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Canon LE-83 Panther

Date of introduction:  January 1974 Display technology:  LED-stick
New price:  $44.95 Display size:  8
Size:  6.1" x 2.9" x 1.0"
 154 x 74 x 25 mm3
    
Weight:  5.0 ounces, 142 grams Serial No:  312349
Batteries:  4*AA Alkaline Date of manufacture:  mth 03 year 1974
AC-Adapter:  Canon AD-1 Origin of manufacture:  Japan
Precision:  8  Integrated circuits:  TMS0101
Logic:  Chain Displays:  ROHM LAB-B-2/8
Memories:      
Program steps:   Courtesy of:  Joerg Woerner
    Download manual:   (US: 1.5M Bytes)

Canon introduced in January 1974 with the LE-83 their first calculator with an MSRP (Manufacturer's Suggested Retail Price) below $50. While we consider the LE-83 and its stablemates as members of the 4th generation of Canon's product portfolio of Battery-powered Handheld Calculators with LED display does it reuse with the TMS0101 single-chip calculator circuit some technology of the 2nd generation LE-80:

1st Generation: LE-10
2nd Generation: LE-80, LE-80M, LE-80R, LE-82
3rd Generation: LE-81M, LE-100, F-5, FC-80
4th Generation: LE-83, LE-84 and LE-85

With the MSRP of the LE-80 in 1973 still around $100, Canon's engineering team needed to dig deep into the cost-reduction toolbox while designing the $50 LE-83 and it shows! Canon decided to use with the TMS0701 the 2nd generation of the TMS0101 chip which allows to drive the segments of the LED display directly. Having the LED display in 1974 as the main cost driver of portable calculators, Canon opted for an 8-digit display and one additional discrete round LED for the minus sign instead the 9-digit display used with LE-80 but missed changing the code of the TMS0101. With the TMS0101 clearly developed for displays with a leading 9th digit and Canon using just a discrete LED to the right of the 1st digit instead a full character instead, the LE-83 expressed some strange behavior:

Negative numbers with 1 to 7 digits show a minus sign to the left of the number
Negative numbers with 8 digits show a minus "dot" to the right of the number
Overflow of the calculating result, displayed with the TMS0101 as or on the 9th digit isn't shown!

Canon's engineering team fixed this flaw with the LE-84 and LE-85 using two different approaches, consequently creating a rather divers portfolio:

Calculator Features Display Overflow
LE-83 [CONST] NONE
LE-84   FLASHING
LE-85 [sqrX][%±]  

Dismantling the featured Canon LE-83 Panther manufactured in March 1974 by Canon in Japan reveals a rather compact design with three printed circuit boards (PCBs) for main electronics, display, and keyboard powered by four disposable Alkaline batteries. The Main-PCB is centered around a Texas Instruments single-chip calculator circuit and supported by a myriad of discrete components:

Calculating Unit - TMS0101 (TMS0701) single-chip calculator circuit
Display Driver - No Segment Drivers and discrete Digit Drivers with two Transistor Arrays
Clock signal generation for TMS0101 with discrete components
Power converter with discrete components and transformer
17-pin connector to the Display-PCB (16 pins used)
20-pin connector to the Keyboard-PCB (18 pins used)

Calculating Unit: The LE-83 makes use of a 2nd generation TMS0101 single-chip calculator circuit, also known as TMS0701 and derived from the TMS1802, better known as first "calculator-on-a-chip".

Display: Texas Instruments introduced together with the TMS0100 calculator chip two pre-configured LED (Light-Emitting-Diode) modules (DIS40, DIS95) based on the TIL360 arrays and the corresponding segment drivers (SN75491) and digit drivers (SN75492). Most early 8-digit designs like the LE-80 made use of these parts exhibiting two disadvantages:

SN75491, SN75492 - Limited to designs with 5 or 6 batteries
TIL360 - Cost driver number one in the calculator design

Texas Instruments consequently introduced with the SN75493 and SN75494 revised display drivers optimized for designs with 3 or 4 batteries but the true innovation could be observed with the technology how to manufacture the 9-digit LED displays used with early four-function calculators:

1972: Two Hermetic Multi-Digit Calculator Numeric Seven-Segment LED Displays soldered onto a PCB
1973: Nine Seven-Segment LED Displays soldered onto a PCB
1974: Nine Seven-Segment LED Display Chips bonded onto a PCB
1975: Nine small Seven-Segment LED Display Chips bonded onto a PCB with additional magnifying lens
1976: LED Displays near extinguished by VFD and LCD technology

On the tireless, never ending quest to squeeze the last penny out of the manufacturing costs of electronic calculators, Canon used with the LE-83 four different LED display manufacturers and technologies. With more than a dozen of LE-83, LE-84 and LE-85 calculators examined, we understood that Canon marked the backside of the 4th Generation of Battery-powered Handheld Calculators accordingly, as of today we identified the following matrix:

Display
Technology
Label LE-83
RSEG - RDIG
LE-84
RSEG - RDIG
LE-85
RSEG - RDIG
ANTEX SK-3-307/8
COB with Ceramic Substrate
Magnifying Lens

51
Version 1
220 Ohm
5.6k Ohm
Version 1
390 Ohm
2.2k Ohm

- - -
Monsanto MAN-3A/8
7-Segment Displays on PCB
No Magnifying Lens

52
Version 2
82 Ohm
5.6k Ohm

- - -

- - -
ANTEX SK-2-151/8
COB with Ceramic Substrate
Magnifying Lens

53

- - -
Version 2
390 Ohm
2.2k Ohm

- - -
ROHM LAB-B-2/8
COB on PCB, No Mask
Magnifying Lens

54
Panther
220 Ohm
5.6k Ohm
Version 3
220 Ohm
2.2k Ohm

- - -
ROHM LAB-B-2/9
COB on PCB, No Mask
Magnifying Lens

54

- - -

- - -
Version 1
220 Ohm
2.2k Ohm
Litronix D-3034/8
COB on PCB, Gray Mask
Magnifying Lens

__
Version 3
220 Ohm
5.6k Ohm

- - -

- - -

Note: Here at the Datamath Calculator Museum we use a "Version Index" for the different display modules located in the Canon LE-83, LE-84 and LE-85 calculators based on the round paper stickers but couldn't find out the chronological order of them.

If your LE-83 uses resistors with a value of 2.2k Ohm instead of 5.6k Ohm as listed in the table above, your calculator was modified after April 1975 - Canon sent out a notice to their Service Partners to replace not only these resistors but even the digit driver transistors from 2N5449 to 2SC1641 in case the customers are complaining about a dim LED display. Learn more about the background of this modification.

The featured LE-83 Panther manufactured in March 1974 makes use of an ROHM LAB-B-2 8-Digit display module with eight 7-Segment displays chips bonded onto a PCB and magnified with a clear plastic lens. The display module is connected with 16 pins to the Main-PCB and follows the industry standard pinout of 9-Digit modules with the leftmost pin (Digit D9) unconnected. A small red LED with long leads is soldered directly onto the Main-PCB of the LE-83 Panther calculator and bended over the display module to act as Minus "dot" for 8-digit numbers.

Display Driver: The Main-PCB Main-PCB of the featured LE-83 Panther manufactured in March 1974 makes use of two Transistor Arrays TA1 and TA2 with four, respective five transistors bonded and encapsulated into a small module as Digit Drivers for the LED display while the TMS0701 chip drives the Segments directly. The layout of the PCB would support nine discrete Transistors instead of the two Transistor Arrays TA1 and TA2, too.

Clock: While the nominal clock frequency of the TMS0700 single-chip calculator circuit is specified with 250 kHz, uses the LE-83 a much slower pace to reduce overall power consumption of the product slightly. The astable multivibrator using two discrete transistors operates at a frequency between 100 kHz and 150 kHz, we observed with the featured LE-83 Panther manufactured in March 1974 a clock frequency of 132 kHz.

Power Supply: The LE-83 is powered by four disposable AA-sized 1.5 Volt batteries and can be operated with an external, DC adapter, too. The PCB of the calculator hosts a discrete power converter to generate the VDD and VGG supply voltages for the TMS0101 chip. To reduce power consumption of the calculator, the VGG voltage is pulsed with the clock frequency between VDD and its peak level. We observed with the featured calculator manufactured in May 1974 voltages of VDD = -6.5 V and VGG(pk) = -13.2 V while operated with VBAT = 6.0 V. The LED displays of the LE-83 are operated directly from the battery voltage and we measured the current consumption of the featured calculator with:

Mode Display Current
VBAT = 6.0 V
Clock Frequency
Calculating 0. 34 mA 132 kHz
Calculating 88888888. 66 mA 132 kHz

The power consumption for the featured Canon LE-83 Panther results in about 200 mW displaying a '0.' and 400 mW with all segments but the minus sign illuminated compared to the LE-84 (Display Version 3) sporting the same LED display with 130 mW and 490 mW, respectively.

Keyboard: The keyboard of the LE-83 Panther uses spring-supported plastic keys pushing a small conductive rubber element against two contacts etched on a single-sided phenolic PCB combining both long-travel keys with reasonable manufacturing costs while maintaining longevity of the calculator. The keyboard module is connected with a short 18-pin flat-cable to the Main-PCB.

The LE-83, LE-84, and LE-85 introduced in 1974 marked the last generation of calculators with LED displays in Canon's portfolio of Portable Handheld Calculators and the next products named Panther D and LD-80 were sporting a green VFD (Vacuum-Fluorescent-Display) instead.


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If you have additions to the above article please email: joerg@datamath.org.

© Joerg Woerner, December 5, 2001. No reprints without written permission.