Variables: Constants Flashcards

1
Q

The two constants used to represent truth and falsity?

A

“true” and “false”

false

false is the easier of the two to define. false is defined as 0 (zero).

true

true is often said to be defined as 1, which is correct, but true has a wider definition. Any integer which is non-zero is true, in a Boolean sense. So -1, 2 and -200 are all defined as true, too, in a Boolean sense.

Note that the true and false constants are typed in lowercase unlike HIGH, LOW, INPUT, and OUTPUT

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2
Q

The two levles that define the pin.

A

HIGH & LOW

The meaning of HIGH (in reference to a pin) is somewhat different depending on whether a pin is set to an INPUT or OUTPUT. When a pin is configured as an INPUT with pinMode(), and read with digitalRead(), the Arduino (Atmega) will report HIGH if:

a voltage greater than 3 volts is present at the pin (5V boards);

a voltage greater than 2 volts is present at the pin (3.3V boards);

A pin may also be configured as an INPUT with pinMode(), and subsequently made HIGH with digitalWrite(). This will enable the internal 20K pullup resistors, which will pull up the input pin to a HIGH reading unless it is pulled LOW by external circuitry. This is how INPUT_PULLUP works and is described below in more detail.

When a pin is configured to OUTPUT with pinMode(), and set to HIGH with digitalWrite(), the pin is at:

5 volts (5V boards);

3.3 volts (3.3V boards);

In this state it can source current, e.g. light an LED that is connected through a series resistor to ground.

LOW

The meaning of LOW also has a different meaning depending on whether a pin is set to INPUT or OUTPUT. When a pin is configured as an INPUT with pinMode(), and read with digitalRead(), the Arduino (Atmega) will report LOW if:

a voltage less than 3 volts is present at the pin (5V boards);

a voltage less than 2 volts is present at the pin (3.3V boards);

When a pin is configured to OUTPUT with pinMode(), and set to LOW with digitalWrite(), the pin is at 0 volts (both 5V and 3.3V boards). In this state it can sink current, e.g. light an LED that is connected through a series resistor to +5 volts (or +3.3 volts).

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3
Q

What is the difference between INPUT, INPUT_PULLUP, and OUPUT

A

Pins Configured as INPUT

Arduino (Atmega) pins configured as INPUT with pinMode() are said to be in a high-impedance state. Pins configured as INPUT make extremely small demands on the circuit that they are sampling, equivalent to a series resistor of 100 Megohms in front of the pin. This makes them useful for reading a sensor.

If you have your pin configured as an INPUT, and are reading a switch, when the switch is in the open state the input pin will be “floating”, resulting in unpredictable results. In order to assure a proper reading when the switch is open, a pull-up or pull-down resistor must be used. The purpose of this resistor is to pull the pin to a known state when the switch is open. A 10 K ohm resistor is usually chosen, as it is a low enough value to reliably prevent a floating input, and at the same time a high enough value to not not draw too much current when the switch is closed. See the Digital Read Serial tutorial for more information.

If a pull-down resistor is used, the input pin will be LOW when the switch is open and HIGH when the switch is closed.

If a pull-up resistor is used, the input pin will be HIGH when the switch is open and LOW when the switch is closed.

Pins Configured as INPUT_PULLUP

The Atmega microcontroller on the Arduino has internal pull-up resistors (resistors that connect to power internally) that you can access. If you prefer to use these instead of external pull-up resistors, you can use the INPUT_PULLUP argument in pinMode().

See the Input Pullup Serial tutorial for an example of this in use.

Pins configured as inputs with either INPUT or INPUT_PULLUP can be damaged or destroyed if they are connected to voltages below ground (negative voltages) or above the positive power rail (5V or 3V).

Pins Configured as Outputs

Pins configured as OUTPUT with pinMode() are said to be in a low-impedance state. This means that they can provide a substantial amount of current to other circuits. Atmega pins can source (provide current) or sink (absorb current) up to 40 mA (milliamps) of current to other devices/circuits. This makes them useful for powering LEDs because LEDs typically use less than 40 mA. Loads greater than 40 mA (e.g. motors) will require a transistor or other interface circuitry.

Pins configured as outputs can be damaged or destroyed if they are connected to either the ground or positive power rails.

Defining built-ins: LED_BUILTIN

Most Arduino boards have a pin connected to an on-board LED in series with a resistor. The constant LED_BUILTIN is the number of the pin to which the on-board LED is connected. Most boards have this LED connected to digital pin 13.

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4
Q

Normally the numbers in the program are in base 10 but you can change them to binary, octal, and hexadecimal by using these syntaxes?

A

Binary - Leading “B”

B1111011

Only works with 8 bit values

Octal - Leading “0”

0173

characters 0-7 are valid

Hexadecimal - leading “0x”

0x7B

characters 0-9, A-F, a-f valid

Examples

B101 // same as 5 decimal ((1 * 2^2) + (0 * 2^1) + 1)

0101 // same as 65 decimal ((1 * 8^2) + (0 * 8^1) + 1)

0x101 // same as 257 decimal ((1 * 16^2) + (0 * 16^1) + 1)

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