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 Page 1


   
      
 
Order and rate of convergence
Iteration is a common approach widely used in various numerical methods. It is the hope that an iteration in the
general form of  will eventually converge to the true solution  of the problem at the limit
when . The concern is whether this iteration will converge, and, if so, the rate of convergence.
Specifically we use the following to represent how quickly the error  converges to zero: 
 
Here  is called the order of convergence, the constant  is the rate of convergence or asymptotic error
constant.
This expression may be better understood when it is interpreted as  when .
Obviously, the larger  and the smaller , the more quickly the sequence converges. Specially, we consider the
following cases:
If  and , , then
if , the convergence is sublinear
if , the convergence is linear with the rate of convergence of .
if , the convergence is superlinear
If , , the convergence is quadratic.
If , , the convergence is cubic.
The iteration  can be written in terms of the errors  and . Consider the Taylor
expansion: 
 
Subtracting  from both sides, we get 
 
Page 2


   
      
 
Order and rate of convergence
Iteration is a common approach widely used in various numerical methods. It is the hope that an iteration in the
general form of  will eventually converge to the true solution  of the problem at the limit
when . The concern is whether this iteration will converge, and, if so, the rate of convergence.
Specifically we use the following to represent how quickly the error  converges to zero: 
 
Here  is called the order of convergence, the constant  is the rate of convergence or asymptotic error
constant.
This expression may be better understood when it is interpreted as  when .
Obviously, the larger  and the smaller , the more quickly the sequence converges. Specially, we consider the
following cases:
If  and , , then
if , the convergence is sublinear
if , the convergence is linear with the rate of convergence of .
if , the convergence is superlinear
If , , the convergence is quadratic.
If , , the convergence is cubic.
The iteration  can be written in terms of the errors  and . Consider the Taylor
expansion: 
 
Subtracting  from both sides, we get 
 
At the limit , all higher order error terms become zero, we have 
 
If , then the convergence is linear. However, if , then 
 
and we have 
 
the convergence is quadratic. We see that if the iteration function has zero derivative at the fixed point, the
iteration may be accelerated.
Examples:
, the sequence is  
This is a sublinear convergence as only when  will the limit be a constant .
, the sequence is  
This is a linear convergence of order  and rate .
Page 3


   
      
 
Order and rate of convergence
Iteration is a common approach widely used in various numerical methods. It is the hope that an iteration in the
general form of  will eventually converge to the true solution  of the problem at the limit
when . The concern is whether this iteration will converge, and, if so, the rate of convergence.
Specifically we use the following to represent how quickly the error  converges to zero: 
 
Here  is called the order of convergence, the constant  is the rate of convergence or asymptotic error
constant.
This expression may be better understood when it is interpreted as  when .
Obviously, the larger  and the smaller , the more quickly the sequence converges. Specially, we consider the
following cases:
If  and , , then
if , the convergence is sublinear
if , the convergence is linear with the rate of convergence of .
if , the convergence is superlinear
If , , the convergence is quadratic.
If , , the convergence is cubic.
The iteration  can be written in terms of the errors  and . Consider the Taylor
expansion: 
 
Subtracting  from both sides, we get 
 
At the limit , all higher order error terms become zero, we have 
 
If , then the convergence is linear. However, if , then 
 
and we have 
 
the convergence is quadratic. We see that if the iteration function has zero derivative at the fixed point, the
iteration may be accelerated.
Examples:
, the sequence is  
This is a sublinear convergence as only when  will the limit be a constant .
, the sequence is  
This is a linear convergence of order  and rate .
, the sequence is  
This is superlinear, specifically quadratic, convergence of order  and rate .
From these examples we see that there is a unique exponent , the order of convergence, so that 
 
In practice, the true solution  is unknown and so is the error . However, it can be estimated if
the convergence is superlinear, satisfying 
 
Consider: 
 
   
  
i.e., when , 
The order and rate of convergence can be estimated by 
 
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FAQs on Rate of Convergence - Numerical Analysis, CSIR-NET Mathematical Sciences - Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

1. What is the rate of convergence in numerical analysis?
Ans. The rate of convergence in numerical analysis refers to how quickly a sequence of approximations approaches the true solution. It measures the speed at which the error decreases as the number of iterations or refinements increases.
2. How is the rate of convergence determined in numerical analysis?
Ans. The rate of convergence is determined by analyzing the behavior of the error term as the number of iterations or refinements increases. It is often expressed in terms of the order of convergence, which indicates the rate at which the error decreases. Common orders of convergence include linear, quadratic, and cubic.
3. What factors affect the rate of convergence in numerical analysis?
Ans. Several factors can affect the rate of convergence in numerical analysis. These include the choice of numerical method or algorithm, the initial approximation or guess, the properties of the problem being solved, and the convergence criteria used to determine when to stop iterating.
4. How can the rate of convergence be improved in numerical analysis?
Ans. To improve the rate of convergence in numerical analysis, one can try using more advanced numerical methods or algorithms that are known to have faster convergence properties. Additionally, choosing a better initial approximation or refining the approximation at each iteration can also help improve the rate of convergence.
5. Are there any limitations to the rate of convergence in numerical analysis?
Ans. Yes, there are limitations to the rate of convergence in numerical analysis. In some cases, the rate of convergence may be inherently slow due to the nature of the problem being solved. Additionally, numerical methods may encounter convergence issues, such as oscillations or divergence, which can hinder the rate of convergence.
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