The answer will depend on what the function is.
The operation appears to involve subtracting 1 from the quotient of each input number divided by 5. Specifically, for each input number ( x ), the output can be calculated as ( \text{output} = \frac{x}{5} + 3 ). For example, for the input 5, the output is ( \frac{5}{5} + 3 = 4 ). This pattern holds for all given input numbers.
The output when the input is 5 depends on the specific function or context in which the input is being used. For example, if the function is to double the input, the output would be 10. If it’s a mathematical function like squaring, the output would be 25. Please provide more details for a precise answer.
5*(-2) - 3 = -10 - 3 = -13
The output of the expression 11 5 will be 6. This is because 11 - 5 = 6.
Gain = Pout - Pin = -10dBm - (-5dBm) = -5dB
Either 5 or 10 states, depending on how the output and input are connected.
Simple Machine Language output typically includes low-level instructions that a computer's processor can execute directly. Examples of such output might include commands like "LOAD A, 5" to load the value 5 into register A, "ADD A, B" to add the contents of register B to A, or "JUMP 10" to move the execution to an instruction located at address 10. This output is often specific to a particular architecture and directly corresponds to the machine's instruction set.
Input: "3+2" --- Output: "5" Input: "song.mp3" ---- Output: the music you listen to
The output is multiplied by 5.
The output is multiplied by 5.
The rule appears to be a linear relationship between the input and output values. When the input increases by 4 (from 1 to 5), the output decreases by 4 (from 5 to 1). Similarly, when the input increases by another 4 (from 5 to 9), the output decreases by 4 again (from 1 to -3). Therefore, the rule seems to be that for every increase of 4 in the input, the output decreases by 4.
The mechanical advantage of the lever is calculated by dividing the output force by the input force. In this case, the output force is 10 N and the input force is 5 N, so the mechanical advantage would be 10 N / 5 N = 2. This means that the lever provides a mechanical advantage of 2, making it easier to lift the box.