DATAMATH CALCULATOR MUSEUM |
Lloyd's Accumatic 30 (Model EH-9036-2, Type 255E)
Date of introduction: | January 1975 | Display technology: | Fluorescent |
New price: | Display size: | 8 + Sign | |
Size: | 5.8" x 3.5" x 1.25" 147 x 89 x 32 mm3 |
||
Weight: | 5.8 ounces, 164 grams | Serial No: | I6-22183 |
Batteries: | 4*AA | Date of manufacture: | mth 04 year 1975 |
AC-Adapter: | YA-7247 (120V AC), YA-7585 240V AC) | Origin of manufacture: | Taiwan |
Precision: | 8 | Integrated circuits: | NEC µPD940 |
Logic: | Chain | Displays: | Futaba 9-CT-08 |
Memories: | |||
Program steps: | Courtesy of: | Ken H. Meine | |
Download manual: | (US: 1.6M Bytes) |
The
Accumatic 30 calculator sold by Lloyd's Electronics, Inc.,
Compton, California caught our attention when we were looking into the first
single-chip calculator circuits manufactured by Sharp Electronics Corporation in
Japan, just to discover that this model number was used between 1974 and 1976
with at least 12 different calculator
designs sporting 4 different
calculator brains.
And
this Accumatic 30 in its Revision 255E does not look even close to its siblings,
the picture on the right shows it centered between an
Accumatic 30 (Type 255C)
and an Accumatic 30 (Type 255G), all three calculators manufactured between
February an September 1975. It is obvious that Lloyd's did not only change the
display from 8-digits to 9-digits, but even the keyboard from 19 keys to 22 keys.
Dismantling the featured Lloyd's Accumatic 30 (EH-9036-2, Type
255E) calculator assembled by an unknown Original
Equipment Manufacturer (OEM) in April 1975 in Taiwan reveals a very compact
design based on a single-sided printed circuit board (PCB) for the main
electronics, a single-sided PCB for the keyboard and powered by four disposable
1.5 Volts batteries or an external power adapter.
The
Main-PCB is centered around a µPD940
single-chip calculator circuit manufactured by NEC and the few other remaining components on the PCB are mainly used to
generate the different supply voltages for the µPD940 and Vacuum Fluorescent
Display (VFD) and to bias the anodes and grids of the display with respect to
its filament. The earlier Accumatic 30 (EH-9036, Type
255D) was using a Hitachi HD36290 chip
offering just the [%] function, while the µPD940 is including the [√x]
and [PI] functions, too. Lloyd's made in a first step use of the additional
function but still offered with the Accumatic 30
(Type 255G) a combination of the µPD940 and the original keyboard with just 19
keys.
To make things even more confusing, added the Product Manager of
the calculator with the Accumatic 30
(EH-9036, Type 260D) a version with the Hitachi chip and a version with the NEC
chip. If you enter this key sequence [2] [0] [x] [5] [%] → '1.', [+] [=] with
these two "identical" calculators, will one give a result of '21.' and the other
of '22.'!
To gain some knowledge about the differences
between the various single-chip calculator circuits used with the Lloyd's
Accumatic 30, we decided here at the Datamath Calculator Museum to give the featured calculator
a partial "Teardown Treatment" and share our findings accordingly.
Calculating Unit:
The µPD940 located in the featured calculator seems to be one of the first
"true" single-chip calculator circuits designed by NEC. It features an
integrated clock oscillator and both its segment and digit output drivers are
interfacing directly with low-voltage VFDs up to 35 Volts. Here at the Datamath
Calculator Museum we don't qualify NEC's earlier µPD271 as a true single-chip
calculator circuit, it is using with the µPD261 an external segment decoder and
driver chip for the calculator display.
Display: The
featured Lloyd's Accumatic 30 (EH-9036, Type 255G) calculator manufactured in
June 1975 makes use of an 9-Digit low-voltage VFD manufactured by Futaba and
known as Type 9-CT-08. The display is soldered with its 19 wires directly to the
Main-PCB.
Display Driver: The term "low-voltage" Vacuum Fluorescent Display might
be misleading when used together with a calculator powered by four 1.5 Volt
batteries. Common VFDs used with portable electronic calculators are usually
operated around 30 Volts, significantly higher than the 10 to 15 Volts operating
voltage of single-chip calculator circuits used in the 1970s. While the first
generation of Texas Instruments TMS0100 single-chip calculator circuits lacked
any display drivers and left the choice of display technology to their
customers, focused the second generation products mainly on Light-Emitting Diode
(LED) technology. In or around 1974, most Western calculator designs still
relied on rather expensive LED technology but Japanese companies like Casio,
Sanyo, Sharp and Toshiba started to leverage the lower manufacturing costs of
VFDs, instead. Texas Instruments introduced in 1974 consequently with the
TMS0850 their first product series focused on battery operated VFD calculators
and modified the integrated segment and digit output drivers to withstand up to
-35 Volts. NEC on the other hand entered the marked of single-chip calculator
circuits in 1973/1974 and focused immediately on compatibility with VFDs. The
µPD940 chips are manufactured in PMOS technology, meaning the
output transistors are "high-side" switching and the most positive voltage of
the chip is labeled VSS for 0 Volt, all other voltages in the
calculator are consequently negative with respect to VSS. Multiplexed
low-voltage VFDs need a voltage difference between its filament and the grids
and anodes of the numbers of around 30 Volts to light up and to avoid "ghosting"
while scanning, the deactivated grids and anodes should be slightly lower than
the filament voltage. An elegant and very common solution is found with this
Accumatic 30 calculator, too. The grids and anodes of the VFD are "pulled-down"
with 17 resistors (150k Ohm) to around -29 Volts, the filament is biased to
around -27 Volts (2.0k Ohm resistor) and the µPD940 switches the relevant grids
and anodes to around 0 Volt to lit them up.
Clock: The Lloyd's Accumatic 30 makes use of the internal clock
oscillator of the µPD940 Series of single-chip calculator circuits, we identified a resistor with
680k Ohm connected
between Pin 28 (CLK/REXT, CEXT) of the µPD940 and the negative
VGG power supply line and a capacitor with 56 pF, resulting in a
clock frequency of about 62 kHz.
Power Supply: The Lloyd's Accumatic 30 calculator is powered with
four disposable AA-sized 1.5 Volt batteries or an external 6 Volt power adapter and uses a
complex DC/DC converter to
generate a total of four voltages:
• VDD - Negative supply for
µPD940 (-6.0 V) • VGG - Negative supply for µPD940 (-11.5 V) • VPP - Negative supply for VFD anodes and grids (-29.3 V) • VFIL - AC supply for VFD Filament (2.5 V) |
We measured the operating current of the featured Lloyd's Accumatic 30 calculator for two different cases:
Mode | Display | Current VBAT = 6.0 V |
Clock Frequency |
Calculating | 0. | 27 mA | 62 kHz |
Calculating | 88888888. | 40 mA | 62 kHz |
Calculating the power consumption at 6 Volts for the Lloyd's Accumatic 30 results in about 160 mW displaying a '0.' and about 240 mW with all segments but the minus sign illuminated. A very interesting result, a Canon LE-84 calculator with a LED display and using four disposable 1.5 Volt Alkaline batteries and a DC/DC converter for its TMS0801 chip clocks in at around 100 mW displaying a '0.' and 320 mW with all segments lit; showing both an advantage and disadvantage of LED-based calculators versus their VFD-based counterparts:
• LED: Only illuminated segments draw current - advantage LED while displaying
'0.' • VFD: Filament uses always current, segment currents are almost negligible - advantage VFD while displaying '88888888.' |
Keyboard: The keyboard assembly of the
Lloyd's Accumatic 30 was manufactured by GICO and uses 22 spring-supported
plastic keys pushing small fingers on stamped sheet-metal pieces against
contacts etched on a single-sided phenolic PCB. The
keyboard module is connected with 10 pins to the Main-PCB, (6 keyboard scan lines,
4 keyboard return lines).
Here
at the Datamath Calculator Museum we use
the DCM-50A Platform to
Characterize and
Reverse-engineer
Single-chip Calculator Circuits. Many designs of electronic calculators do not
use all features of their calculator brains and it would be difficult to unleash
the full potential of the calculator chips in these cases. Additionally are
electronic calculators "closed systems" with limited flexibility to measure
signals, change voltages or clock frequencies, provide additional input keys or
even change the display technology or specifications additional digits. Core
idea of the DCM-50A is providing a generic platform to access all features of a
single-chip calculator circuit and with the
DCM-50A (PLAYGROUND) we
increased the scope from Texas Instruments products to offerings from their
competitors in the 1970s, namely AMI, Cal-Tex, Commodore/MOS Technology,
Electronic Arrays, General Instrument, Hitachi, Litronix, Matsushita, Mitsubishi, Mostek,
National Semiconductor, NEC, Omron, RFT, Rockwell, Sharp, Toshiba, and Western
Digital.
The Accumatic
30 sold by Lloyd's mid of the Seventies went through many redesigns within its
lifecycle of around 2 years and we started to look into the differences of the
four different single-chip calculator circuits located in at least 12 different
design iterations. Learn more about our observations
here.
If you have additions to the above article please email: joerg@datamath.org.
© Joerg Woerner, November 15, 2024. No reprints without written permission.