Monte Carlo simulation with Excel and Python

Posted on 31/05/2026 by dougaj4

The pyxll blog has a post from last year on Monte Carlo Simulations in Excel with Python, with examples and full code going from the simplest implementation to more refined code allowing all the calculations to be set up on the spreadsheet, with the simulation just requiring a single call of the Python code.

The calculation modelled in the pyxll blog example is simply the addition of 3 variables. In this post I have used the same code to do a more complex engineering-based analysis, the evaluation of the ultimate bending capacity of a reinforced concrete section subject to combined bending and axial load. This uses the Py_UMom function, last presented at: py_UMom 1-05, and available for download at:

py_UMom.zip

The rest of the required code, and the example spreadsheet, can be downloaded from:

MonteCarlo.zip

Most of the code is copied directly from the pyxll post, with the addition of a link to the py_UMom code and a new function calling the Scipy Norm function to generate the samples, rather than the PERT function. Note that the examples are purely to demonstrate the process. The values I used to define the range of the distributions were based purely on what “seemed about right” and have no significance beyond that.

The first example below has minimal change to the layout used in the pyxll blog:

The py_UMom function input includes an array of 12 cells defining the cross section dimensions and material properties. Of these, 3 are adjusted in the Monte Carlo simulation, with the rest remaining constant. In the example above the parameters defining the range of the sample distribution are listed adjacent to the input value to be adjusted, followed by the PertRandomVariable function.

In the next example the random variables are listed separately, with the output cell defined in the PertRandomVariable functions input:

This generates similar output to the first example, with the small change in the results being due to the Monte Carlo process:

The final example uses the same analysis process, but uses the Scipy Norm function to generate the input random distributions:

class NormRandomVariable(RandomVar):
    """Random variable using the normal distribution."""
 
    def __init__(self,
                 name: str,
                 target: XLCell,
                 mean_value: float,
                 std_dev: float):
        super().__init__(name, target)
        self.__dist = norm(loc=mean_value, scale=std_dev)
 
    def samples(self, n, seed=None):
        return self.__dist.rvs(size=n, random_state=seed)

The range of the variable distributions is now defined with two values, the mean and the standard deviation. The results are very similar to the PERT distribution:

Posted in Beam Bending, Concrete, Excel, Link to Python, Maths, Newton, NumPy and SciPy, UDFs | Tagged , , , , , , , | Leave a comment

FeedSpot

Posted on 24/05/2026 by dougaj4

Feedspot is a blog database with a huge list of different categories, each with listings of the best blogs, including:

60 Best Excel Blogs to Follow in 2026

with a wide range of blogs, including:

For a complete list of contents see:

FeedSpot helps you find the best blogs on the web.

https://bloggers.feedspot.com

Posted in Computing - general, Excel | Tagged , , | Leave a comment

Scipy-statistics with all distributions

Posted on 17/05/2026 by dougaj4

Following the previous post the Scipy statistics functions have been updated to include all the distributions, including the discrete distributions. The input to the distribution functions has also been updated to allow arrays to be transferred either as Excel ranges or pyxll cache objects. The updated code and spreadsheets can be downloaded from:

py_SciPy.zip

The screenshot below shows the py_multivariate_norm function with the x array input as a cache object:

Changing x to the range G32:G36 returns exactly the same results:

There have also been changes to the py_linspace function, in the pyNumpy.py file, to allow the results array to be returned either as a range or a pyxll cache.

If the optional Rtn_Cache input is set to False (default) the results are returned as a range:

If Rtn_Cache is set to True the array is returned as a pyxll cache, as for py_linspace_o, which is still available:

The updated pyNumpy.py file comes in two versions, pyNumpy-jit.py and pyNumpy-noJIT.py, with the jit version including calls to the Numba just-in-time compiler. The chosen version should be copied to pyNumpy.py.

Posted in Arrays, Excel, Link to Python, Maths, Newton, NumPy and SciPy, PyXLL, UDFs | Tagged , , , , , , , , , , , | Leave a comment

Transferring different data types to/from Python with pyxll

Posted on 12/05/2026 by dougaj4

When a user defined function (UDF) is created in Excel with Python and pyxll the data type of each argument can be specified, either in the @xl_func decorator, or with a separate @xl_arg decorator for each argument. I prefer the latter, which I find more readable and easier to check.

A problem arises if the argument may have different data types; for instance, in my recent additions to the Scipy Stats functions, one of the inputs is often an array of x values, which can easily be created on the spreadsheet for small arrays, but for very large arrays it is may be better to generate a pyxll cache object, which displays as a single cell on the spreadsheet. I had been creating separate functions for these two cases, but I recently discovered, with the help of Tony Roberts from pyxll, that it is now possible to specify alternative data types for any argument, using Union Types

The code below illustrates this approach, with the ‘x’ argument being specified either as a ‘numpy_array’ or an ‘object’.

@xl_func(category = "Scipy-Stats", help_topic="https://docs.scipy.org/doc/scipy/reference/generated/scipy.stats.multivariate_normal.html!0")
@xl_arg('method', 'str')
@xl_arg('x', 'union<numpy_array, object>')
@xl_arg('kwargs', 'dict')
@xl_return('numpy_array')
def py_multivariate_norm(method, x = [], kwargs = None):
    """
A multivariate normal random variable.
The mean keyword specifies the mean. The cov keyword specifies the covariance matrix.
See on-line help for full list of methods and arguments
    """
    newmethod = getattr(stats.multivariate_normal, method)
    if type(x) == list:
        res = newmethod(**kwargs)
    else:
        res = newmethod(x, **kwargs)
    if isinstance(res, np.ndarray) == False: res = np.array(res)
    return res

In this case the x argument is optional, and defaults to an empty list if omitted, but if included it may be specified either as a cache object:

or a selected range which will be converted to a NumPy array.

The results are the same in both cases.

The same approach may be used to return the function results either as a numpy array, displaying all the results, or a pyxll cache object, which displays as a single cell, but contains all the data, which can either be passed back to Python, or the data can be extracted, all or in part, for display in the spreadsheet.

In this case the Python data must be prepared before being transferred, as described in this pyxll FAQ:

https://support.pyxll.com/hc/en-gb/articles/360036961153-How-can-my-function-return-different-types

This approach has been used in the py_linspace function:

@xl_func(category="py-Maths", help_topic="https://numpy.org/doc/stable/reference/generated/numpy.linspace")
@xl_arg('startnum', 'float')
@xl_arg('stopnum', 'float')
@xl_arg('num', 'int')
@xl_arg('endpoint', 'bool')
@xl_arg('retstep', 'bool')
@xl_arg('rtn_cache', 'bool')
@xl_arg('dtype', 'str')
@xl_arg('axis', 'int')
@xl_return('union<var, object>')
def py_linspace(startnum, stopnum, num = None, endpoint = None, retstep = None, rtn_cache = False, dtype = None, axis = 0):
 
    try:
        axis = int(axis)
    except:
        pass
    kwargs = {'num': num, 'endpoint': endpoint, 'retstep': retstep, 'dtype': dtype, 'axis': axis}
    kwargs = {k:v for k,v in kwargs.items() if v is not None}
    
    res = np.linspace(startnum, stopnum, **kwargs)
    if rtn_cache:
        return res
    else:
        to_var = get_type_converter('numpy_array', 'var')
        res = to_var(res)
        return res

The Python code generates a numpy array, which will be displayed in Excel as a cache object. To display as an Excel range of values the pyxll get_type_converter is used to generate a to_var function that converts the array to an Excel variant array.

The updated Scipy and Numpy code will be included for download in the next post.

Posted in Arrays, Excel, Link to Python, Newton, NumPy and SciPy, PyXLL, UDFs | Tagged , , , , , , , , , | 1 Comment

Scipy-statistics with distributions

Posted on 01/05/2026 by dougaj4

The Scipy statistics functions last presented here have now been updated with the addition of links to the numerous distribution functions.

The py_Stats spreadsheet, with associated Python code in PythonStatsFuncs3.py and pyScipy3.py, and also minor updates to the pyNumpy.py code, are included in the download file:

py_SciPy.zip

Details of the required pyxll package (including download, free trial, and full documentation) can be found at: pyxll

For those installing a new copy of pyxll, a 10% discount on the first year’s fees is available using the coupon code “NEWTONEXCELBACH10”.

The Scipy distribution functions are divided into Continuous, Multivariate, and Discrete. There are 114 continuous functions, each with a large number of different methods. All of these functions can be called from Excel with the py_rv_continuous function, specifying the required distribution and associated method, followed by required arguments, then any optional arguments, listed in dictionary format. There are also specific functions calling the Normdist and Norminvgauss functions, as shown below:

The spreadsheet lists all the available methods of the Normdist function, with required and optional arguments. Help on the methods of the other distributions can be found at the linked on-line help.

For the multivariate functions there is more variation in the function arguments, so each function has an associated Excel function, with an example on the spreadsheet:

All the functions are listed on the spreadsheet with a short description and a link to the associated on-line help:

The on-line help may also be accessed when entering the function in the spreadsheet, using the “help on this function” link at the bottom-left of the function dialog:

The Multivariate and Discrete functions are also listed on the spreadsheet, with a link to the on-line help for each:

Note that this is a work in progress, and that Excel functions have not yet been created for the Discrete list.

Posted in Arrays, Excel, Link to Python, Maths, Newton, NumPy and SciPy, Python Pandas, PyXLL, UDFs | Tagged , , , , , , , , , | Leave a comment