spatiotemporal_w_nohrf
¶
Classes and functions for fitting SpatioTemporal population receptive field models
SpatioTemporalFit (model, data, grids, bounds, Ns) |
A spatiotemporal population receptive field fit class |
SpatioTemporalModel (stimulus, hrf_model) |
A Gaussian population receptive field model class |
PopulationFit
¶
-
class
popeye.spatiotemporal_w_nohrf.
PopulationFit
(model, data, grids, bounds, Ns, voxel_index, auto_fit, verbose)¶ Bases:
object
Base class for all pRF model fits.
-
__init__
(model, data, grids, bounds, Ns, voxel_index, auto_fit, verbose)¶ A class containing tools for fitting pRF models.
The PopulationFit class houses all the fitting tool that are associated with estimatinga pRF model. The PopulationFit takes a PoulationModel instance model and a time-series data. In addition, extent and sampling-rate of a brute-force grid-search is set with grids and Ns. Use bounds to set limits on the search space for each parameter.
- model : AuditoryModel class instance
- An object representing the 1D Gaussian model.
- data : ndarray
- An array containing the measured BOLD signal of a single voxel.
- grids : tuple
A tuple indicating the search space for the brute-force grid-search. The tuple contains pairs of upper and lower bounds for exploring a given dimension. For example grids=((-10,10),(0,5),) will search the first dimension from -10 to 10 and the second from 0 to 5. These values cannot be None.
For more information, see scipy.optimize.brute.
- bounds : tuple
- A tuple containing the upper and lower bounds for each parameter in parameters. If a parameter is not bounded, simply use None. For example, fit_bounds=((0,None),(-10,10),) would bound the first parameter to be any positive number while the second parameter would be bounded between -10 and 10.
- Ns : int
Number of samples per stimulus dimension to sample during the ballpark search.
For more information, see scipy.optimize.brute.
- voxel_index : tuple
- A tuple containing the index of the voxel being modeled. The fitting procedure does not require a voxel index, but collating the results across many voxels will does require voxel indices. With voxel indices, the brain volume can be reconstructed using the newly computed model estimates.
- auto_fit : bool
- A flag for automatically running the fitting procedures once the GaussianFit object is instantiated.
- verbose : int
- 0 = silent 1 = print the final solution of an error-minimization 2 = print each error-minimization step
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Jout
()¶
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allvecs
()¶
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ballpark
()¶
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brute_force
()¶
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direc
()¶
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estimate
()¶
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fopt
()¶
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funcalls
()¶
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fval
()¶
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gradient_descent
()¶
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grid
()¶
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iter
()¶
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msg
()¶
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overloaded_estimate
()¶
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prediction
()¶
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rsquared
()¶
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rss
()¶
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PopulationModel
¶
-
class
popeye.spatiotemporal_w_nohrf.
PopulationModel
(stimulus, hrf_model, nuissance=None)¶ Bases:
object
Base class for all pRF models.
-
__init__
(stimulus, hrf_model, nuissance=None)¶ Base class for all pRF models.
- stimulus : StimulusModel class instance
- An instance of the StimulusModel class containing the stim_arr and various stimulus parameters, and can represent various stimulus modalities, including visual, auditory, etc.
- hrf_model : callable
- A function that generates an HRF model given an HRF delay. For more information, see popeye.utilties.double_gamma_hrf_hrf and `popeye.utilities.spm_hrf
- nuissance : ndarray
- A nuissance regressor for removing effects of non-interest. You can regress out any nuissance effects from you data prior to fitting the model of interest. The nuissance model is a statsmodels.OLS compatible design matrix, and the user is expected to have already added any constants.
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generate_ballpark_prediction
()¶
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generate_prediction
()¶
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SpatioTemporalFit
¶
-
class
popeye.spatiotemporal_w_nohrf.
SpatioTemporalFit
(model, data, grids, bounds, Ns, voxel_index=(1, 2, 3), auto_fit=True, verbose=0)¶ Bases:
popeye.base.PopulationFit
A spatiotemporal population receptive field fit class
-
__init__
(model, data, grids, bounds, Ns, voxel_index=(1, 2, 3), auto_fit=True, verbose=0)¶
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baseline
()¶
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baseline0
()¶
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beta
()¶
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beta0
()¶
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overloaded_estimate
()¶
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prediction
()¶
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receptive_field
()¶
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rho
()¶
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sigma
()¶
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sigma0
()¶
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theta
()¶
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weight
()¶
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weight0
()¶
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x
()¶
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x0
()¶
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y
()¶
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y0
()¶
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SpatioTemporalModel
¶
-
class
popeye.spatiotemporal_w_nohrf.
SpatioTemporalModel
(stimulus, hrf_model)¶ Bases:
popeye.base.PopulationModel
A Gaussian population receptive field model class
-
__init__
(stimulus, hrf_model)¶ A spatiotemporal population receptive field model.
- stimulus : VisualStimulus class object
- A class instantiation of the VisualStimulus class containing a representation of the visual stimulus.
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center
()¶
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flickers
()¶
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generate_ballpark_prediction
(x, y, sigma, weight, beta, baseline)¶
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generate_prediction
(x, y, sigma, weight, beta, baseline)¶
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m
()¶
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m_resp
()¶
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m_rf
(tau)¶
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p
()¶
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p_resp
()¶
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p_rf
(tau)¶
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t
()¶
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auto_attr¶
-
popeye.spatiotemporal_w_nohrf.
auto_attr
(func)¶ Decorator to create OneTimeProperty attributes.
- func : method
- The method that will be called the first time to compute a value. Afterwards, the method’s name will be a standard attribute holding the value of this computation.
>>> class MagicProp(object): ... @auto_attr ... def a(self): ... return 99 ... >>> x = MagicProp() >>> 'a' in x.__dict__ False >>> x.a 99 >>> 'a' in x.__dict__ True
fftconvolve¶
-
popeye.spatiotemporal_w_nohrf.
fftconvolve
(in1, in2, mode='full')¶ Convolve two N-dimensional arrays using FFT.
Convolve in1 and in2 using the fast Fourier transform method, with the output size determined by the mode argument.
This is generally much faster than convolve for large arrays (n > ~500), but can be slower when only a few output values are needed, and can only output float arrays (int or object array inputs will be cast to float).
- in1 : array_like
- First input.
- in2 : array_like
- Second input. Should have the same number of dimensions as in1; if sizes of in1 and in2 are not equal then in1 has to be the larger array.
- mode : str {‘full’, ‘valid’, ‘same’}, optional
A string indicating the size of the output:
full
- The output is the full discrete linear convolution of the inputs. (Default)
valid
- The output consists only of those elements that do not rely on the zero-padding.
same
- The output is the same size as in1, centered with respect to the ‘full’ output.
- out : array
- An N-dimensional array containing a subset of the discrete linear convolution of in1 with in2.
generate_og_receptive_field¶
-
popeye.spatiotemporal_w_nohrf.
generate_og_receptive_field
()¶ Generate a Gaussian.
- x : float
- The x coordinate of the center of the Gaussian (degrees)
- y : float
- The y coordinate of the center of the Gaussian (degrees)
- s : float
- The dispersion of the Gaussian (degrees)
- beta : float
- The amplitude of the Gaussian
- deg_x : 2D array
- The coordinate matrix along the horizontal dimension of the display (degrees)
- deg_y : 2D array
- The coordinate matrix along the vertical dimension of the display (degrees)
Returns
- stim : ndarray
- The 1D array containing the stimulus energies given the Gaussian coordinates
linregress¶
-
popeye.spatiotemporal_w_nohrf.
linregress
(x, y=None)¶ Calculate a regression line
This computes a least-squares regression for two sets of measurements.
- x, y : array_like
- two sets of measurements. Both arrays should have the same length. If only x is given (and y=None), then it must be a two-dimensional array where one dimension has length 2. The two sets of measurements are then found by splitting the array along the length-2 dimension.
- slope : float
- slope of the regression line
- intercept : float
- intercept of the regression line
- r-value : float
- correlation coefficient
- p-value : float
- two-sided p-value for a hypothesis test whose null hypothesis is that the slope is zero.
- stderr : float
- Standard error of the estimate
>>> from scipy import stats >>> import numpy as np >>> x = np.random.random(10) >>> y = np.random.random(10) >>> slope, intercept, r_value, p_value, std_err = stats.linregress(x,y)
# To get coefficient of determination (r_squared)
>>> print "r-squared:", r_value**2 r-squared: 0.15286643777
simps¶
-
popeye.spatiotemporal_w_nohrf.
simps
(y, x=None, dx=1, axis=-1, even='avg')¶ Integrate y(x) using samples along the given axis and the composite Simpson’s rule. If x is None, spacing of dx is assumed.
If there are an even number of samples, N, then there are an odd number of intervals (N-1), but Simpson’s rule requires an even number of intervals. The parameter ‘even’ controls how this is handled.
- y : array_like
- Array to be integrated.
- x : array_like, optional
- If given, the points at which y is sampled.
- dx : int, optional
- Spacing of integration points along axis of y. Only used when x is None. Default is 1.
- axis : int, optional
- Axis along which to integrate. Default is the last axis.
- even : {‘avg’, ‘first’, ‘str’}, optional
- ‘avg’ : Average two results:1) use the first N-2 intervals with
- a trapezoidal rule on the last interval and 2) use the last N-2 intervals with a trapezoidal rule on the first interval.
- ‘first’ : Use Simpson’s rule for the first N-2 intervals with
- a trapezoidal rule on the last interval.
- ‘last’ : Use Simpson’s rule for the last N-2 intervals with a
- trapezoidal rule on the first interval.
quad: adaptive quadrature using QUADPACK romberg: adaptive Romberg quadrature quadrature: adaptive Gaussian quadrature fixed_quad: fixed-order Gaussian quadrature dblquad: double integrals tplquad: triple integrals romb: integrators for sampled data cumtrapz: cumulative integration for sampled data ode: ODE integrators odeint: ODE integrators
For an odd number of samples that are equally spaced the result is exact if the function is a polynomial of order 3 or less. If the samples are not equally spaced, then the result is exact only if the function is a polynomial of order 2 or less.
trapz¶
-
popeye.spatiotemporal_w_nohrf.
trapz
(y, x=None, dx=1.0, axis=-1)¶ Integrate along the given axis using the composite trapezoidal rule.
Integrate y (x) along given axis.
- y : array_like
- Input array to integrate.
- x : array_like, optional
- The sample points corresponding to the y values. If x is None, the sample points are assumed to be evenly spaced dx apart. The default is None.
- dx : scalar, optional
- The spacing between sample points when x is None. The default is 1.
- axis : int, optional
- The axis along which to integrate.
- trapz : float
- Definite integral as approximated by trapezoidal rule.
sum, cumsum
Image [2] illustrates trapezoidal rule – y-axis locations of points will be taken from y array, by default x-axis distances between points will be 1.0, alternatively they can be provided with x array or with dx scalar. Return value will be equal to combined area under the red lines.
[1] Wikipedia page: http://en.wikipedia.org/wiki/Trapezoidal_rule [2] Illustration image: http://en.wikipedia.org/wiki/File:Composite_trapezoidal_rule_illustration.png >>> np.trapz([1,2,3]) 4.0 >>> np.trapz([1,2,3], x=[4,6,8]) 8.0 >>> np.trapz([1,2,3], dx=2) 8.0 >>> a = np.arange(6).reshape(2, 3) >>> a array([[0, 1, 2], [3, 4, 5]]) >>> np.trapz(a, axis=0) array([ 1.5, 2.5, 3.5]) >>> np.trapz(a, axis=1) array([ 2., 8.])