How does a recurrent neural network (RNN) differ from a traditional feedforward neural network?
Both recurrent neural networks (RNNs) and feedforward neural networks (FFNNs) are powerful tools in deep learning, but their internal workings and strengths differ significantly. Let's delve into the technical aspects of each architecture to understand their distinct approaches to processing information.

1. Information Flow:

FFNNs: Information cascades unidirectionally, from input to output layers. Each layer receives data from the previous one, transforms it, and sends the processed output to the next layer. Think of it as a simple assembly line where each station performs a specific task on the incoming material.

RNNs: Information flow becomes dynamic and bi-directional. RNNs introduce internal loops, allowing neurons within a layer to connect with themselves and past states. This creates a "memory" of previous inputs, enabling the network to learn and exploit long-term dependencies within sequential data. Imagine a chef revisiting past ingredients and techniques while crafting a dish, building upon the accumulated knowledge.

2. Hidden Layer Connections:

FFNNs: Connections exist solely between neighboring layers. Neurons in a layer only "see" the outputs of the previous layer and send their processed information to the next. This promotes efficient parallel processing but limits the network's ability to capture long-range relationships within the data.

RNNs: The internal loop adds another dimension to the information flow. Neurons can directly interact with their past states within the same layer, propagating information across time steps. This enables the network to learn intricate temporal patterns and context within sequential data, like the flow of words in a sentence.

3. Memory and State:

FFNNs: Stateless. Each layer operates independently, unaware of past inputs. This makes them suitable for tasks like image recognition where each input image is independent of its predecessors.

RNNs: Stateful. The internal loop allows them to maintain a hidden state that carries information across time steps. This "memory" is crucial for tasks like language processing, where understanding the context of previous words is essential for accurate prediction of the next word.

4. Strengths and Limitations:

FFNNs:

Strengths: Efficient parallel processing, excel at tasks with independent inputs, simpler architecture.
Limitations: Struggle with long-term dependencies, not well-suited for sequential data analysis.
RNNs:

Strengths: Capture long-range dependencies, excel at sequential data analysis, and learn intricate temporal patterns.
Limitations: More complex architecture, computationally expensive, prone to vanishing or exploding gradients.

Choosing the right architecture depends on the nature of your data and task. FFNNs shine with independent data like images, while RNNs excel at analyzing sequential data like text or time series.