A short tutorial on the esoreader module

This post explains how to use the esoreader, a python module for parsing the .eso file produced by EnergyPlus. It also includes a small (incomplete) reverse engineering of the .eso file format.

EnergyPlus is a whole building simulation tool EnergyPlus is a whole building energy simulation program that engineers, architects, and researchers use to model energy and water use in buildings. The .eso file is the main output file produced by EnergyPlus and is normally parsed by tools that come with the EnergyPlus suit of tools. The esoreader module lets you read in the time series data in python scripts, which for my research is quite useful. I published the module thinking other people might want to do so too.

Last week I got an email about how the documentation on the pypi page for the esoreader module is rather… terse. So I went to check the esoreader page and yes, there is not a lot of documentation. The example code I published was this:

import esoreader
PATH_TO_ESO = r'/Path/To/EnergyPlus/Output/eplusout.eso'
dd, data = esoreader.read(PATH_TO_ESO)
frequency, key, variable = dd.find_variable(
    'Zone Ventilation Total Heat Loss Energy')[0]
idx = dd.index[frequency, key, variable]
time_series = data[idx] 

What can I say? There is not much more you can do with esoreader. I think the best way to understand the module is to look at the .eso file format:

The eso file format starts of with a header section called the “data dictionary” (I used the variable dd in the example code for that). The first few lines of a sample eso file look something like this:

Program Version,EnergyPlus-Windows-32 8.1.0.009, YMD=2014.03.20 14:18
1,5,Environment Title[],Latitude[deg],Longitude[deg],Time Zone[],Elevation[m]
2,6,Day of Simulation[],Month[],Day of Month[],DST Indicator[1=yes 0=no],Hour[],StartMinute[],EndMinute[],DayType
3,3,Cumulative Day of Simulation[],Month[],Day of Month[],DST Indicator[1=yes 0=no],DayType  ! When Daily Report Variables Requested
4,2,Cumulative Days of Simulation[],Month[]  ! When Monthly Report Variables Requested
5,1,Cumulative Days of Simulation[] ! When Run Period Report Variables Requested
6,1,DEFAULT_ZONE,Zone Outdoor Air Drybulb Temperature [C] !TimeStep
99,1,DPVWALL:1157026,Surface Outside Face Temperature [C] !TimeStep
100,1,DPVWINDOW:COMBINED:DPVWALL:1157026:DEFAULTWINDOWCONSTRUCTION,Surface Outside Face Temperature [C] !TimeStep
101,1,DPVWALL:1157027,Surface Outside Face Temperature [C] !TimeStep
102,1,DPVWINDOW:COMBINED:DPVWALL:1157027:DEFAULTWINDOWCONSTRUCTION,Surface Outside Face Temperature [C] !TimeStep
103,1,DPVWALL:1157028,Surface Outside Face Temperature [C] !TimeStep
104,1,DPVWINDOW:COMBINED:DPVWALL:1157028:DEFAULTWINDOWCONSTRUCTION,Surface Outside Face Temperature [C] !TimeStep
105,1,DPVWALL:1157029,Surface Outside Face Temperature [C] !TimeStep
106,1,DPVWINDOW:COMBINED:DPVWALL:1157029:DEFAULTWINDOWCONSTRUCTION,Surface Outside Face Temperature [C] !TimeStep
107,1,DPVFLOOR:1157042,Surface Outside Face Temperature [C] !TimeStep
108,1,DPVROOF:1157058.0,Surface Outside Face Temperature [C] !TimeStep
109,1,DPVROOF:1157058.1,Surface Outside Face Temperature [C] !TimeStep
110,1,DPVROOF:1157058.2,Surface Outside Face Temperature [C] !TimeStep
111,1,DPVROOF:1157058.3,Surface Outside Face Temperature [C] !TimeStep
112,1,DEFAULT_ZONE,Zone Mean Air Temperature [C] !TimeStep
278,1,DEFAULT_ZONEZONEHVAC:IDEALLOADSAIRSYSTEM,Zone Ideal Loads Zone Total Heating Energy [J] !TimeStep
279,1,DEFAULT_ZONEZONEHVAC:IDEALLOADSAIRSYSTEM,Zone Ideal Loads Zone Total Cooling Energy [J] !TimeStep
End of Data Dictionary

The first line is stored in the DataDictionary object (dd) as version and timestamp. After that, each line represents a variable being reported. Each such variable has an index, a number of values being reported and then a reporting frequency. Well… the first few lines (indexes 1 through 5) are a bit special and I just discard them. The rest of the data dictionary lines are built like this:

  • index (e.g. 100)
  • column count (is always one as far as I can tell)
  • key (the same variable can be measured for different keys, as per the Output:Variable object in the IDF file) (e.g. “DPVWINDOW:COMBINED:DPVWALL:1157026:DEFAULTWINDOWCONSTRUCTION”, a surface name in one of my models)
  • variable name (e.g. “Surface Outisde Face Temperature”)
  • unit (e.g. “C”)
  • reporting frequency (e.g. “TimeStep”)

These get parsed into a DataDictionary object and stored in the attributes variables and index.

variables = dict of ids, int => [reporting_frequency,
                                 key, variable, unit]

index = dict {(key, variable, reporting_frequency) => id)}

here is an example (I’m using the IPython shell, in case you’re wondering about the In [71] line - check it out! it is awesome!!)

In [71]: dd.variables.items()[1]
Out[71]:
(100,
 ['TimeStep',
  'DPVWINDOW:COMBINED:DPVWALL:1157026:DEFAULTWINDOWCONSTRUCTION',
  'Surface Outside Face Temperature',
  'C'])

The DataDictionary object has a method find_variable. Say, you want to find the variable for ‘Zone Mean Air Temperature’:

In [75]: dd.find_variable('Zone Mean Air Temperature')
Out[75]: [('TimeStep', 'DEFAULT_ZONE', 'Zone Mean Air Temperature')]

Notice how the result is a list? If you had looked for surface temperatures instead:

In [76]: dd.find_variable('surface')
Out[76]:
[('TimeStep', 'DPVROOF:1157058.1', 'Surface Outside Face Temperature'),
 ('TimeStep', 'DPVWALL:1157029', 'Surface Outside Face Temperature'),
 ('TimeStep',
  'DPVWINDOW:COMBINED:DPVWALL:1157029:DEFAULTWINDOWCONSTRUCTION',
  'Surface Outside Face Temperature'),
 ('TimeStep', 'DPVWALL:1157028', 'Surface Outside Face Temperature'),
 ('TimeStep', 'DPVROOF:1157058.3', 'Surface Outside Face Temperature'),
 ('TimeStep', 'DPVROOF:1157058.0', 'Surface Outside Face Temperature'),
 ('TimeStep',
  'DPVWINDOW:COMBINED:DPVWALL:1157028:DEFAULTWINDOWCONSTRUCTION',
  'Surface Outside Face Temperature'),
 ('TimeStep',
  'DPVWINDOW:COMBINED:DPVWALL:1157026:DEFAULTWINDOWCONSTRUCTION',
  'Surface Outside Face Temperature'),
 ('TimeStep', 'DPVWALL:1157027', 'Surface Outside Face Temperature'),
 ('TimeStep',
  'DPVWINDOW:COMBINED:DPVWALL:1157027:DEFAULTWINDOWCONSTRUCTION',
  'Surface Outside Face Temperature'),
 ('TimeStep', 'DPVFLOOR:1157042', 'Surface Outside Face Temperature'),
 ('TimeStep', 'DPVWALL:1157026', 'Surface Outside Face Temperature'),
 ('TimeStep', 'DPVROOF:1157058.2', 'Surface Outside Face Temperature')]

you’d have gotten a list of all variables that match ‘surface’ (case-insensitive, substring match). The tuples define the variable you’re looking for: Frequency, key and variable name, since you can have the same variable output for different frequencies and keys!

So the index of the variable we’re looking for (Zone Mean Air Temperature) can be found like this:

In [77]: dd.index['TimeStep', 'DEFAULT_ZONE', 'Zone Mean Air Temperature']
Out[77]: 112

When you parse an .eso file, you get two values back: The DataDictionary and the data itself, which is stored in a simple dictionary mapping the variable index to the timeseries data:

In [82]: dd, data = esoreader.read('RevitToCitySim_fmibeta.eso')

In [84]: data[112]
Out[84]:
[19.9999999999999,
 20.0,
 20.0,
 20.0,
 20.0,
 20.0,
 20.0,

Where does that data come from? From the rest of the .eso file, which looks like this:

1,Zuerich-SMA - - TMY2-66600 WMO#=,  47.38,   8.57,   1.00, 556.00
2,1, 1, 1, 0, 1, 0.00,60.00,Tuesday        
6,-9.733141026918536E-003
99,4.22860281958676
100,2.29752216466107
101,4.62549195332972
102,2.48360878690238
103,4.45346228786434
104,2.40363283464546
105,4.29531948374435
106,2.37522804444541
107,18.
108,4.50377052140968
109,4.62335191215081
110,4.38341749556803
111,4.62165617120029
112,19.9999999999999
278,69070426.0448551
279,2.200249582529068E-006
2,1, 1, 1, 0, 2, 0.00,60.00,Tuesday        
6,-20.0097331410269
99,-3.72067959222121
100,-11.9333570144822
101,-3.2185453285921
102,-11.9539672821419
103,-3.21604754356428
104,-11.6999602208759
105,-3.69978393125912
106,-12.1422252778574
107,18.
108,-0.183133489472591
109,0.134352957894094
110,-0.291113509003108
111,9.541793763769267E-002
112,20.
278,12241499.5530833
279,0.0
2,1, 1, 1, 0, 3, 0.00,60.00,Tuesday        
6,-20.0097331410269
99,-8.25275818278861
100,-10.9050845966823

For all the main variables (id > 5) the format is:

  • index
  • value

Thus, the data dictionary is necessary to figure out what variables (with what frequency) are being output.

To sum up the tutorial: The code on the pypi page shows you pretty much all you can do and also all you need to do to retrieve a specific timeseries from an .eso file:

  • read in the eso file to obtain the data dictionary and the data
  • find the key, frequency and variable name you need in the data dictionary (with find_variable) or by guessing from your IDF input
  • retrieve the index of that variable
  • retrieve the time series data using that index

(this post was originally published on blogspot)

Written on December 22, 2014