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Hardware Meets Software CPSC 120 Principles of Computer Science February 15, 2012.

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Presentation on theme: "Hardware Meets Software CPSC 120 Principles of Computer Science February 15, 2012."— Presentation transcript:

1 Hardware Meets Software CPSC 120 Principles of Computer Science February 15, 2012

2 Quick Reminder: Programming as Encoding  Recall we write computer programs in high level languages such as PBASIC, Java, C++, etc.  These commands are checked for correct spelling and use by a syntax checker  If acceptable, our program is translated into machine specific code by a compiler  This object code or machine code is downloaded to our target device, such as BS2, usually by serial cable or wireless link  This machine code is stored in RAM then fetched, decoded and executed one instruction after another until the program exits

3 Ideal view of the programming process. What is missing is the design phase and the edit-run-test-edit loop of revision and testing.

4 Basic Stamp Editor: An Integrated Development Environment (IDE)

5 Communication Channels  Notice we communicate with our BS2 through a serial link. One character after another sent along a wire. Examples are USB (Universal Serial Bus) and old fashioned RS-232.  Bits in serial mode are encoded as voltage up or down, a pulse, during a short time interval.  This compares to parallel mode of having 8 or more wires in a cable. Ex. Older printers.  ASCII code (American Standard Code for Information Interchange)is used to encode letters, digits, and control characters.  Basic unit is 8 bits called a byte to encode a character. There are 256 possible characters.  Unicode is a more modern extension of ASCII.

6 ASCII Code Chart

7 Integrated Circuits Our CPU and RAM are manufactured as integrated circuits. The metal tabs are called pins and allow communication between the IC and connected circuits. The high/low or Vdd/Vss values of certain pins can be set/controlled by our programs! Pin voltage can be read by our programs and thus allow our program to react accordingly. This is programmer controlled input/output or programmed I/O.

8 Controlling Input/Output Pins  Input/output pins on the Basic Stamp 2 IC are brought out to and are numbered on our BOE board for access via the breadboard.  BS2 has 16 I/O pins available via BOE, labeled P0, P1, P2, …, P14, P15, we can use to read/write values.  A TRUE/HIGH value on a pin means +5 volts (Vdd), a FALSE/LOW value means 0 volts (Vss).  Using program control, we can turn an LED on/off if we set up such a circuit on our breadboard connected to BS2 correctly!  As we can read pin values, we can also build sensor circuits on our breadboard so our robot will be smarter.

9 Creating a PBASIC program to control PIN values Here is our hardware arrangement with the resistors and LEDs controlled from pins P12 and P13 on the BOE

10 ' Robotics with the Boe-Bot – HighLowLed.bs2 ' Turn the LED connected to P13 on/off once every second. ' Programmer: John Doe ' Date Created: 9/20/2007 ' Last modified: 2/15/2012 ' {$STAMP BS2} ' {$PBASIC 2.5} DEBUG "The LED connected to Pin 13 is blinking!" DO ' Beginning of loop HIGH 13 ' Set pin 13 high PAUSE 500 ' Pause for 500 milliseconds LOW 13 ' Set pin 13 low PAUSE 500 ' Pause again for 500 milliseconds LOOP ' End of loop A simple PBASIC program to blink an LED

11 Controlling Servo Motors  Servo motors are electric motors controlled by digital signals, perfect for use with microcontrollers such as BS2  Servo motors have three attached wires: power (+6V), ground, and control  Servo motors rotate left or right depending on the width of a pulse on the control wire  The duration of a servo pulse is about 1.5 thousands of a second. 1.5 milliseconds!  We have library commands in our PBASIC language to generate such very short pulses  Using two servos, we can drive a robot around!

12 Servo motors attached to the Homework Board, our BOE-BOT connection is similar but easier!

13 ' Robotics with the Boe-Bot - CenterServoP13.bs2 ' This program sends 1.5 ms pulses to the servo connected to ' P13 for servo centering. See BOE-BOT manual for details. ' Programmer: John Doe ' Date Created: 9/21/07 ' Date Modified: 9/24/07 ' {$STAMP BS2} ' {$PBASIC 2.5} DEBUG "Program Running!" DO PULSOUT 13, 750 ' Send centering pulse to pin 13 PAUSE 20 ' Wait 20 milliseconds LOOP A PBASIC program to test centering of a servo attached to BOE

14 Review of Common Prefixes from SI Here are some standard prefix modifiers for multiples of number values: Deca: means 10. Ex. A geometric decagon has 10 sides. Kilo: means 1000 = 10 3. Ex. A kilometer is 1000 meters. Mega: means 1,000,000 = 10 6. Ex. A megabye of RAM is (about) one million bytes. [Actually it is 2 20 = 1,048,576 in binary] Giga: means 1,000,000,000 = 10 9. Ex. A gigabyte of disk storage is (about) one billion bytes of storage space. [2 30 in binary] Other prefixes are used for fractions: Deci: means 1/10. Ex. To decimate is to destroy 1/10, also decimal. Centi: means 1/100 = 1 x 10 -2. Ex. Centimeter = 1/100 of a meter. Milli: means 1/1000 = 1 x 10 -3. Ex. A millisecond is 1/1000 of a second. Often denoted ms or msec. Micro: means 1/1,000,000 = 1 x 10 -6. Ex. A microsecond is 1 millionth of a second. Often denoted  sec. [Greek letter mu] Micro: means 1/1,000,000 = 1 x 10 -6. Ex. A microsecond is 1 millionth of a second. Often denoted  sec. [Greek letter mu]

15 Applications to PBASIC  We have seen how the DEBUG command acts like a mathematical function and takes arguments, the list of items to display. Ex. DEBUG CR, “Hello”, CR, “there!”  The PAUSE command takes one argument which is the number of milliseconds to simply wait, doing nothing.  PAUSE 500 ‘ Wait 1/2 second before continuing  The math: 1 ms x 500 = 500/1000 second = 1/2 second.  The PULSOUT command takes two arguments: A BS2 pin number and interval to create an up/down signal on that pin. However, the basic unit used is NOT milliseconds but 2 microseconds!  PULSOUT 12, 500 ‘ Create a pulse on pin 12 of 1 millisecond The math: 2  s x 500 = 1000  s = 1 millisecond.  So, this turns out to be exactly the kind of extremely short on/off interval we need to send to a servo motor to rotate in a particular direction.

16 ' Robotics with the Boe-Bot - CenterServoP13.bs2 ' This program sends 1.5 ms pulses to the servo connected to ' P13 for manual centering. See BOE-BOT manual for details. ' Programmer: John Doe ' Date Created: 9/21/07 ' Date Modified: 2/15/12 ' {$STAMP BS2} ' {$PBASIC 2.5} DEBUG "Program Running!" DO PULSOUT 13, 750 ' Send centering pulse to pin 13 PAUSE 20 ' Wait 20 milliseconds LOOP A PBASIC program to test centering of a servo attached to BOE

17 Variables in PBASIC  Variables are simply named memory locations we can use for arithmetic, control of loops, and storing sensor values. We choose the variable names!  You can declare four different types of variables in PBASIC:  Type Stores This Range of Number Values Bit 0 to 1 Nib 0 to 15 Byte 0 to 255 Word 0 to 65535 or -32768 to + 32767 We need to choose the appropriate variable type when we plan on storing values in the variable

18 Variable Use and Assignments Here are some variable declarations and assignments (with some errors). Notice that PBASIC is not case-sensitive. You can use either upper or lower case letters for your code. Some other languages do not allow this! ‘ Variable declarations begin here Counter VAR WORD ON_OFFVARBIT LetterVARBYTE ‘ Some simple assignments begin here LETTER = 32 Letter = -1 ON_OFF = 4 Counter = 25 Counter = Counter * 100 + LETTER DO Counter = Counter + 1 LOOP

19 Loops in PBASIC We can use several different types of looping constructions in PBASIC depending on what we need to do. ‘ Simple FOR…NEXT loop to drive a servo for about 1 second counter VARWord FOR counter = 1 TO 46 ‘ Iterate this loop 46 times PULSOUT 13, 850‘ Drive servo attached to pin 13 forward, 1.7 ms PAUSE 20 ‘ Do nothing for 20 ms NEXT ‘ Increment our counter variable, then top of loop PULSOUT 13, 750‘ Stop the servo by using the centering value This code “loops” or iterates through the two commands in the body of of the loop as the counter variable (started at 1) is automatically incremented by one each time through. When counter reaches 46, we do one last pass through the loop, then exit to go to the next PBASIC instruction.


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