Quantum computers is a machine that performs calculations based on the laws of quantum mechanics which is the behaviour of particles at the subatomic level.
1. QUANTUM COMPUTER
Presented by Under the Guidance
T. Bhanu Prakash Prof. I. S. Pallavi
PG212202061 Director of MCA
MCA(2021-2023)
2. Concepts of Quantum Computers..
Introduction & History
Basic concept of quantum computer
Applications
Advantages
Disadvantages and Problems
Future work
3. What does "quantum" mean?
The word "quantum", in quantum computer, originates from "quantum
mechanics," a basic theory in physics. In brief, on the scale of atoms and
molecules, matter behaves in a quantum manner.
INTRODUCTION
What is a Quantum Computer?
A quantum computer is a machine that performs calculations based on the
laws of quantum mechanics, which is the behavior of particles at the sub-atomic
level.
4. HISTORY
In 1918 - Max Planck’s -Energy quantum
In 1921- Einstein’s discovery of the photon
In 1980 - Idea of quantum computation
In 1996, Grover’s came up with an algorithm to search a name in
unsorted database. Grover’s algorithm and the law of super-positioning
makes this possible.
5. Basic Concept Of Quantum Computers & Differences With Existing Computers:
In existing computers, all information is expressed in terms of 0s and 1s, and the entity
that carries such information is called a "bit.“
A bit can be in either a 0 or 1 state at any one moment in time.
A quantum computer, on the other hand, uses a “quantum bit” or "qubit" instead of a bit.
A qubit also makes use of two states (0 and 1) to hold information, but in contrast to a
bit, In this state, a qubit can take on the properties of 0 and 1 simultaneously at any one
moment.
Accordingly, two qubits in this state can express the four values of 00, 01, 10, and 11 all
at one time .
6. A qubit in superposition is in both of the states
|1> and |0> at the same time.
7. Classical bit Vs Qubits:
• Classical bit: {0, 1}
• Qubits: {0, 1, superposed states of 0 and 1}
8. WHAT IS DIFFERENT ABOUT QUANTUM COMPUTERS?
Applications:
There is much that is different between quantum computers and classical computers.
But am going to explain only few:
1. Quantum Super Positioning
2. Quantum Entanglement
3. Quantum Teleportation
9. Quantum Superposition
• Super Positioning is a big word for an old concept: that two things can
overlap each other without interfering with each other.
• In classical computers, electrons cannot occupy the same space at the same
time, but as waves, they can.
• One may think of this as a vector of the probabilities drawn in a two-
dimensional coordinate system of the Complex plane, that is, coordinates of
the form x+iy where
• x is a coordinate on the Real number line, and
• y is a coordinate on the Imaginary number line.
• Classical bits are either vectors of 0 or 1 and have no Imaginary component.
10. •Quantum bits, or "qubits", have both components.
•If the probabilities were equal, the vector could be represented
as 45 degrees from vertical; if the probability of 1 were twice
that of 0, the vector could be represented as 30 degrees from
vertical.
•This vector represents the superposition of the probability of 1
and the probability of 0 simultaneously. In this way, the state
vectors of classical bits are "collapsed" qubit state vectors
11. Entanglement is the ability of quantum systems to exhibit correlations
between states within a superposition.
Quantum entanglement is one of the central principles of quantum physics,
though it is also highly misunderstood.
In short, quantum entanglement means that multiple particles are linked
together in a way such that the measurement of one particle's quantum state
determines the possible quantum states of the other particles.
When this happens, the state of the two particles is said to be entangled.
Quantum Entanglement
12. Quantum Teleportation
Quantum teleportation is a technique used to transfer information on
a quantum level, usually from one particle to another.
Its distinguishing feature is that it can transmit the information present in
a quantum superposition, useful for quantum communication and
computation.
13. Applications:
Encryption Technology
Ultra-secure And Super-dense Communications
Improved Error Correction And Error Detection
Molecular Simulations
True Randomness
Cryptography
Searching
Factorization
Simulating
Encryption Problem & Quantum Chemistry
Problem
14. Advantages :
Could process massive amount of complex data.
Ability to solve scientific and commercial problems.
Process data in a much faster speed.
Capability to convey more accurate answers.
More can be computed in less time.
These are used to protect secure Web pages, encrypted email, and
many other types of data.
15. Hard to control quantum particles
Lots of heat
Expensive
Difficult to build
Not suitable for word processing and email.
Problem of it need of a noise free & Cool Environment.
Complex hardware schemes like superconductors
Disadvantages and Problems:
16. Silicon Quantum Computer
It may become technology sooner than we expect
At the current rate of chip miniaturization, energy efficiency, and economics,
the classical computer of the year 2020 (if it could happen at all), would
contain a CPU running at 40 GHz (or 40,000 MHz), with 160 GB (160,000
MB) RAM, and run on 40 watts of power.
New algorithms and communication
Maximum exploitation
Simulate other quantum systems.
Feature work :
17. Conclusion and Scope
V
eryAdvance Technology
Very Faster & Powerful
Stage of Infancy
Implementation is Difficult