Adafactor

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Author: Aolei Cao (ac3237), Ziyang Li (zl986), Junjia Liang (jl4439) (ChemE 6800 Fall 2024)

Stewards: Nathan Preuss, Wei-Han Chen, Tianqi Xiao, Guoqing Hu

Introduction

Problem formulation

1. Objective

Minimize the loss function , where and is the weight vector to be optimized.

2. Parameters

  • Gradient:

  • Second moment estimate:

  • Where:
    • is the running average of the squared gradient.
    • is the corrected decay parameter.
    • is a regularization constant.
  • Step size:

  • Where:
    • is the relative step size.
    • is a regularization constant.
    • is the root mean square, defined as:

Clipping

3. Algorithms

Adafactor for Weighted Vectors

Inputs:

  • Initial point:
  • Relative step sizes: for to
  • Second moment decay: for to , with
  • Regularization constants:
  • Clipping threshold:

Algorithm:

  • For to :
    • Compute adaptive step size:
    • Compute gradient:
    • Update second moment estimate:
    • Compute normalized gradient:
    • Apply clipping:
    • Update parameter:
  • End for

Adafactor for Weighted Matrices

Inputs:

  • Initial point:
  • Relative step sizes: for to
  • Second moment decay: for to , with
  • Regularization constants:
  • Clipping threshold:

Algorithm:

  • For to :
    • Compute adaptive step size:
    • Compute gradient:
    • Update row-wise second moment:
    • Update column-wise second moment:
    • Update overall second moment estimate:
    • Compute normalized gradient:
    • Apply clipping:
    • Update parameter:
  • End for

4. Proposed Hyperparameters for Adafactor

  • Regularization constant 1:
  • Ensures numerical stability by preventing division by zero in the calculation of second-moment estimates, so the numerical value should be very close to zero
  • Regularization constant 2:
  • Help to stabilize parameter updates by controlling the effect of second-moment scaling in low-magnitude scenarios. Compared to , a relatively larger value ensures the stability of noise and low-magnitude scenarios.
  • Clipping threshold:
  • A threshold of 1 balances stability and learning efficiency. It avoids excessive suppression of large gradients, which could hinder learning, while still protecting against extreme updates that could destabilize the model.
  • Relative step size:
    • can caps the learning rate at 10^-2, which is a empirical found for upper bound
    • This step size promote convergence of the model. This rate ensures a balance between sufficient exploration in early iteration and stability in later iterations
  • Second moment decay:
    • 1-...: ensures the decay factor remains close to 1
    • the power 0.8 ensures a balance between rapid adaptation in early training and later iterations

Numerical Examples

Applications

Conclusion

Reference