Well, I hope I'm not too late for the party! Let me first try to establish some intuition before digging into loads of information (**warning**: this is not a brief comparison, TL;DR)

## Introduction

A hypothesis `h(x)`

, takes an *input* and gives us the *estimated output value*.

This hypothesis can be as simple as a one-variable linear equation, .. up to a very complicated and long multivariate equation with respect to the type of algorithm we’re using (*e.g. linear regression, logistic regression..etc*).

Our task is to find the **best Parameters** (a.k.a Thetas or Weights) that give us the **least error** in predicting the output. We call the function that calculates this error a **Cost or Loss Function**, and apparently, our goal is to **minimize** the error in order to get the best-predicted output!

One more thing to recall is, the relation between the parameter value and its effect on the cost function (i.e. the error) looks like a **bell curve** (i.e. **Quadratic**; recall this because it’s important).

So if we start at any point in that curve and keep taking the derivative (i.e. tangent line) of each point we stop at (*assuming it's a univariate problem, otherwise, if we have multiple features, we take the partial derivative*), we will end up at what so-called the **Global Optima** as shown in this image:

If we take the partial derivative at the minimum cost point (i.e. global optima) we find the **slope** of the tangent line = **0** (then we know that we reached our target).

That’s valid only if we have a *Convex* Cost Function, but if we don’t, we may end up stuck at what is called **Local Optima**; consider this non-convex function:

Now you should have the intuition about the heck relationship between what we are doing and the terms: *Derivative*, *Tangent Line*, *Cost Function*, *Hypothesis* ..etc.

*Side Note: The above-mentioned intuition is also related to the Gradient Descent Algorithm (see later).*

## Background

**Linear Approximation:**

Given a function, `f(x)`

, we can find its tangent at `x=a`

. The equation of the tangent line `L(x)`

is: `L(x)=f(a)+f′(a)(x−a)`

.

Take a look at the following graph of a function and its tangent line:

From this graph we can see that near `x=a`

, the tangent line and the function have *nearly* the same graph. On occasion, we will use the tangent line, `L(x)`

, as an approximation to the function, `f(x)`

, near `x=a`

. In these cases, we call the tangent line the "*Linear Approximation*" to the function at `x=a`

.

**Quadratic Approximation:**

Same as a linear approximation, yet this time we are dealing with a curve where we *cannot* find the point near to **0** by using only the *tangent line*.

Instead, we use the **parabola** as it's shown in the following graph:

In order to fit a good parabola, both parabola and quadratic function should have the same **value**, the same **first derivative**, AND the same **second derivative**. The formula will be (*just out of curiosity*): `Qa(x) = f(a) + f'(a)(x-a) + f''(a)(x-a)2/2`

*Now we should be ready to do the comparison in detail.*

## Comparison between the methods

**1. Newton’s Method**

Recall the motivation for the gradient descent step at `x`

: we minimize the quadratic function (i.e. Cost Function).

Newton’s method uses in a sense a **better** quadratic function minimisation.
It's better because it uses the quadratic approximation (i.e. first AND *second* partial derivatives).

You can imagine it as a twisted Gradient Descent with the Hessian (*the Hessian is a square matrix of second-order partial derivatives of order *`n X n`

).

Moreover, the geometric interpretation of Newton's method is that at each iteration one approximates `f(x)`

by a quadratic function around `xn`

, and then takes a step towards the maximum/minimum of that quadratic function (in higher dimensions, this may also be a *saddle point*). Note that if `f(x)`

happens to be a quadratic function, then the exact extremum is found in one step.

**Drawbacks:**

It’s computationally **expensive** because of the Hessian Matrix (i.e. second partial derivatives calculations).

It attracts to **Saddle Points** which are common in multivariable optimization (i.e. a point that its partial derivatives disagree over whether this input should be a maximum or a minimum point!).

**2. Limited-memory Broyden–Fletcher–Goldfarb–Shanno Algorithm:**

In a nutshell, it is an analogue of Newton’s Method, yet here the Hessian matrix is **approximated** using updates specified by gradient evaluations (or approximate gradient evaluations). In other words, using estimation to the inverse Hessian matrix.

The term Limited-memory simply means it stores only a few vectors that represent the approximation implicitly.

If I dare say that when the dataset is **small**, L-BFGS relatively performs the best compared to other methods especially because it saves a lot of memory, however, there are some “*serious*” drawbacks such that if it is unsafeguarded, it may not converge to anything.

*Side note: This solver has become the default solver in sklearn LogisticRegression since version 0.22, replacing LIBLINEAR.*

**3. A Library for Large Linear Classification:**

It’s a linear classification that supports logistic regression and linear support vector machines.

The solver uses a Coordinate Descent (CD) algorithm that solves optimization problems by successively performing approximate minimization along coordinate directions or coordinate hyperplanes.

`LIBLINEAR`

is the winner of the ICML 2008 large-scale learning challenge. It applies *automatic parameter selection* (a.k.a L1 Regularization) and it’s recommended when you have high dimension dataset (*recommended for solving large-scale classification problems*)

**Drawbacks:**

It may get stuck at a *non-stationary point* (i.e. non-optima) if the level curves of a function are not smooth.

Also cannot run in parallel.

It cannot learn a true multinomial (multiclass) model; instead, the optimization problem is decomposed in a “one-vs-rest” fashion, so separate binary classifiers are trained for all classes.

*Side note: According to Scikit Documentation: The “liblinear” solver was the one used by default for historical reasons before version 0.22. Since then, the default use is Limited-memory Broyden–Fletcher–Goldfarb–Shanno Algorithm.*

**4. Stochastic Average Gradient:**

The SAG method optimizes the sum of a finite number of smooth convex functions. Like stochastic gradient (SG) methods, the SAG method's iteration cost is independent of the number of terms in the sum. However, by *incorporating a memory of previous gradient values, the SAG method achieves a faster convergence rate* than black-box SG methods.

It is **faster** than other solvers for *large* datasets when both the number of samples and the number of features are large.

**Drawbacks:**

It only supports `L2`

penalization.

This is not really a drawback, but more like a comparison: although SAG is suitable for large datasets, with a memory cost of `O(N)`

, it can be less practical for very large `N`

(*as the most recent gradient evaluation for each function needs to be maintained in the memory*). This is usually not a problem, but a better option would be SVRG 1, 2 which is unfortunately not implemented in scikit-learn!

**5. SAGA:**

The SAGA solver is a *variant* of SAG that also supports the non-smooth *penalty L1* option (i.e. L1 Regularization). This is therefore the solver of choice for **sparse** multinomial logistic regression. It also has a better theoretical convergence compared to SAG.

**Drawbacks:**

- This is not really a drawback, but more like a comparison: SAGA is similar to SAG with regard to memory cost. That's it's suitable for large datasets, yet in edge cases where the dataset is very large, the SVRG 1, 2 would be a better option (unfortunately not implemented in scikit-learn)!

*Side note: According to Scikit Documentation: The SAGA solver is often the best choice.*

Please note the attributes "Large" and "Small" used in Scikit-Learn and in this comparison are relative. AFAIK, there is no universal unanimous and accurate definition of the dataset boundaries to be considered as "Large", "Too Large", "Small", "Too Small"...etc!

## Summary

The following table is taken from Scikit Documentation

*Updated Table from the same link above (accessed 02/11/2021):*