I have a data set which I need to fit to two quadratic equation:
f1(x) = a*x + b*x^2
f2(x) = b*x^2
Is there a way to estimate the error where I take into account both the standard error in the measurement and the error in the curve fittig?
I have a data set which I need to fit to two quadratic equation:
Is there a way to estimate the error where I take into account both the standard error in the measurement and the error in the curve fittig? 


I guess you mean that "error due to measurement" is the distribution of the measured values around the "true" predicted values by some physical law, and "error in curve fitting" is caused by fitting the data to a model that does not fully capture the physical law. There is no way to know which kind of error you are seeing unless you already know the physical law. For example: Suppose you have a perfect amplifier whose transfer function is Vo = Vi^2. You input a range of voltages Vo and measure the output Vi for each. If you fit a quadratic to the data, you know that any error is caused by measurement. If you fit a line to the data, your error is caused by both measurement and your choice of curve fitting. But you'd have to know that the behavior is actually quadratic in order to measure the error source. And you'd do it by... fitting a quadratic. In the real world, nothing ever behaves perfectly, so you're always stuck with your best approximation to the physical reality. 


If you have errors in your measurements as well as in your response variable, you might try fitting your models using Orthogonal Regression. There's a demo illustrating exactly this process that ships as part MATLAB's Statistics Toolbox. 

