AIU 2023-2024 2nd Semester: Parallel Computing Environment Chapter 1 Quiz

Obviously, an execution time of 10 years is always ______.

Examples Global weather forecasting ______.

Modeling motion of astronomical ______.

An execution time of 10 years is always ______.

Global weather forecasting requires ______.

Each calculation requires 200 floating point ______.

In one time step, 10^11 floating point ______ necessary.

Suppose each calculation requires 200 floating point ______.

Each calculation requires 200 ______ point operations.

In one time step, 10^11 floating ______ operations necessary.

In AIU 2023-2024 2nd Semester, the course on Parallel Processing is taught by __________.

Chapter 1 of the course focuses on the Parallel Computing __________.

There is a continual demand for greater computational speed due to areas like numerical modeling and simulation of scientific and engineering __________.

One of the key reasons for the demand for greater computational speed is the need for faster __________.

Demand for computational speed is driven by the need for more efficient processing of complex __________.

Motives Usually to achieve faster computation – very simple idea - that n computers operating simultaneously can achieve the result n times faster - it will not be n times faster for various ______.

It is a very simple idea that n computers operating simultaneously can achieve the result n times faster, but it will not be n times faster due to various ______.

The main motive is usually to achieve faster computation by having n computers operating simultaneously, but the speedup may not be n times faster due to various ______.

The key concept is that n computers working together can achieve the result faster, but it may not be n times faster due to various ______.

Although the idea is simple – using n computers to operate together for faster computation, the actual speedup may not be n times faster due to various ______.

Performing calculation in just 5 minutes requires one computer operating at 3.4 Tflops (3.4  1012 floating point operations/sec). 1.23 Modeling Motion of Astronomical Bodies Each body attracted to each other body by ________ forces.

Performing calculation in just _______ requires one computer operating at 3.4 Tflops (3.4  1012 floating point operations/sec). 1.23 Modeling Motion of Astronomical Bodies Each body attracted to each other body by gravitational forces.

Performing calculation in just 5 minutes requires one computer operating at _______ (3.4  1012 floating point operations/sec). 1.23 Modeling Motion of Astronomical Bodies Each body attracted to each other body by gravitational forces.

Performing calculation in just 5 minutes requires one computer operating at 3.4 Tflops (3.4  1012 floating point operations/sec). _______ Modeling Motion of Astronomical Bodies Each body attracted to each other body by gravitational forces.

Performing calculation in just 5 minutes requires one computer operating at 3.4 Tflops (3.4  1012 floating point operations/sec). 1.23 Modeling Motion of Astronomical Bodies Each body attracted to each other body by gravitational _______.