Analog-and-Digital-Processing_Lesson.pptx

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Analog and
Digital
Processing
What is Analog Processing?
Analog processing is concerned with manipulating
smoothly varying continuous time in variant signals.
These signals are usually represented by voltage,
current or other measurable physical quantities.
Analog processing embraces all possible signal
fluctuations and is commonly used for audio, and video
systems as well as for communication ones that process
real-life signals at hand.
Types of Analog Processing
Linear Processing: This deals with linear operations such as
amplification and filtering.
Non-linear Processing: This involves operations like modulation
and demodulation.
Time-Domain Processing: Signal process directly with respect to
time domain
Frequency-Domain Processing: Processes signals in the frequency
domain using techniques like Fourier Transform.
Analog Modulation: Here a carrier signal changes to transmit data
(for example AM, FM).
Advantages Analog Processing
Real-life Representation: True format of the realworld
signals is captured.
Ease of Execution: Easy to implement for simple tasks.
Lower First Cost: Simple applications cost less generally.
Highest Fidelity for Audio: Top quality sound
reproduction provided.
Ploy in Harsh Conditions: Operating well in some tough
conditions.
Disadvantages Analog Processing
Prone to Noise: Can easily get affected by noise and
signal erosion.
Inflexible: Difficult to change or update signals.
Storage Challenges: Requires large physical media
storage capacities.
Limited Precision: Less accurate in signal
representation.
Non-Scalable Poorly scalable for complex jobs.
Applications Analog Processing
Audio Equipment: Amplifiers, microphones, and
speakers.
Radio Broadcasting: AM and FM radio transmission.
Television Transmission: Analog TV signal transmission.
Medical Devices: ECG and EEG machines.
Instrumentation: Analog sensors and transducers.
 Digital Processing
Digital processing is the manipulation of a discrete
signal that is represented by binary digits (0s and 1s).
These signals are samples or quantized versions of
analog signals therebking them amenable to digital
computation and storage. Digital processing, however,
has been widely used in areas such as
telecommunications, computing, and digital media that
require fast and accurate data handling.
Types of Digital Processing
Digital Filtering: Application of digital filters removes noise from
the signal enhancing it.
Digital Modulation: Digital data modulated into a carrier wave (e.g.
QAM, PSK).
Digital Image Processing: It manipulates digital images so that
they can be enhanced, or information can be extracted from them.
DSP (digital signal processing): It entails processing digital signals
meant for audio purposes or communication systems.
Digital Compression: The decrease in size for storage or
transmission of digital data.
Advantages Digital Processing
High Precision. Provides accurate signal representation
Flexibility. Can be easily modified or updated
Reliable Data Transmission Over Distance. Maintains its
integrity over long distances
Compact Storage Solution. Compact digital storage
systems
Easily Scalable. Can be easily scaled up for large and
complex applications
Disadvantages Digital Processing
Higher Initial Costs. It is expensive to set up at first sight.
Complex Implementation. Requires sophisticated hardware
and software tools for implementation purposes
Processing Delays. There may be delays in real-time
processing,
Power Consumption Issue, Higher power consumption is
typically associated with it,
Vulnerability to Cyber Threats, Prone to hacking and data
breach
Applications Digital Processing
Computing: Digital signal processors in computers and
smartphones.
Telecommunications: Digital telephony and internet
communication.
Multimedia: Digital video and audio editing.
Medical Imaging: MRI, CT scans, and digital X-rays.
Data Storage: Hard drives, SSDs, and cloud storage.
Difference Between Analog and Digital Processing
 Both analog processing as well as digital processing
have their own strengths that can be applied to
different situations. In some cases like audio where
simplicity is key, analog processing is more suitable for
capturing real-world signals in their original form with
high fidelity. On the other hand digital processing is very
accurate making it ideal for use in computing
telecommunications and digital media due to its
flexibility as well as scalability. Knowledge about these
two processing methods will enable one to choose the
right approach for specific applications hence achieving
the maximum level of efficiency or productivity.