DESIGNED AND BUILT THIS FOR LAB USE A FEW YEARS AGO
The 1053 attaches to a mainframe with three SMS paddle cards - two carry signals and the third delivers power. This emulator is built around an Arduino Mega 2560 R3, a MOSFET switching board and some simple circuitry, hooked to three SMS paddle cards. It provides a serial port connection over a USB cable for communicating with a terminal emulator program on a personal computer to display the output that is being 'typed' by the mainframe.
This emulates the console typeball that is installed on an IBM 1130 system, but can be easily modified to support a different (or additional) typeballs. The typeball has characters that are not in standard ASCII, e.g. ¬ and ¢ which can be displayed in UTF8.
Using a terminal emulator that supports UTF8 encoding and ANSI colors provides the most realistic output, since the text will display in either black or red on white background - the text color is selectable by ribbon shift commands from the mainframe to the 1053. I have had good results with The terminal emulator PUTTY, set for 9600 baud. The code offers a few commands that can be issued to the PC1053 - mainly to set the left and right margins, but also to set, clear and display tab stop columns that will be in effect.
PC1053 operates at approximately the same timing as a 1053, which supported a maximum of 15.5 characters per second and with the high speed carrier return feature would move from right to left edge in just a bit over 1 second. This provides realistic timing on the feedback signals that tell the mainframe when the Selectric mechanism is busy in a print cycle or performing an operation such as shifting case or moving to a new line.
The device is constructed in a case with a three digit display to show the current column that the typeball/carrier has reached. It has buttons on the front to match the controls on a real 1053 - buttons to Tab, Space and Return, plus tab Set and Clear. This project has a Fritzing diagram of the connections, a schematic of the MOSFET switch board and other circuits, while the physical layout of the case is left as an exercise for the reader.
TESTING THE 1053 EMULATOR
I connected the 1053 Emulator to the VCF 1130 to check out its operating condition before loaning it to the System Source Museum. The one challenge I had was that my emulator had two male SMS paddle cables for signals, but the 1053 itself has one male and one female card. Thus I needed to use a Female to Female adapter from my own 1053 just to complete the testing. I tested the signal connections to be sure that the pad reversal of the adapter wasn't crossing signals; soon I had everything connected between emulator and 1130 according to the design.
FOUND A FEW FLAWS
Immediately I found that the END OF FORMS lamp on the console was lit, which makes the typewriter not ready for operation. The controller logic inside the 1130 won't work properly with that error state. My emulator should tell the controller that forms are good, thus ready for printing.
I began testing anyway since I saw that my little hand program to write to the console printer was seeing the print codes when I did an XIO Write. The controller hangs up after the first write - must be an issue with the response signals back to the 1130, but it could also be due to the forms error condition.
I saw the proper characters on the terminal screen for all the letters, numerals and special characters on the lower case hemisphere of the typeball. Any time I entered a code on the upper case side, the controller fired off a shift command which failed to complete, thus it would not type any character on that side.
I felt good about the translation and display of the characters, even the cents sign which is not part of normal ASCII but is being displayed using UTF-8 unicode encoding of the characters. The column pointer was advancing properly, showing where the carrier would be sitting if it were a real printer.
Space, backspace, line feed (new line) and tab seemed to work just fine. When I issued a carriage return command, which should also be triggering a line feed, I only saw the cursor return to the beginning of the same line. This happens even when I push the Return button on the emulated printer console (actually on my emulator box). I suspect this is a simple flaw in my Arduino code inside the emulator.
I tried the commands to shift to red ink and shift to black ink, but the output on the terminal did not change. This may be a remnant of the issue caused the the forms error, but it could also be a defect in my code. I do remember this working properly on the bench, so it could also be a flaw in detecting the shift to xxx ink commands.
DEBUGGING THE FORMS LIGHT ISSUE AND LACK OF FEEDBACK SIGNALS
The hidden analog circuits inside the IBM 1130 logic cards were the reason that my MOSFET switched feedback signals including end of forms were not working as expected. IBM debounces these with a circuit that pulls the +12V line down to -3V, with resistors in that circuit acting as a voltage divider, so that without the 12V applied, the line will activate the next logic gate.
My problem was the 4.7K pullup resistor in my circuit - the line from the emulator to the 1130 passes through a 470 ohm resistor before entering the debouncer (voltage divider) and the result was always seen as a logic low by the following 1130 gates. Switching my resistor to a 470 ohm pullup gave me exactly the results I wanted. The forms condition went away.
I have to make similar changes to the other three MOSFET switch circuits in order to be recognized by the 1130 debouncers and ensuing logic gates as validly high or low. Once the controller triggers a set of solenoids in the 1053, it expects to see the two feedback signals change (-TWR CB RESPONSE and +TWR CRLFT INLK).
-TWR CB RESPONSE should dip from +48V to ground for any print or operations cycle, except for the commands to change the ribbon use between black and red ink stripes. If my signals don't return to logical high then the controller believes the typewriter mechanism is stalled and won't continue.
+TWR CRLFT INLK will rise from logic low to logic high with +12V delivered during the times that a carrier return, a line feed or a tab movement are underway. Due to the high resistors I used, it will never be seen as reaching the high state, nor will the other feedback signal.
Its a fairly trivial rework of the MOSFET switch board. The new 470 ohm resistors will consume about 300 milliwatts of power if steadily on, for the three signals that switch between 12V and ground. The 48V signal, with a 470 ohm resistor, would consume 5W when the output needs to be at ground level.
That only occurs during a cycle, when typing or moving, otherwise relatively little power required. During times of rapid typing the average power use will be about 2 1/4 Watts maximum, although if the typewriter mechanism stalls or jams it could jump up to the full 5W for some time. I will make use of a suitable high power resistor.
FIXED THE FAILURE TO MOVE THE LINE DOWN DURING A CARRIER RETURN
I simply forgot to print the 0x10 character (new line) after the 0x13 (carrier return) in the emulator code. It was added and corrected the problem.
BUILDING SMS ADAPTER HOUSING
I had built some SMS paddle card PCBs previously and realized that I could use one of them to create a female SMS socket to put onto my 1053 emulator in lieu of the male paddle card. What I needed was a housing to hold my male paddle card in place with room for another male card to be inserted parallel to the first. I would add some springy contacts soldered to the pads of the male paddle card, thus giving contact when the second male card is inserted into the housing.
I had to secure my own male card in the housing, so that we had a female socket with the combination of my male card and the housing. I fired up FreeCAD and designed a housing that could be 3D printed.
On challenge using the adapters is that the way IBM built them, they reverse the pads from one side to the other. Pad A on one side is pad R on the other, pad B is pad Q, and so forth. This can be confusing when dealing with signals on the two paddle cards being joined.
