Will Feature LGP-30 on Dec. TVshows. 1956. Retrieved 2018-03-19.{{cite web}}: CS1 maint: others (link)
  2. ^ Flamm, Kenneth (2010-12-01). Creating the Computer: Government, Industry and High Technology. Abstract of Computer Oral History Collection, 1969-1973, 1977, p. 75. Brookings Institution Press. p. 66. ISBN 978-0815707219.
  3. ^ "Strand v. Librascope, Incorporated, 197 F. Supp. 743 (E.D. Mich. 1961)". Justia Law. Retrieved 2018-03-20. In November, 1955, (...) two important events occurred. The LGP-30 computer, containing seven MH-10R heads, failed to function correctly at the International Automation Exhibition in Chicago on November 15, 1955. In fact, an LGP-30 computer did not work satisfactorily until March, 1956, and the computer was not offered for sale to the general public until the fall of 1956.
  4. ^ 1634–1699: McCusker, J. J. (1997). How Much Is That in Real Money? A Historical Price Index for Use as a Deflator of Money Values in the Economy of the United States: Addenda et Corrigenda (PDF). American Antiquarian Society. 1700–1799: McCusker, J. J. (1992). How Much Is That in Real Money? A Historical Price Index for Use as a Deflator of Money Values in the Economy of the United States (PDF). American Antiquarian Society. 1800–present: Federal Reserve Bank of Minneapolis. "Consumer Price Index (estimate) 1800–". Retrieved February 29, 2024.
  5. ^ Weik, Martin H. (January 1964). "LGP 30". ed-thelen.org. A Fourth Survey of Domestic Electronic Digital Computing Systems.
  6. ^ Frankel, Stanly P. (1957). "The Logical Design of a Simple General Purpose Computer". IRE Transactions on Electronic Computers. EC-6 (1): 5–14. doi:10.1109/TEC.1957.5221555.
  7. ^ Miller, Raymond E. (1965). Switching Theory – Volume 1: Combinational Circuits. Vol. 1 (Second printing, March 1966, of 1st ed.). John Wiley & Sons, Inc. pp. 44–47. LCCN 65-14249.
  8. ^ Royal Precision Electronic Computer LGP - 30 Programming Manual. Port Chester, New York: Royal Precision. April 1957. Retrieved 19 November 2023.   This article incorporates text from this source, which is in the public domain.
  9. ^ File:ACT III program.agr.jpg
  10. ^ Stephen J. Garland, Robert F. Hargaraves, Anthony W. Knapp, Jorge Llacer (15 February 1962). Algol for the LGP-30 (PDF). Computation Center, Dartmouth College. Retrieved 5 February 2024.{{cite book}}: CS1 maint: multiple names: authors list (link)
  11. ^ Laudeman, Charles (October 6, 1959). DODCO Interpretive Code for Three Address with Technical Optimum Range (PDF). LGP-30 Users' Organization-Pool. Retrieved 20 November 2023.
  12. ^ Reinhold, Arnold. "Act-III and booting sections". Computer History. (NB. With permission under GFDL and CC-BY-SA 3.0).
  13. ^ "1960-1969 Librazettes". www.librascopememories.com. May, 1963 Librazette: LGP-21 Is Selling Well – p. 4, See Page Eight ad – pp. 7-8.
  14. ^ Picture with description of computer parts: "1963 Pictorial Report on the Computer Field: Digital Computers – LGP-21" (PDF). Computers and Automation. XII (12): 29. Dec 1963. Retrieved 2020-09-05.
  15. ^ "Across the Editor's Desk: Computing and Data Processing Newsletter – "Doorstep" Era in Computer Marketing Heralded". Computers and Automation: 62. May 1964.
  16. ^ Weik, Martin H. (Jan 1964). "LGP 21". ed-thelen.org. A Fourth Survey of Domestic Electronic Digital Computing Systems.
  17. ^ "WPS:LGP 21:Documentation". sr-ix.com. LGP-21 Sales Brochure (G3-3101): p. 7.
  18. ^ "The LGP-30's big brother · e-basteln". www.e-basteln.de.
  19. ^ 900 pounds (410 kg) according to
  20. ^ BRL Report. 1964.
  21. ^ "RPC-4000 Electronic Computing System". Computers and Automation: 4B (20). May 1960.
  22. ^ Gleick, James (1987). Chaos: Making a New Science.
  23. ^ "Story of Mel".
edit
  • November, 1955 Librascope’s Amazing New General Purpose Computer Put On Market
  • December, 1955 LGP-30 Wins Wide Acclaim At Chicago Automation Show
  • July, 1956 Royal Precision Plans – LGP-30 Promotion
  • March, 1957 Librascope's Commercial Division Does Outstanding Job on LGP-30 Production