DADS401 ADVANCED MACHINE LEARNING

Description

SESSION	FEB MARCH 2025
PROGRAM	MASTER OF BUSINESS ADMINISTRATION (MBA)
SEMESTER	IV
COURSE CODE & NAME	DADS401 ADVANCED MACHINE LEARNING

 

 

Assignment Set – 1

 

Q1. Write a note on:

(a) Criticise the types of Stationarity.

(b) Illustrate Exponential Smoothing.         5+5     

Ans 1.

1. Types of Stationarity

Stationarity in time series analysis refers to the property of a process where its statistical features such as mean, variance, and autocorrelation structure remain constant over time. There are primarily three types of stationarity: strict stationarity, weak (or second-order) stationarity, and trend stationarity.

Strict stationarity requires the complete joint distribution of any subset of variables to remain unchanged over time. While this is a strong and mathematically ideal condition, it is practically difficult to validate with real-world data due to the need for a large number of observations and complex computations. It is often criticized for being too rigid and not realistic for most economic or

 

Its Half solved only

Buy Complete from our online store

 

https://smuassignment.in/online-store/

 

MUJ Fully solved assignment available for session Jan-Feb-March-April 2025.

 

Lowest price guarantee with quality.

Charges INR 198 only per assignment. For more information you can get via mail or Whats app also

Mail id is aapkieducation@gmail.com

 

Our website www.smuassignment.in

After mail, we will reply you instant or maximum

1 hour.

Otherwise you can also contact on our

whatsapp no 8791490301.

 

 

Q2. Write a note on:

1. Interpret the ARCH Model. Explain its Usage.
2. Appraise a few risks associated with Artificial Intelligence. 5+5

Ans 2.

1. ARCH Model and its usage

The Autoregressive Conditional Heteroskedasticity (ARCH) model, developed by Robert Engle in 1982, is a statistical model used to describe time series data exhibiting volatility clustering. This phenomenon refers to the observation that large changes in a series tend to be followed by large changes, and small changes tend to be followed by small changes, regardless of

 

Q3. (a) Demonstrate any three applications of AI in Medical sciences.

(b)Discuss some challenges or limitations we face with Deep Learning.  5+5

Ans 3.

(a) Applications of AI in Medical Sciences

Artificial Intelligence (AI) has made significant strides in transforming the field of medical sciences. One of the most impactful applications is in medical imaging and diagnostics. AI-powered systems, especially deep learning models like Convolutional Neural Networks (CNNs), are capable of identifying patterns in X-rays, MRIs, and CT scans with accuracy comparable to or exceeding that of human radiologists. These tools are used in detecting diseases such as cancer,

 

Assignment Set – 2

 

 

Q4. (a) Summarise Back Propagation.

(b) Appraise the classification of the Layers of CNN.                  

Ans 4.

1. Backpropagation

Backpropagation is a supervised learning algorithm widely used for training artificial neural networks. The process involves the computation of gradients of a loss function with respect to the network’s weights, allowing the model to adjust these weights and minimize prediction errors. Backpropagation begins with a forward pass where inputs are processed layer by layer to compute an output. Once

 

Q5. (a) What is an Auto-Encoder? Explain its classification.

(b) Describe the concept of LSTM. 5+5     

Ans 5.

1. Understanding Autoencoders in Machine Learning and its classification

Autoencoders are a class of unsupervised artificial neural networks that aim to learn efficient representations of input data. The goal of an autoencoder is to compress the input into a latent-space representation and then reconstruct the output from this representation to be as close as possible to the original input. This structure comprises three components: the encoder, the bottleneck, and the decoder. The encoder compresses the input data into a smaller representation. The bottleneck contains the most critical compressed information. The decoder then tries to

 

 

 

Q6. (a) Contrast between SARSA and Q-Learning.

(b) Reframe some algorithms commonly used with Image recognition systems. 5+5

Ans 6.

1. Comparison Between SARSA and Q-Learning

SARSA and Q-learning are two popular reinforcement learning algorithms used for policy learning in an environment. They are both model-free, meaning they do not require prior knowledge of the environment’s dynamics. However, their learning strategies are fundamentally different. SARSA stands for State-Action-Reward-State-Action, while Q-learning is based on the State-Action-Reward-State formulation. The key difference lies in how they update