| Term | Meaning |
|---|---|
| Similarity Score | General relevance score between vectors |
| Cosine Similarity Score | Specifically cosine-based similarity |
| Relevance Score | More general IR/RAG terminology |
| Retrieval Score | Score used for ranking retrieved items |
| Distance Score | Used when lower = better (e.g. Euclidean distance) |
It is working
| Technique | Description | Formula / Key Point | Best Used When |
|---|---|---|---|
| Min-Max Normalization | Scales data to [0, 1] or [a, b] | X' = (X - min) / (max - min) | Bounded data, Neural Networks |
| Standardization (Z-score) | Mean = 0, Std = 1 | X' = (X - μ) / σ | Gaussian-like data, Linear models |
| Robust Scaling | Uses median & IQR (robust to outliers) | X' = (X - median) / IQR | Data with outliers |
| MaxAbs Scaling | Scales by maximum absolute value | X' = X / max(|X|) | Sparse data |
| Mean Normalization | Centers around zero | X' = (X - mean) / (max - min) | Less common |
| Technique | Description | Formula | Use Case |
|---|---|---|---|
| L2 Normalization (Euclidean) | Most common vector normalization | X' = X / ||X||₂ | Distance-based algorithms, Neural Networks |
| L1 Normalization (Manhattan) | Sum of absolute values = 1 | X' = X / ||X||₁ | Sparse data, Feature importance |
| Max Normalization | Divide by maximum value in vector | X' = X / max(|X|) | Simple scaling of feature vectors |
| Layer | Year | Key Idea | Main Advantage | Common Use Cases |
|---|---|---|---|---|
| Batch Normalization (BatchNorm) | 2015 | Normalize across batch dimension | Accelerates training | CNNs (ResNet, etc.) |
| Layer Normalization (LayerNorm) | 2016 | Normalize across features (per sample) | Works with variable batch sizes | Transformers |
| Instance Normalization | 2017 | Normalize per sample per channel | Style transfer | StyleGAN, artistic tasks |
| Group Normalization | 2018 | Normalize within groups of channels | Good for small batch sizes | Object detection |
| RMS Normalization (RMSNorm) | - | Normalize by Root Mean Square | Simpler & faster | Modern LLMs (Llama, etc.) |
| Scenario | Recommended Technique |
|---|---|
| Classical ML (SVM, KNN, etc.) | Standardization or Robust Scaling |
| Neural Networks (small batch) | LayerNorm / GroupNorm |
| Large batch CNNs | BatchNorm |
| Transformers / Large Language Models | RMSNorm or LayerNorm |
| Data with outliers | Robust Scaling |
| Images (style-related) | Instance Normalization |
Euclidean L2 normalization scales a vector so that its total length (magnitude) equals 1, effectively stripping away the "size" of the data while preserving its direction.
Hence, the normalized values of (2, 3) and (3, 2) are not the same. They point in different directions, and their normalized coordinates reflect that.
To normalize a vector, you first find its L2 norm (Euclidean distance from the origin) using the formula:
||v||₂ = √(Σ xi²)
For the example (2,3) and (3,2):
Vector A (2, 3):
√(2² + 3²) = √(4 + 9) = √13 ≈ 3.606
Vector B (3, 2):
√(3² + 2²) = √(9 + 4) = √13 ≈ 3.606
You then divide each component of the original vector by this magnitude:
Normalized A:
(2/√13, 3/√13) ≈ (0.555, 0.832)
Normalized B:
(3/√13, 2/√13) ≈ (0.832, 0.555)
As you can see, the values are swapped, not identical. They represent distinct points on a unit circle.
It represents the orientation or relative proportions of the components.
In a vector of (2, 3), the second feature is 1.5× larger than the first. Normalization keeps this ratio intact while forcing the vector to sit exactly 1 unit away from the origin.
It effectively says:
“I don't care how much of this stuff we have in total; I only care about the mix or the direction.”
Cosine Similarity: In Machine Learning (like recommendation systems), we often care about the angle between vectors rather than their magnitude. If you normalize two vectors, their dot product becomes their Cosine Similarity.
Stable Training: In Deep Learning, normalizing inputs or gradients prevents "exploding" values and helps the model converge faster because every feature is on the same scale (between -1 and 1).
Pattern Recognition: In image processing or computer vision, it helps recognize a shape or pattern regardless of the overall brightness or contrast of the image.
The normalized values for (2, 3) and (3, 2) are distinct: approximately (0.55, 0.83) and (0.83, 0.55) respectively.
Euclidean L2 normalization represents the pure direction of a vector on a unit hypersphere, removing the influence of its magnitude.
Would you like to see how this compares to L1 (Manhattan) normalization, which is often used for probability distributions?
The L2 normalisations of (2, 3) and (10, 15) are identical.
Since (10, 15) is just a scaled-up version of (2, 3)—specifically 5 × (2, 3)—they both point in the exact same direction. Normalisation strips away that "5x" magnitude, leaving you with the same unit vector.
Vector A (2, 3):
Magnitude:
√(2² + 3²) = √13 ≈ 3.606
Normalised:
(2/3.606, 3/3.606) ≈ (0.555, 0.832)
Vector B (10, 15):
Magnitude:
√(10² + 15²) = √(100 + 225) = √325 ≈ 18.028
Normalised:
(10/18.028, 15/18.028) ≈ (0.555, 0.832)
Normalization treats these two vectors as "the same" because their internal ratio is the same (2:3 = 10:15). In many data science contexts, this is exactly what you want.
For example:
Text Analysis: A short document mentioned "Apple" 2 times and "Orange" 3 times. A long document mentions them 10 and 15 times. Normalization tells your algorithm that both documents have the same topic balance, regardless of their length.
Image Processing: A dim pixel (2, 3) and a bright pixel (10, 15) have the same chrominance (color), just different intensities. Normalization lets you process the color while ignoring the lighting.
The L2 normalisation for both vectors is approximately (0.555, 0.832).
This confirms that normalization captures the proportional relationship between components rather than their absolute scale.
L1 normalization (also known as the Manhattan Norm or Least Absolute Deviations) scales a vector so that the sum of the absolute values of its components equals 1.
Unlike L2 normalization, which focuses on the straight-line "Euclidean" distance, L1 normalization focuses on the "Taxicab" distance—measuring how far you'd travel if you could only move along grid lines.
To L1 normalize a vector, you divide each component by the L1 norm (the sum of absolute values):
||v||₁ = Σ |xi|
For your examples:
Vector A (2, 3):
|2| + |3| = 5
Normalised: (2/5, 3/5) = (0.4, 0.6)
Vector B (10, 15):
|10| + |15| = 25
Normalised: (10/25, 15/25) = (0.4, 0.6)
As with L2, vectors with the same internal proportions (2:3) result in the same normalized vector.
L1 normalization represents the contribution share of each element.
If a vector represents counts of different items, the L1 normalized version tells you the percentage or probability of each item occurring relative to the total.
In (0.4, 0.6), the first element represents 40% of the total magnitude and the second represents 60%.
Creating Probabilities: It is commonly used to transform a vector of raw scores into a Probability Mass Function (PMF) where all parts sum to 1.
Sparse Modeling (Lasso): In machine learning, L1 regularization Lasso Regression is famous for its ability to zero out less important features, performing automatic feature selection.
Robustness to Outliers: Because it doesn't square the values (unlike L2), L1 is much less sensitive to extreme outliers. An outlier value of 100 is treated as 100 in L1, but as 10,000 in L2.
L1 normalization scales a vector so that the sum of its absolute components is 1.
For both (2, 3) and (10, 15), the L1 normalized vector is (0.4, 0.6).
It is primarily used to represent proportions or to create sparse models that ignore irrelevant data.
L-Infinity Normalization (also called the Max Norm or Supremum Norm) scales a vector so that its largest component has a magnitude of exactly 1.
Instead of looking at the sum (L1) or the square root of squares (L2), it simply looks for the "peak" value in the set.
To normalize a vector using L-Infinity, you divide every component by the absolute value of the largest component:
||v||∞ = max(|xi|)
For your examples:
Vector A (2, 3): The maximum value is 3.
Normalized: (2/3, 3/3) = (0.66, 1.0)
Vector B (10, 15): The maximum value is 15.
Normalized: (10/15, 15/15) = (0.66, 1.0)
Again, because the proportions are the same, the result is identical.
L-Infinity normalization represents relative importance compared to the maximum.
It forces the most dominant feature to be the "baseline" (1.0) and scales everything else relative to that peak.
In geometry, if you plot all possible L-Infinity normalized vectors, they form a square (or a hypercube in higher dimensions) rather than a circle or a diamond.
Image Processing: It is used to normalize pixel intensities. If you have a dark image, L-infinity normalization scales the brightest pixel to 1.0 (pure white) and stretches all other pixels proportionally, effectively "auto-leveling" the brightness.
Adversarial Machine Learning: In cybersecurity, "L-infinity attacks" are used to test models. An attacker might change every pixel in an image by a tiny, equal amount. L-infinity captures the maximum change made to any single pixel.
Control Systems: It's used when there is a strict limit on a system—for example, if a motor can only handle a maximum of 5 volts, you normalize your control signals so no single output ever exceeds that physical "cap."
| Norm | Result for (2, 3) | Key Logic | Best For |
|---|---|---|---|
| L1 (Plots a Diamond) | (0.4, 0.6) | Components sum to 1 | Proportions & Probabilities |
| L2 (Plots a Circle) | (0.55, 0.83) | Distance to origin is 1 | Directions & Angles |
| L-inf (Plots a Square) | (0.66, 1.0) | Max component is 1 | Peak values & Constraints |
To calculate dot products and cosine similarity in NumPy, you primarily use np.dot() and np.linalg.norm(). While NumPy has a direct function for the dot product, cosine similarity is typically calculated by combining several operations.
np.dot(a, b): The standard function for computing the dot product.a @ b: A more modern and readable operator for matrix multiplication and dot products introduced in Python 3.5.np.inner(a, b): Computes the inner product, which for 1D arrays is identical to the dot product. np.dot(): For the numerator (A.B)np.linalg.norm(): For the denominator magnitudes Magnitude(A).Magnitude(B)import numpy as np
from numpy.linalg import norm
def cosine_similarity(a, b):
return np.dot(a, b) / (norm(a) * norm(b))
| Metric | NumPy Function(s) | Result Range |
|---|---|---|
| Dot Product | np.dot(a, b) or a @ b | -infinity to +infinity |
| Cosine Similarity | np.dot(a, b) / (norm(a) * norm(b)) | -1 to 1 |
cosine_similarity function or SciPy's spatial.distance.cosine (which returns cosine distance, or 1 - similarity)