Metadata-Version: 2.1
Name: timemachines
Version: 0.8.10
Summary: Evaluation and standardization of popular time series packages
Home-page: https://github.com/microprediction/timemachines
Author: microprediction
Author-email: pcotton@intechinvestments.com
License: MIT
Description: # timemachines ![tests](https://github.com/microprediction/timemachines/workflows/tests/badge.svg)![tsa](https://github.com/microprediction/timemachines/workflows/test-tsa/badge.svg)  ![prophet](https://github.com/microprediction/timemachines/workflows/test-prophet/badge.svg) ![orbit](https://github.com/microprediction/timemachines/workflows/test-orbit/badge.svg)  ![neuralprophet](https://github.com/microprediction/timemachines/workflows/test-neuralprophet/badge.svg) ![pmd](https://github.com/microprediction/timemachines/workflows/test-pmd/badge.svg) ![pydlm](https://github.com/microprediction/timemachines/workflows/test-pydlm/badge.svg) ![elo-ratings](https://github.com/microprediction/timeseries-elo-ratings/workflows/timeseries-elo-ratings/badge.svg)   ![License: MIT](https://img.shields.io/badge/License-MIT-yellow.svg)
        
        ## Fast, incremental, pure-functional, time-series forecasting ([article](https://www.microprediction.com/blog/timemachines))
        Use popular forecasting packages with one line of code, or view their [Elo ratings](https://microprediction.github.io/timeseries-elo-ratings/html_leaderboards/univariate-k_003.html)
        
        What's different:
        
           - **Simple canonical functional use** of *some* functionality from packages like fbprophet, pmdarima, tsa, pmdarima, neuralprophet and their ilk. Sadly most of these are slow but...
        
           - **Simple fast accurate alternatives** to popular time series packages that are often faster, lighter and more accurate (e.g. [thinking](https://github.com/microprediction/timemachines/blob/main/timemachines/skaters/simple/thinking.py))
        
           - **Simple, ongoing empirical evaluation**. See the [leaderboards](https://microprediction.github.io/timeseries-elo-ratings/html_leaderboards/univariate-k_003.html) in
            the accompanying repository [timeseries-elo-ratings](https://github.com/microprediction/timeseries-elo-ratings). Assessment is always out of sample and uses *live*, constantly updating real-world data 
             from [microprediction.org](https://www.microprediction.org/browse_streams.html).   
        
           - **Simple k-step ahead forecasts** in functional style involving [one line of code](https://github.com/microprediction/timemachines/blob/main/timemachines/skaters/proph/prophskaterscomposed.py). 
           
           - **Simple tuning** with [one line of code](https://github.com/microprediction/timemachines/blob/main/timemachines/skatertools/tuning/hyper.py) facilitated by [HumpDay](https://github.com/microprediction/humpday), which provides canonical functional use of scipy.optimize, ax-platform,
           hyperopt, optuna, platypus, pymoo, pySOT, skopt, dlib, nlopt, bayesian-optimization, nevergrad and more. 
        
           
           - **Simple evaluation** with [one line of code](https://github.com/microprediction/timemachines/blob/main/timemachines/skatertools/evaluation/evaluators.py) using
            metrics like RMSE or energy distances. 
            
           - **Simple stacking** of models with [one line of code](https://github.com/microprediction/timemachines/blob/main/timemachines/skaters/simple/thinking.py). The functional
           form makes other types of model combination easy as well.  
        
          
          - **Simpler deployment**. There is no state, other that that explicitly returned to the caller. For many models state is a pure Python dictionary and thus
          trivially converted to JSON and back. 
        
        **NO CLASSES**  **NO DATAFRAMES** **NO CEREMONY**   
        
        Nothing to slow you down!
        
        Here time series "models" are plain old functions. Those functions have a "skater" signature, facilitating "[skating](https://github.com/microprediction/timemachines/blob/main/timemachines/skating.py)".
           One might say that skater functions *suggest* state machines for sequential assimilation of observations (as a data point arrives, 
            forecasts for 1,2,...,k steps ahead, with corresponding standard deviations are emitted). However here the *caller* is expected to maintain state from one 
            invocation (data point) to the next. See the [FAQ](https://github.com/microprediction/timemachines/blob/main/FAQ.md) if this seems odd. 
        
        ![](https://i.imgur.com/elu5muO.png)
        
        ### New contributor guide:
            
        See  [CONTRIBUTE.md](https://github.com/microprediction/timemachines/blob/main/CONTRIBUTE.md)
        
        ### Running a model and plotting it 
        
            from timemachines.skatertools.data import hospital_with_exog
            from timemachines.skatertools.visualization.priorplot import prior_plot
            import matplotlib.pyplot as plt
            
            # Get some data - including variables known in advance:
            k = 1
            y, a = hospital_with_exog(k=k, n=450, offset=True)
            
            # Run the model and plot it 
            prior_plot(f=fbprophet_exogenous, k=k, y=y, n=450, n_plot=50)
            
            plt.show()
        
        ## The Skater signature 
        
              x, w, s = f(   y:Union[float,[float]],               # Contemporaneously observerd data, 
                                                                 # ... including exogenous variables in y[1:], if any. 
                        s=None,                                  # Prior state
                        k:float=1,                               # Number of steps ahead to forecast. Typically integer. 
                        a:[float]=None,                          # Variable(s) known in advance, or conditioning
                        t:float=None,                            # Time of observation (epoch seconds)
                        e:float=None,                            # Non-binding maximal computation time ("e for expiry"), in seconds
                        r:float=None)                            # Hyper-parameters ("r" stands for for hype(r)-pa(r)amete(r)s in R^n)
        
        The function is intended to be applied repeatedly. For example one could harvest
        a sequence of the model predictions as follows:
        
            def posteriors(f,y):
                s = {}       
                x = list()
                for yi in y: 
                    xi, xi_std, s = f(yi,s)
                    x.append(xi)
                return x
         
         or see the prominently positioned [skating.py](https://github.com/microprediction/timemachines/blob/main/timemachines/skating.py). Notice the use of s={} on first invocation. 
         
        ### Skater "y" argument
        
        A skater function *f* takes a vector *y*, where the quantity to be predicted is y[0] and there may be other, simultaneously observed
         variables y[1:] deemed helpful in predicting y[0].
        
        ### Skater "s" argument
         
        The state. Pass empty dict the first time. 
        
        ### Skater "k" argument 
        
        Determines the length of the term structure of predictions (and also their standard deviations) that will be returned. This cannot be varied from
        one invocation to the next. 
        
        ### Skater "a" argument 
        
        A vector of known-in-advance variables. 
        
        ### Skater "t" argument 
        
        Epoch time of the observation. 
        
        ### Skater "e" argument ("expiry")
        
        Seconds allowed for computation. See remark below. 
           
        ## Skater "r" argument ("hype(r) pa(r)amete(r)s")
        
        A scalar in the closed interval \[0,1\] represents *all* hyper-parameters. See comments below. 
        
        ### Return values
        
        Two vectors and the posterior state. The first set of *k* numbers can be *interpreted* as a point estimate (but need not be) and the second is *typically* suggestive of a symmetric error std, or width. However a broader interpretation is possible wherein a skater *suggests* a useful affine transformation of the incoming data and nothing more.  
        
        
                  -> x     [float],    # A vector of point estimates, or anchor points, or theos
                     x_std [float]     # A vector of "scale" quantities (such as a standard deviation of expected forecast errors) 
                     s    Any,         # Posterior state, intended for safe keeping by the callee until the next invocation 
                               
        
        In returning state, the intent is that the *caller* might carry the state from one invocation to the next verbatim. This is arguably more convenient than having the predicting object maintain state, because the caller can "freeze" the state as they see fit, as 
        when making conditional predictions. This also eyes lambda-based deployments and *encourages* tidy use of internal state - not that we succeed
         when calling down to statsmodels (though prophet, and others including the home grown models use simple dictionaries, making serialization trivial). 
         
        You'll notice also that parameter use seems limited. This is deliberate. A skater is morally a "bound" model (i.e. fixed hyper-parameters) and ready to use. Any fitting, estimation or updating is the skater's internal responsibility. That said, it is sometimes useful to enlarge the skater concept to include hyper-parameters, as this enourages a more standardized way to expose and fit them. It remains the responsibility of the skater designer to ensure that the parameter space is folded into (0,1) is a somewhat sensible way. 
        
        The use of a single scalar for hyper-parameters may seem unnatural, but is slighly less unnatural if [conventions](https://github.com/microprediction/timemachines/blob/main/timemachines/skatertools/utilities/conventions.py) are followed that inflate \[0,1\] into the square \[0,1\]^2 or the cube \[0,1\]^3. See the functions **to_space** and **from_space**. This also makes it trivial for anyone to design black box optimization routines that can work on any skater, without knowing its working. The humpday package makes this trivial - albeit time-consuming. 
        
        The use of *e* is a fairly *weak* convention that many skaters ignore. In theory, a large expiry *e* can be used as a hint to the callee that
         there is time enough to do a 'fit', which we might define as anything taking longer than the usual function invocation. A zero might suggest that there isn't even time for a "proper" prediction to be made, and we are still in the burn-in period as far as assessment or usage is concerned. However, this is between the caller and it's priest really - or its prophet we should say. Some skaters, such
         as the Facebook prophet skater, do a full 'fit' every invocation so this is meaningless. Other skaters don't even have a separate notion of 'fit' versus 'update' because everything is incremental. 
            
        ### Summary of conventions: 
        
        - State
            - The caller, not the callee, persists state from one invocation to the next
            - The caller passes s={} the first time, and the callee initializes state
            - State can be mutable for efficiency (e.g. it might be a long buffer) or not. 
            - State should, ideally, be JSON-friendly. 
               
        - Observations: target, and contemporaneous exogenous
             - If y is a vector, the target is the first element y[0]
             - The elements y[1:] are contemporaneous exogenous variables, *not known in advance*.  
             - Missing data can be supplied to some skaters, as np.nan.  
             - Most skaters will accept scalar *y* and *a* if there is only one of either. 
            
        - Variables known k-steps in advance, or conditioning variables:
             - Pass the *vector* argument *a* that will occur in k-steps time (not the contemporaneous one)
             - Remark: In the case of k=1 there are different interpretations that are possible beyond "business day", such as "size of a trade" or "joystick up" etc. 
        
        - Hyper-Parameter space:
             - A float *r* in (0,1). 
             - This package provides functions *to_space* and *from_space*, for expanding to R^n using space filling curves, so that the callee's (hyper) parameter optimization can still exploit geometry, if it wants to.   
             
        See [FAQ](https://github.com/microprediction/timemachines/blob/main/FAQ.md) or file an issue if anything offends you greatly. 
         
        ### Related illustrations 
        
        - See [examples](https://github.com/microprediction/timemachines/tree/main/examples) 
        
        ## Install
        
        We've moved to bare-bones dependencies because some timeseries packages are not keeping up with changes to dependent packages (as with STAN releases), or operating system or hardware quirks (like Apple M1 for example), and 
        also because the statistical evidence for their inclusion is less than overwhelming ([ahem](https://www.microprediction.com/blog/prophet). So ...
        
            pip install --upgrade pip
            pip install timemachines
            
        This gives you access to the home grown packages and to scipy/tsa models. Those perform well. The popular packages and some others are not added by default. But add them manually if you want to use them:
        
            pip install prophet
            pip install neuralprophet
            pip install pydlm
            pip install divinity
            pip install pmdarima
            
        Add matplotlib if you want to use plotting utilities provides
        
            pip install matplotlib 
        
        Add microprediction if you want to use live data
        
            pip install microprediction   
        
        ### Apple M1
        
        A fluid situation. You might try adding the pip argument to skip pep517 if you run into trouble on M1 chips
        
            pip install whatever --no-use-pep517
        
            
        ### Tuning hyper-params
        
        - See [examples/tuning](https://github.com/microprediction/timemachines/tree/main/examples/tuning)
        - See [tuning](https://github.com/microprediction/timemachines/tree/main/timemachines/skatertools/tuning)
            
        ## Contribute 
        
        If you'd like to contribute to this standardizing and benchmarking effort, here are some ideas:
        
        - See the [list of popular time series packages](https://www.microprediction.com/blog/popular-timeseries-packages) ranked by download popularity. 
        - Think about the most important hyper-parameters and consider "warming up" the mapping (0,1)->hyper-params by testing on real data. There is a [tutorial](https://www.microprediction.com/python-3) on retrieving live data, or use the [real data](https://pypi.org/project/realdata/) package, if that's simpler.
        - The [comparison of hyper-parameter optimization packages](https://www.microprediction.com/blog/optimize) might also be helpful.  
        
        If you are the maintainer of a time series package, we'd love your feedback and if you take the time to submit a PR here that incorporates your library, do yourself a favor and also enable "supporting" on your repo. Nothing here is put forward
           as *the right way* to write time series packages - more a way of exposing their functionality for comparisons. 
          If you are interested in design thoughts for time series maybe participate in this [thread](https://github.com/MaxBenChrist/awesome_time_series_in_python/issues/1). 
        
        ## FAQ 
        See [FAQ](https://github.com/microprediction/timemachines/blob/main/FAQ.md)
        
Platform: UNKNOWN
Classifier: License :: OSI Approved :: MIT License
Classifier: Programming Language :: Python :: 3
Classifier: Programming Language :: Python :: 3.7
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