def test_array_like(self): np.random.seed(54321) x = stats.norm.rvs(size=100, loc=10) lmbda = 1 llf = stats.boxcox_llf(lmbda, x) llf2 = stats.boxcox_llf(lmbda, list(x)) assert_allclose(llf, llf2, rtol=1e-12)
def test_2d_input(self): # Note: boxcox_llf() was already working with 2-D input (sort of), so # keep it like that. boxcox() doesn't work with 2-D input though, due # to brent() returning a scalar. np.random.seed(54321) x = stats.norm.rvs(size=100, loc=10) lmbda = 1 llf = stats.boxcox_llf(lmbda, x) llf2 = stats.boxcox_llf(lmbda, np.vstack([x, x]).T) assert_allclose([llf, llf], llf2, rtol=1e-12)
def generate_box_cox_plot(input, min_lambda): lmbdas = np.linspace(-2, 10) llf = np.zeros(lmbdas.shape, dtype=float) for ii, lmbda in enumerate(lmbdas): llf[ii] = stats.boxcox_llf(lmbda, input) fig = plt.figure() ax = fig.add_subplot(111) ax.plot(lmbdas, llf, 'b.-') ax.axhline(stats.boxcox_llf(min_lambda, input), color='r') ax.set_xlabel('lambda parameter') ax.set_ylabel('Box-Cox log-likelihood') plt.tight_layout()
def test_basic(self): np.random.seed(54321) x = stats.norm.rvs(size=10000, loc=10) lmbda = 1 llf = stats.boxcox_llf(lmbda, x) llf_expected = -x.size / 2. * np.log(np.sum(x.std()**2)) assert_allclose(llf, llf_expected)
def box_cox(datacol, lam_min, lam_max, grain): lam_range = np.linspace(lam_min, lam_max, grain) llf = np.zeros(lam_range.shape, dtype=float) for i, lam in enumerate(lam_range): llf[i] = stats.boxcox_llf(lam, datacol) lam_best = lam_range[llf.argmax()] y = special.boxcox1p(datacol, lam_best) #return the transformed y and the best lamda return y, lam_best
def _boxcox(lib, x): from numpy_sugar import epsilon from scipy.stats import boxcox_llf from scipy.special import boxcox as bc x = lib.asarray(x).astype(float) m = x.min() if m <= 0: m = max(lib.abs(m), epsilon.small) x = x + m + m / 2 lmb = brent(lambda lmb: -boxcox_llf(lmb, x), -5, +5)[0] return bc(x, lmb)
def test_empty(self): assert_(np.isnan(stats.boxcox_llf(1, [])))
from scipy import stats import matplotlib.pyplot as plt from mpl_toolkits.axes_grid1.inset_locator import inset_axes np.random.seed(1245) # Generate some random variates and calculate Box-Cox log-likelihood values # for them for a range of ``lmbda`` values: x = stats.loggamma.rvs(5, loc=10, size=1000) lmbdas = np.linspace(-2, 10) llf = np.zeros(lmbdas.shape, dtype=float) for ii, lmbda in enumerate(lmbdas): llf[ii] = stats.boxcox_llf(lmbda, x) # Also find the optimal lmbda value with `boxcox`: x_most_normal, lmbda_optimal = stats.boxcox(x) # Plot the log-likelihood as function of lmbda. Add the optimal lmbda as a # horizontal line to check that that's really the optimum: fig = plt.figure() ax = fig.add_subplot(111) ax.plot(lmbdas, llf, 'b.-') ax.axhline(stats.boxcox_llf(lmbda_optimal, x), color='r') ax.set_xlabel('lmbda parameter') ax.set_ylabel('Box-Cox log-likelihood') # Now add some probability plots to show that where the log-likelihood is # maximized the data transformed with `boxcox` looks closest to normal:
## 实证 #index_path = r'E:\bookdata\SZ399300.TXT' index_path = r'D:\hot\book\data\SZ399300.TXT' index300 = pd.read_table(index_path,\ encoding = 'cp936',header = None) idx = index300[:-1] idx.columns = ['date', 'o', 'h', 'l', 'c', 'v', 'to'] idx.index = idx['date'] idx['rt'] = idx['c'].pct_change() idx.dropna(inplace=True) # boxcox转换 y = (idx['rt'] + np.abs(idx['rt'].min()) + 0.01) * 100 lam_range = np.linspace(-2, 5, 100) llf = np.zeros(lam_range.shape, dtype=float) for i, lam in enumerate(lam_range): llf[i] = stats.boxcox_llf(lam, y) lam_best = lam_range[llf.argmax()] y_boxcox = special.boxcox1p(y, lam_best) d = y_boxcox.values.reshape(len(idx), 1) training = 250 S = 3 i = 0 actual = [] predict = [] while i + training < len(d): print(i) d_t = d[i:i + training, :] mean_hat, sigma_hat, pi_hat, trans_hat, LT, alpha_T = Baum_Welch_Algorithm( d_t, S) pp = alpha_T.reshape(1, S).dot(trans_hat)
def _eval_mle(lmb, data): # function to minimize return -boxcox_llf(lmb, data)
def main(): parser = argparse.ArgumentParser() parser.add_argument("-i", "--infile", required=True, help="Tabular file.") parser.add_argument("-o", "--outfile", required=True, help="Path to the output file.") parser.add_argument("--sample_one_cols", help="Input format, like smi, sdf, inchi") parser.add_argument("--sample_two_cols", help="Input format, like smi, sdf, inchi") parser.add_argument("--sample_cols", help="Input format, like smi, sdf, inchi,separate arrays using ;") parser.add_argument("--test_id", help="statistical test method") parser.add_argument( "--mwu_use_continuity", action="store_true", default=False, help="Whether a continuity correction (1/2.) should be taken into account.", ) parser.add_argument( "--equal_var", action="store_true", default=False, help="If set perform a standard independent 2 sample test that assumes equal population variances. If not set, perform Welch's t-test, which does not assume equal population variance.", ) parser.add_argument( "--reta", action="store_true", default=False, help="Whether or not to return the internally computed a values." ) parser.add_argument("--fisher", action="store_true", default=False, help="if true then Fisher definition is used") parser.add_argument( "--bias", action="store_true", default=False, help="if false,then the calculations are corrected for statistical bias", ) parser.add_argument("--inclusive1", action="store_true", default=False, help="if false,lower_limit will be ignored") parser.add_argument( "--inclusive2", action="store_true", default=False, help="if false,higher_limit will be ignored" ) parser.add_argument("--inclusive", action="store_true", default=False, help="if false,limit will be ignored") parser.add_argument( "--printextras", action="store_true", default=False, help="If True, if there are extra points a warning is raised saying how many of those points there are", ) parser.add_argument( "--initial_lexsort", action="store_true", default="False", help="Whether to use lexsort or quicksort as the sorting method for the initial sort of the inputs.", ) parser.add_argument("--correction", action="store_true", default=False, help="continuity correction ") parser.add_argument( "--axis", type=int, default=0, help="Axis can equal None (ravel array first), or an integer (the axis over which to operate on a and b)", ) parser.add_argument( "--n", type=int, default=0, help="the number of trials. This is ignored if x gives both the number of successes and failures", ) parser.add_argument("--b", type=int, default=0, help="The number of bins to use for the histogram") parser.add_argument("--N", type=int, default=0, help="Score that is compared to the elements in a.") parser.add_argument("--ddof", type=int, default=0, help="Degrees of freedom correction") parser.add_argument("--score", type=int, default=0, help="Score that is compared to the elements in a.") parser.add_argument("--m", type=float, default=0.0, help="limits") parser.add_argument("--mf", type=float, default=2.0, help="lower limit") parser.add_argument("--nf", type=float, default=99.9, help="higher_limit") parser.add_argument( "--p", type=float, default=0.5, help="The hypothesized probability of success. 0 <= p <= 1. The default value is p = 0.5", ) parser.add_argument("--alpha", type=float, default=0.9, help="probability") parser.add_argument("--new", type=float, default=0.0, help="Value to put in place of values in a outside of bounds") parser.add_argument( "--proportiontocut", type=float, default=0.0, help="Proportion (in range 0-1) of total data set to trim of each end.", ) parser.add_argument( "--lambda_", type=float, default=1.0, help="lambda_ gives the power in the Cressie-Read power divergence statistic", ) parser.add_argument( "--imbda", type=float, default=0, help="If lmbda is not None, do the transformation for that value.If lmbda is None, find the lambda that maximizes the log-likelihood function and return it as the second output argument.", ) parser.add_argument("--base", type=float, default=1.6, help="The logarithmic base to use, defaults to e") parser.add_argument("--dtype", help="dtype") parser.add_argument("--med", help="med") parser.add_argument("--cdf", help="cdf") parser.add_argument("--zero_method", help="zero_method options") parser.add_argument("--dist", help="dist options") parser.add_argument("--ties", help="ties options") parser.add_argument("--alternative", help="alternative options") parser.add_argument("--mode", help="mode options") parser.add_argument("--method", help="method options") parser.add_argument("--md", help="md options") parser.add_argument("--center", help="center options") parser.add_argument("--kind", help="kind options") parser.add_argument("--tail", help="tail options") parser.add_argument("--interpolation", help="interpolation options") parser.add_argument("--statistic", help="statistic options") args = parser.parse_args() infile = args.infile outfile = open(args.outfile, "w+") test_id = args.test_id nf = args.nf mf = args.mf imbda = args.imbda inclusive1 = args.inclusive1 inclusive2 = args.inclusive2 sample0 = 0 sample1 = 0 sample2 = 0 if args.sample_cols != None: sample0 = 1 barlett_samples = [] for sample in args.sample_cols.split(";"): barlett_samples.append(map(int, sample.split(","))) if args.sample_one_cols != None: sample1 = 1 sample_one_cols = args.sample_one_cols.split(",") if args.sample_two_cols != None: sample_two_cols = args.sample_two_cols.split(",") sample2 = 1 for line in open(infile): sample_one = [] sample_two = [] cols = line.strip().split("\t") if sample0 == 1: b_samples = columns_to_values(barlett_samples, line) if sample1 == 1: for index in sample_one_cols: sample_one.append(cols[int(index) - 1]) if sample2 == 1: for index in sample_two_cols: sample_two.append(cols[int(index) - 1]) if test_id.strip() == "describe": size, min_max, mean, uv, bs, bk = stats.describe(map(float, sample_one)) cols.append(size) cols.append(min_max) cols.append(mean) cols.append(uv) cols.append(bs) cols.append(bk) elif test_id.strip() == "mode": vals, counts = stats.mode(map(float, sample_one)) cols.append(vals) cols.append(counts) elif test_id.strip() == "nanmean": m = stats.nanmean(map(float, sample_one)) cols.append(m) elif test_id.strip() == "nanmedian": m = stats.nanmedian(map(float, sample_one)) cols.append(m) elif test_id.strip() == "kurtosistest": z_value, p_value = stats.kurtosistest(map(float, sample_one)) cols.append(z_value) cols.append(p_value) elif test_id.strip() == "variation": ra = stats.variation(map(float, sample_one)) cols.append(ra) elif test_id.strip() == "itemfreq": freq = stats.itemfreq(map(float, sample_one)) for list in freq: elements = ",".join(map(str, list)) cols.append(elements) elif test_id.strip() == "nanmedian": m = stats.nanmedian(map(float, sample_one)) cols.append(m) elif test_id.strip() == "variation": ra = stats.variation(map(float, sample_one)) cols.append(ra) elif test_id.strip() == "boxcox_llf": IIf = stats.boxcox_llf(imbda, map(float, sample_one)) cols.append(IIf) elif test_id.strip() == "tiecorrect": fa = stats.tiecorrect(map(float, sample_one)) cols.append(fa) elif test_id.strip() == "rankdata": r = stats.rankdata(map(float, sample_one), method=args.md) cols.append(r) elif test_id.strip() == "nanstd": s = stats.nanstd(map(float, sample_one), bias=args.bias) cols.append(s) elif test_id.strip() == "anderson": A2, critical, sig = stats.anderson(map(float, sample_one), dist=args.dist) cols.append(A2) for list in critical: cols.append(list) cols.append(",") for list in sig: cols.append(list) elif test_id.strip() == "binom_test": p_value = stats.binom_test(map(float, sample_one), n=args.n, p=args.p) cols.append(p_value) elif test_id.strip() == "gmean": gm = stats.gmean(map(float, sample_one), dtype=args.dtype) cols.append(gm) elif test_id.strip() == "hmean": hm = stats.hmean(map(float, sample_one), dtype=args.dtype) cols.append(hm) elif test_id.strip() == "kurtosis": k = stats.kurtosis(map(float, sample_one), axis=args.axis, fisher=args.fisher, bias=args.bias) cols.append(k) elif test_id.strip() == "moment": n_moment = stats.moment(map(float, sample_one), n=args.n) cols.append(n_moment) elif test_id.strip() == "normaltest": k2, p_value = stats.normaltest(map(float, sample_one)) cols.append(k2) cols.append(p_value) elif test_id.strip() == "skew": skewness = stats.skew(map(float, sample_one), bias=args.bias) cols.append(skewness) elif test_id.strip() == "skewtest": z_value, p_value = stats.skewtest(map(float, sample_one)) cols.append(z_value) cols.append(p_value) elif test_id.strip() == "sem": s = stats.sem(map(float, sample_one), ddof=args.ddof) cols.append(s) elif test_id.strip() == "zscore": z = stats.zscore(map(float, sample_one), ddof=args.ddof) for list in z: cols.append(list) elif test_id.strip() == "signaltonoise": s2n = stats.signaltonoise(map(float, sample_one), ddof=args.ddof) cols.append(s2n) elif test_id.strip() == "percentileofscore": p = stats.percentileofscore(map(float, sample_one), score=args.score, kind=args.kind) cols.append(p) elif test_id.strip() == "bayes_mvs": c_mean, c_var, c_std = stats.bayes_mvs(map(float, sample_one), alpha=args.alpha) cols.append(c_mean) cols.append(c_var) cols.append(c_std) elif test_id.strip() == "sigmaclip": c, c_low, c_up = stats.sigmaclip(map(float, sample_one), low=args.m, high=args.n) cols.append(c) cols.append(c_low) cols.append(c_up) elif test_id.strip() == "kstest": d, p_value = stats.kstest( map(float, sample_one), cdf=args.cdf, N=args.N, alternative=args.alternative, mode=args.mode ) cols.append(d) cols.append(p_value) elif test_id.strip() == "chi2_contingency": chi2, p, dof, ex = stats.chi2_contingency( map(float, sample_one), correction=args.correction, lambda_=args.lambda_ ) cols.append(chi2) cols.append(p) cols.append(dof) cols.append(ex) elif test_id.strip() == "tmean": if nf is 0 and mf is 0: mean = stats.tmean(map(float, sample_one)) else: mean = stats.tmean(map(float, sample_one), (mf, nf), (inclusive1, inclusive2)) cols.append(mean) elif test_id.strip() == "tmin": if mf is 0: min = stats.tmin(map(float, sample_one)) else: min = stats.tmin(map(float, sample_one), lowerlimit=mf, inclusive=args.inclusive) cols.append(min) elif test_id.strip() == "tmax": if nf is 0: max = stats.tmax(map(float, sample_one)) else: max = stats.tmax(map(float, sample_one), upperlimit=nf, inclusive=args.inclusive) cols.append(max) elif test_id.strip() == "tvar": if nf is 0 and mf is 0: var = stats.tvar(map(float, sample_one)) else: var = stats.tvar(map(float, sample_one), (mf, nf), (inclusive1, inclusive2)) cols.append(var) elif test_id.strip() == "tstd": if nf is 0 and mf is 0: std = stats.tstd(map(float, sample_one)) else: std = stats.tstd(map(float, sample_one), (mf, nf), (inclusive1, inclusive2)) cols.append(std) elif test_id.strip() == "tsem": if nf is 0 and mf is 0: s = stats.tsem(map(float, sample_one)) else: s = stats.tsem(map(float, sample_one), (mf, nf), (inclusive1, inclusive2)) cols.append(s) elif test_id.strip() == "scoreatpercentile": if nf is 0 and mf is 0: s = stats.scoreatpercentile( map(float, sample_one), map(float, sample_two), interpolation_method=args.interpolation ) else: s = stats.scoreatpercentile( map(float, sample_one), map(float, sample_two), (mf, nf), interpolation_method=args.interpolation ) for list in s: cols.append(list) elif test_id.strip() == "relfreq": if nf is 0 and mf is 0: rel, low_range, binsize, ex = stats.relfreq(map(float, sample_one), args.b) else: rel, low_range, binsize, ex = stats.relfreq(map(float, sample_one), args.b, (mf, nf)) for list in rel: cols.append(list) cols.append(low_range) cols.append(binsize) cols.append(ex) elif test_id.strip() == "binned_statistic": if nf is 0 and mf is 0: st, b_edge, b_n = stats.binned_statistic( map(float, sample_one), map(float, sample_two), statistic=args.statistic, bins=args.b ) else: st, b_edge, b_n = stats.binned_statistic( map(float, sample_one), map(float, sample_two), statistic=args.statistic, bins=args.b, range=(mf, nf), ) cols.append(st) cols.append(b_edge) cols.append(b_n) elif test_id.strip() == "threshold": if nf is 0 and mf is 0: o = stats.threshold(map(float, sample_one), newval=args.new) else: o = stats.threshold(map(float, sample_one), mf, nf, newval=args.new) for list in o: cols.append(list) elif test_id.strip() == "trimboth": o = stats.trimboth(map(float, sample_one), proportiontocut=args.proportiontocut) for list in o: cols.append(list) elif test_id.strip() == "trim1": t1 = stats.trim1(map(float, sample_one), proportiontocut=args.proportiontocut, tail=args.tail) for list in t1: cols.append(list) elif test_id.strip() == "histogram": if nf is 0 and mf is 0: hi, low_range, binsize, ex = stats.histogram(map(float, sample_one), args.b) else: hi, low_range, binsize, ex = stats.histogram(map(float, sample_one), args.b, (mf, nf)) cols.append(hi) cols.append(low_range) cols.append(binsize) cols.append(ex) elif test_id.strip() == "cumfreq": if nf is 0 and mf is 0: cum, low_range, binsize, ex = stats.cumfreq(map(float, sample_one), args.b) else: cum, low_range, binsize, ex = stats.cumfreq(map(float, sample_one), args.b, (mf, nf)) cols.append(cum) cols.append(low_range) cols.append(binsize) cols.append(ex) elif test_id.strip() == "boxcox_normmax": if nf is 0 and mf is 0: ma = stats.boxcox_normmax(map(float, sample_one)) else: ma = stats.boxcox_normmax(map(float, sample_one), (mf, nf), method=args.method) cols.append(ma) elif test_id.strip() == "boxcox": if imbda is 0: box, ma, ci = stats.boxcox(map(float, sample_one), alpha=args.alpha) cols.append(box) cols.append(ma) cols.append(ci) else: box = stats.boxcox(map(float, sample_one), imbda, alpha=args.alpha) cols.append(box) elif test_id.strip() == "histogram2": h2 = stats.histogram2(map(float, sample_one), map(float, sample_two)) for list in h2: cols.append(list) elif test_id.strip() == "ranksums": z_statistic, p_value = stats.ranksums(map(float, sample_one), map(float, sample_two)) cols.append(z_statistic) cols.append(p_value) elif test_id.strip() == "ttest_1samp": t, prob = stats.ttest_1samp(map(float, sample_one), map(float, sample_two)) for list in t: cols.append(list) for list in prob: cols.append(list) elif test_id.strip() == "ansari": AB, p_value = stats.ansari(map(float, sample_one), map(float, sample_two)) cols.append(AB) cols.append(p_value) elif test_id.strip() == "linregress": slope, intercept, r_value, p_value, stderr = stats.linregress( map(float, sample_one), map(float, sample_two) ) cols.append(slope) cols.append(intercept) cols.append(r_value) cols.append(p_value) cols.append(stderr) elif test_id.strip() == "pearsonr": cor, p_value = stats.pearsonr(map(float, sample_one), map(float, sample_two)) cols.append(cor) cols.append(p_value) elif test_id.strip() == "pointbiserialr": r, p_value = stats.pointbiserialr(map(float, sample_one), map(float, sample_two)) cols.append(r) cols.append(p_value) elif test_id.strip() == "ks_2samp": d, p_value = stats.ks_2samp(map(float, sample_one), map(float, sample_two)) cols.append(d) cols.append(p_value) elif test_id.strip() == "mannwhitneyu": mw_stats_u, p_value = stats.mannwhitneyu( map(float, sample_one), map(float, sample_two), use_continuity=args.mwu_use_continuity ) cols.append(mw_stats_u) cols.append(p_value) elif test_id.strip() == "zmap": z = stats.zmap(map(float, sample_one), map(float, sample_two), ddof=args.ddof) for list in z: cols.append(list) elif test_id.strip() == "ttest_ind": mw_stats_u, p_value = stats.ttest_ind( map(float, sample_one), map(float, sample_two), equal_var=args.equal_var ) cols.append(mw_stats_u) cols.append(p_value) elif test_id.strip() == "ttest_rel": t, prob = stats.ttest_rel(map(float, sample_one), map(float, sample_two), axis=args.axis) cols.append(t) cols.append(prob) elif test_id.strip() == "mood": z, p_value = stats.mood(map(float, sample_one), map(float, sample_two), axis=args.axis) cols.append(z) cols.append(p_value) elif test_id.strip() == "shapiro": W, p_value, a = stats.shapiro(map(float, sample_one), map(float, sample_two), args.reta) cols.append(W) cols.append(p_value) for list in a: cols.append(list) elif test_id.strip() == "kendalltau": k, p_value = stats.kendalltau( map(float, sample_one), map(float, sample_two), initial_lexsort=args.initial_lexsort ) cols.append(k) cols.append(p_value) elif test_id.strip() == "entropy": s = stats.entropy(map(float, sample_one), map(float, sample_two), base=args.base) cols.append(s) elif test_id.strip() == "spearmanr": if sample2 == 1: rho, p_value = stats.spearmanr(map(float, sample_one), map(float, sample_two)) else: rho, p_value = stats.spearmanr(map(float, sample_one)) cols.append(rho) cols.append(p_value) elif test_id.strip() == "wilcoxon": if sample2 == 1: T, p_value = stats.wilcoxon( map(float, sample_one), map(float, sample_two), zero_method=args.zero_method, correction=args.correction, ) else: T, p_value = stats.wilcoxon( map(float, sample_one), zero_method=args.zero_method, correction=args.correction ) cols.append(T) cols.append(p_value) elif test_id.strip() == "chisquare": if sample2 == 1: rho, p_value = stats.chisquare(map(float, sample_one), map(float, sample_two), ddof=args.ddof) else: rho, p_value = stats.chisquare(map(float, sample_one), ddof=args.ddof) cols.append(rho) cols.append(p_value) elif test_id.strip() == "power_divergence": if sample2 == 1: stat, p_value = stats.power_divergence( map(float, sample_one), map(float, sample_two), ddof=args.ddof, lambda_=args.lambda_ ) else: stat, p_value = stats.power_divergence(map(float, sample_one), ddof=args.ddof, lambda_=args.lambda_) cols.append(stat) cols.append(p_value) elif test_id.strip() == "theilslopes": if sample2 == 1: mpe, met, lo, up = stats.theilslopes(map(float, sample_one), map(float, sample_two), alpha=args.alpha) else: mpe, met, lo, up = stats.theilslopes(map(float, sample_one), alpha=args.alpha) cols.append(mpe) cols.append(met) cols.append(lo) cols.append(up) elif test_id.strip() == "combine_pvalues": if sample2 == 1: stat, p_value = stats.combine_pvalues( map(float, sample_one), method=args.med, weights=map(float, sample_two) ) else: stat, p_value = stats.combine_pvalues(map(float, sample_one), method=args.med) cols.append(stat) cols.append(p_value) elif test_id.strip() == "obrientransform": ob = stats.obrientransform(*b_samples) for list in ob: elements = ",".join(map(str, list)) cols.append(elements) elif test_id.strip() == "f_oneway": f_value, p_value = stats.f_oneway(*b_samples) cols.append(f_value) cols.append(p_value) elif test_id.strip() == "kruskal": h, p_value = stats.kruskal(*b_samples) cols.append(h) cols.append(p_value) elif test_id.strip() == "friedmanchisquare": fr, p_value = stats.friedmanchisquare(*b_samples) cols.append(fr) cols.append(p_value) elif test_id.strip() == "fligner": xsq, p_value = stats.fligner(center=args.center, proportiontocut=args.proportiontocut, *b_samples) cols.append(xsq) cols.append(p_value) elif test_id.strip() == "bartlett": T, p_value = stats.bartlett(*b_samples) cols.append(T) cols.append(p_value) elif test_id.strip() == "levene": w, p_value = stats.levene(center=args.center, proportiontocut=args.proportiontocut, *b_samples) cols.append(w) cols.append(p_value) elif test_id.strip() == "median_test": stat, p_value, m, table = stats.median_test( ties=args.ties, correction=args.correction, lambda_=args.lambda_, *b_samples ) cols.append(stat) cols.append(p_value) cols.append(m) cols.append(table) for list in table: elements = ",".join(map(str, list)) cols.append(elements) outfile.write("%s\n" % "\t".join(map(str, cols))) outfile.close()
def main(): parser = argparse.ArgumentParser() parser.add_argument("-i", "--infile", required=True, help="Tabular file.") parser.add_argument("-o", "--outfile", required=True, help="Path to the output file.") parser.add_argument("--sample_one_cols", help="Input format, like smi, sdf, inchi") parser.add_argument("--sample_two_cols", help="Input format, like smi, sdf, inchi") parser.add_argument( "--sample_cols", help="Input format, like smi, sdf, inchi,separate arrays using ;", ) parser.add_argument("--test_id", help="statistical test method") parser.add_argument( "--mwu_use_continuity", action="store_true", default=False, help= "Whether a continuity correction (1/2.) should be taken into account.", ) parser.add_argument( "--equal_var", action="store_true", default=False, help= "If set perform a standard independent 2 sample test that assumes equal population variances. If not set, perform Welch's t-test, which does not assume equal population variance.", ) parser.add_argument( "--reta", action="store_true", default=False, help="Whether or not to return the internally computed a values.", ) parser.add_argument( "--fisher", action="store_true", default=False, help="if true then Fisher definition is used", ) parser.add_argument( "--bias", action="store_true", default=False, help= "if false,then the calculations are corrected for statistical bias", ) parser.add_argument( "--inclusive1", action="store_true", default=False, help="if false,lower_limit will be ignored", ) parser.add_argument( "--inclusive2", action="store_true", default=False, help="if false,higher_limit will be ignored", ) parser.add_argument( "--inclusive", action="store_true", default=False, help="if false,limit will be ignored", ) parser.add_argument( "--printextras", action="store_true", default=False, help= "If True, if there are extra points a warning is raised saying how many of those points there are", ) parser.add_argument( "--initial_lexsort", action="store_true", default="False", help= "Whether to use lexsort or quicksort as the sorting method for the initial sort of the inputs.", ) parser.add_argument( "--correction", action="store_true", default=False, help="continuity correction ", ) parser.add_argument( "--axis", type=int, default=0, help= "Axis can equal None (ravel array first), or an integer (the axis over which to operate on a and b)", ) parser.add_argument( "--n", type=int, default=0, help= "the number of trials. This is ignored if x gives both the number of successes and failures", ) parser.add_argument("--b", type=int, default=0, help="The number of bins to use for the histogram") parser.add_argument("--N", type=int, default=0, help="Score that is compared to the elements in a.") parser.add_argument("--ddof", type=int, default=0, help="Degrees of freedom correction") parser.add_argument( "--score", type=int, default=0, help="Score that is compared to the elements in a.", ) parser.add_argument("--m", type=float, default=0.0, help="limits") parser.add_argument("--mf", type=float, default=2.0, help="lower limit") parser.add_argument("--nf", type=float, default=99.9, help="higher_limit") parser.add_argument( "--p", type=float, default=0.5, help= "The hypothesized probability of success. 0 <= p <= 1. The default value is p = 0.5", ) parser.add_argument("--alpha", type=float, default=0.9, help="probability") parser.add_argument( "--new", type=float, default=0.0, help="Value to put in place of values in a outside of bounds", ) parser.add_argument( "--proportiontocut", type=float, default=0.0, help="Proportion (in range 0-1) of total data set to trim of each end.", ) parser.add_argument( "--lambda_", type=float, default=1.0, help= "lambda_ gives the power in the Cressie-Read power divergence statistic", ) parser.add_argument( "--imbda", type=float, default=0, help= "If lmbda is not None, do the transformation for that value.If lmbda is None, find the lambda that maximizes the log-likelihood function and return it as the second output argument.", ) parser.add_argument( "--base", type=float, default=1.6, help="The logarithmic base to use, defaults to e", ) parser.add_argument("--dtype", help="dtype") parser.add_argument("--med", help="med") parser.add_argument("--cdf", help="cdf") parser.add_argument("--zero_method", help="zero_method options") parser.add_argument("--dist", help="dist options") parser.add_argument("--ties", help="ties options") parser.add_argument("--alternative", help="alternative options") parser.add_argument("--mode", help="mode options") parser.add_argument("--method", help="method options") parser.add_argument("--md", help="md options") parser.add_argument("--center", help="center options") parser.add_argument("--kind", help="kind options") parser.add_argument("--tail", help="tail options") parser.add_argument("--interpolation", help="interpolation options") parser.add_argument("--statistic", help="statistic options") args = parser.parse_args() infile = args.infile outfile = open(args.outfile, "w+") test_id = args.test_id nf = args.nf mf = args.mf imbda = args.imbda inclusive1 = args.inclusive1 inclusive2 = args.inclusive2 sample0 = 0 sample1 = 0 sample2 = 0 if args.sample_cols is not None: sample0 = 1 barlett_samples = [] for sample in args.sample_cols.split(";"): barlett_samples.append(map(int, sample.split(","))) if args.sample_one_cols is not None: sample1 = 1 sample_one_cols = args.sample_one_cols.split(",") if args.sample_two_cols is not None: sample_two_cols = args.sample_two_cols.split(",") sample2 = 1 for line in open(infile): sample_one = [] sample_two = [] cols = line.strip().split("\t") if sample0 == 1: b_samples = columns_to_values(barlett_samples, line) if sample1 == 1: for index in sample_one_cols: sample_one.append(cols[int(index) - 1]) if sample2 == 1: for index in sample_two_cols: sample_two.append(cols[int(index) - 1]) if test_id.strip() == "describe": size, min_max, mean, uv, bs, bk = stats.describe( map(float, sample_one)) cols.append(size) cols.append(min_max) cols.append(mean) cols.append(uv) cols.append(bs) cols.append(bk) elif test_id.strip() == "mode": vals, counts = stats.mode(map(float, sample_one)) cols.append(vals) cols.append(counts) elif test_id.strip() == "nanmean": m = stats.nanmean(map(float, sample_one)) cols.append(m) elif test_id.strip() == "nanmedian": m = stats.nanmedian(map(float, sample_one)) cols.append(m) elif test_id.strip() == "kurtosistest": z_value, p_value = stats.kurtosistest(map(float, sample_one)) cols.append(z_value) cols.append(p_value) elif test_id.strip() == "variation": ra = stats.variation(map(float, sample_one)) cols.append(ra) elif test_id.strip() == "itemfreq": freq = stats.itemfreq(map(float, sample_one)) for list in freq: elements = ",".join(map(str, list)) cols.append(elements) elif test_id.strip() == "nanmedian": m = stats.nanmedian(map(float, sample_one)) cols.append(m) elif test_id.strip() == "variation": ra = stats.variation(map(float, sample_one)) cols.append(ra) elif test_id.strip() == "boxcox_llf": IIf = stats.boxcox_llf(imbda, map(float, sample_one)) cols.append(IIf) elif test_id.strip() == "tiecorrect": fa = stats.tiecorrect(map(float, sample_one)) cols.append(fa) elif test_id.strip() == "rankdata": r = stats.rankdata(map(float, sample_one), method=args.md) cols.append(r) elif test_id.strip() == "nanstd": s = stats.nanstd(map(float, sample_one), bias=args.bias) cols.append(s) elif test_id.strip() == "anderson": A2, critical, sig = stats.anderson(map(float, sample_one), dist=args.dist) cols.append(A2) for list in critical: cols.append(list) cols.append(",") for list in sig: cols.append(list) elif test_id.strip() == "binom_test": p_value = stats.binom_test(map(float, sample_one), n=args.n, p=args.p) cols.append(p_value) elif test_id.strip() == "gmean": gm = stats.gmean(map(float, sample_one), dtype=args.dtype) cols.append(gm) elif test_id.strip() == "hmean": hm = stats.hmean(map(float, sample_one), dtype=args.dtype) cols.append(hm) elif test_id.strip() == "kurtosis": k = stats.kurtosis( map(float, sample_one), axis=args.axis, fisher=args.fisher, bias=args.bias, ) cols.append(k) elif test_id.strip() == "moment": n_moment = stats.moment(map(float, sample_one), n=args.n) cols.append(n_moment) elif test_id.strip() == "normaltest": k2, p_value = stats.normaltest(map(float, sample_one)) cols.append(k2) cols.append(p_value) elif test_id.strip() == "skew": skewness = stats.skew(map(float, sample_one), bias=args.bias) cols.append(skewness) elif test_id.strip() == "skewtest": z_value, p_value = stats.skewtest(map(float, sample_one)) cols.append(z_value) cols.append(p_value) elif test_id.strip() == "sem": s = stats.sem(map(float, sample_one), ddof=args.ddof) cols.append(s) elif test_id.strip() == "zscore": z = stats.zscore(map(float, sample_one), ddof=args.ddof) for list in z: cols.append(list) elif test_id.strip() == "signaltonoise": s2n = stats.signaltonoise(map(float, sample_one), ddof=args.ddof) cols.append(s2n) elif test_id.strip() == "percentileofscore": p = stats.percentileofscore(map(float, sample_one), score=args.score, kind=args.kind) cols.append(p) elif test_id.strip() == "bayes_mvs": c_mean, c_var, c_std = stats.bayes_mvs(map(float, sample_one), alpha=args.alpha) cols.append(c_mean) cols.append(c_var) cols.append(c_std) elif test_id.strip() == "sigmaclip": c, c_low, c_up = stats.sigmaclip(map(float, sample_one), low=args.m, high=args.n) cols.append(c) cols.append(c_low) cols.append(c_up) elif test_id.strip() == "kstest": d, p_value = stats.kstest( map(float, sample_one), cdf=args.cdf, N=args.N, alternative=args.alternative, mode=args.mode, ) cols.append(d) cols.append(p_value) elif test_id.strip() == "chi2_contingency": chi2, p, dof, ex = stats.chi2_contingency( map(float, sample_one), correction=args.correction, lambda_=args.lambda_) cols.append(chi2) cols.append(p) cols.append(dof) cols.append(ex) elif test_id.strip() == "tmean": if nf == 0 and mf == 0: mean = stats.tmean(map(float, sample_one)) else: mean = stats.tmean(map(float, sample_one), (mf, nf), (inclusive1, inclusive2)) cols.append(mean) elif test_id.strip() == "tmin": if mf == 0: min = stats.tmin(map(float, sample_one)) else: min = stats.tmin(map(float, sample_one), lowerlimit=mf, inclusive=args.inclusive) cols.append(min) elif test_id.strip() == "tmax": if nf == 0: max = stats.tmax(map(float, sample_one)) else: max = stats.tmax(map(float, sample_one), upperlimit=nf, inclusive=args.inclusive) cols.append(max) elif test_id.strip() == "tvar": if nf == 0 and mf == 0: var = stats.tvar(map(float, sample_one)) else: var = stats.tvar(map(float, sample_one), (mf, nf), (inclusive1, inclusive2)) cols.append(var) elif test_id.strip() == "tstd": if nf == 0 and mf == 0: std = stats.tstd(map(float, sample_one)) else: std = stats.tstd(map(float, sample_one), (mf, nf), (inclusive1, inclusive2)) cols.append(std) elif test_id.strip() == "tsem": if nf == 0 and mf == 0: s = stats.tsem(map(float, sample_one)) else: s = stats.tsem(map(float, sample_one), (mf, nf), (inclusive1, inclusive2)) cols.append(s) elif test_id.strip() == "scoreatpercentile": if nf == 0 and mf == 0: s = stats.scoreatpercentile( map(float, sample_one), map(float, sample_two), interpolation_method=args.interpolation, ) else: s = stats.scoreatpercentile( map(float, sample_one), map(float, sample_two), (mf, nf), interpolation_method=args.interpolation, ) for list in s: cols.append(list) elif test_id.strip() == "relfreq": if nf == 0 and mf == 0: rel, low_range, binsize, ex = stats.relfreq( map(float, sample_one), args.b) else: rel, low_range, binsize, ex = stats.relfreq( map(float, sample_one), args.b, (mf, nf)) for list in rel: cols.append(list) cols.append(low_range) cols.append(binsize) cols.append(ex) elif test_id.strip() == "binned_statistic": if nf == 0 and mf == 0: st, b_edge, b_n = stats.binned_statistic( map(float, sample_one), map(float, sample_two), statistic=args.statistic, bins=args.b, ) else: st, b_edge, b_n = stats.binned_statistic( map(float, sample_one), map(float, sample_two), statistic=args.statistic, bins=args.b, range=(mf, nf), ) cols.append(st) cols.append(b_edge) cols.append(b_n) elif test_id.strip() == "threshold": if nf == 0 and mf == 0: o = stats.threshold(map(float, sample_one), newval=args.new) else: o = stats.threshold(map(float, sample_one), mf, nf, newval=args.new) for list in o: cols.append(list) elif test_id.strip() == "trimboth": o = stats.trimboth(map(float, sample_one), proportiontocut=args.proportiontocut) for list in o: cols.append(list) elif test_id.strip() == "trim1": t1 = stats.trim1( map(float, sample_one), proportiontocut=args.proportiontocut, tail=args.tail, ) for list in t1: cols.append(list) elif test_id.strip() == "histogram": if nf == 0 and mf == 0: hi, low_range, binsize, ex = stats.histogram( map(float, sample_one), args.b) else: hi, low_range, binsize, ex = stats.histogram( map(float, sample_one), args.b, (mf, nf)) cols.append(hi) cols.append(low_range) cols.append(binsize) cols.append(ex) elif test_id.strip() == "cumfreq": if nf == 0 and mf == 0: cum, low_range, binsize, ex = stats.cumfreq( map(float, sample_one), args.b) else: cum, low_range, binsize, ex = stats.cumfreq( map(float, sample_one), args.b, (mf, nf)) cols.append(cum) cols.append(low_range) cols.append(binsize) cols.append(ex) elif test_id.strip() == "boxcox_normmax": if nf == 0 and mf == 0: ma = stats.boxcox_normmax(map(float, sample_one)) else: ma = stats.boxcox_normmax(map(float, sample_one), (mf, nf), method=args.method) cols.append(ma) elif test_id.strip() == "boxcox": if imbda == 0: box, ma, ci = stats.boxcox(map(float, sample_one), alpha=args.alpha) cols.append(box) cols.append(ma) cols.append(ci) else: box = stats.boxcox(map(float, sample_one), imbda, alpha=args.alpha) cols.append(box) elif test_id.strip() == "histogram2": h2 = stats.histogram2(map(float, sample_one), map(float, sample_two)) for list in h2: cols.append(list) elif test_id.strip() == "ranksums": z_statistic, p_value = stats.ranksums(map(float, sample_one), map(float, sample_two)) cols.append(z_statistic) cols.append(p_value) elif test_id.strip() == "ttest_1samp": t, prob = stats.ttest_1samp(map(float, sample_one), map(float, sample_two)) for list in t: cols.append(list) for list in prob: cols.append(list) elif test_id.strip() == "ansari": AB, p_value = stats.ansari(map(float, sample_one), map(float, sample_two)) cols.append(AB) cols.append(p_value) elif test_id.strip() == "linregress": slope, intercept, r_value, p_value, stderr = stats.linregress( map(float, sample_one), map(float, sample_two)) cols.append(slope) cols.append(intercept) cols.append(r_value) cols.append(p_value) cols.append(stderr) elif test_id.strip() == "pearsonr": cor, p_value = stats.pearsonr(map(float, sample_one), map(float, sample_two)) cols.append(cor) cols.append(p_value) elif test_id.strip() == "pointbiserialr": r, p_value = stats.pointbiserialr(map(float, sample_one), map(float, sample_two)) cols.append(r) cols.append(p_value) elif test_id.strip() == "ks_2samp": d, p_value = stats.ks_2samp(map(float, sample_one), map(float, sample_two)) cols.append(d) cols.append(p_value) elif test_id.strip() == "mannwhitneyu": mw_stats_u, p_value = stats.mannwhitneyu( map(float, sample_one), map(float, sample_two), use_continuity=args.mwu_use_continuity, ) cols.append(mw_stats_u) cols.append(p_value) elif test_id.strip() == "zmap": z = stats.zmap(map(float, sample_one), map(float, sample_two), ddof=args.ddof) for list in z: cols.append(list) elif test_id.strip() == "ttest_ind": mw_stats_u, p_value = stats.ttest_ind(map(float, sample_one), map(float, sample_two), equal_var=args.equal_var) cols.append(mw_stats_u) cols.append(p_value) elif test_id.strip() == "ttest_rel": t, prob = stats.ttest_rel(map(float, sample_one), map(float, sample_two), axis=args.axis) cols.append(t) cols.append(prob) elif test_id.strip() == "mood": z, p_value = stats.mood(map(float, sample_one), map(float, sample_two), axis=args.axis) cols.append(z) cols.append(p_value) elif test_id.strip() == "shapiro": W, p_value, a = stats.shapiro(map(float, sample_one), map(float, sample_two), args.reta) cols.append(W) cols.append(p_value) for list in a: cols.append(list) elif test_id.strip() == "kendalltau": k, p_value = stats.kendalltau( map(float, sample_one), map(float, sample_two), initial_lexsort=args.initial_lexsort, ) cols.append(k) cols.append(p_value) elif test_id.strip() == "entropy": s = stats.entropy(map(float, sample_one), map(float, sample_two), base=args.base) cols.append(s) elif test_id.strip() == "spearmanr": if sample2 == 1: rho, p_value = stats.spearmanr(map(float, sample_one), map(float, sample_two)) else: rho, p_value = stats.spearmanr(map(float, sample_one)) cols.append(rho) cols.append(p_value) elif test_id.strip() == "wilcoxon": if sample2 == 1: T, p_value = stats.wilcoxon( map(float, sample_one), map(float, sample_two), zero_method=args.zero_method, correction=args.correction, ) else: T, p_value = stats.wilcoxon( map(float, sample_one), zero_method=args.zero_method, correction=args.correction, ) cols.append(T) cols.append(p_value) elif test_id.strip() == "chisquare": if sample2 == 1: rho, p_value = stats.chisquare(map(float, sample_one), map(float, sample_two), ddof=args.ddof) else: rho, p_value = stats.chisquare(map(float, sample_one), ddof=args.ddof) cols.append(rho) cols.append(p_value) elif test_id.strip() == "power_divergence": if sample2 == 1: stat, p_value = stats.power_divergence( map(float, sample_one), map(float, sample_two), ddof=args.ddof, lambda_=args.lambda_, ) else: stat, p_value = stats.power_divergence(map(float, sample_one), ddof=args.ddof, lambda_=args.lambda_) cols.append(stat) cols.append(p_value) elif test_id.strip() == "theilslopes": if sample2 == 1: mpe, met, lo, up = stats.theilslopes(map(float, sample_one), map(float, sample_two), alpha=args.alpha) else: mpe, met, lo, up = stats.theilslopes(map(float, sample_one), alpha=args.alpha) cols.append(mpe) cols.append(met) cols.append(lo) cols.append(up) elif test_id.strip() == "combine_pvalues": if sample2 == 1: stat, p_value = stats.combine_pvalues( map(float, sample_one), method=args.med, weights=map(float, sample_two), ) else: stat, p_value = stats.combine_pvalues(map(float, sample_one), method=args.med) cols.append(stat) cols.append(p_value) elif test_id.strip() == "obrientransform": ob = stats.obrientransform(*b_samples) for list in ob: elements = ",".join(map(str, list)) cols.append(elements) elif test_id.strip() == "f_oneway": f_value, p_value = stats.f_oneway(*b_samples) cols.append(f_value) cols.append(p_value) elif test_id.strip() == "kruskal": h, p_value = stats.kruskal(*b_samples) cols.append(h) cols.append(p_value) elif test_id.strip() == "friedmanchisquare": fr, p_value = stats.friedmanchisquare(*b_samples) cols.append(fr) cols.append(p_value) elif test_id.strip() == "fligner": xsq, p_value = stats.fligner(center=args.center, proportiontocut=args.proportiontocut, *b_samples) cols.append(xsq) cols.append(p_value) elif test_id.strip() == "bartlett": T, p_value = stats.bartlett(*b_samples) cols.append(T) cols.append(p_value) elif test_id.strip() == "levene": w, p_value = stats.levene(center=args.center, proportiontocut=args.proportiontocut, *b_samples) cols.append(w) cols.append(p_value) elif test_id.strip() == "median_test": stat, p_value, m, table = stats.median_test( ties=args.ties, correction=args.correction, lambda_=args.lambda_, *b_samples) cols.append(stat) cols.append(p_value) cols.append(m) cols.append(table) for list in table: elements = ",".join(map(str, list)) cols.append(elements) outfile.write("%s\n" % "\t".join(map(str, cols))) outfile.close()
outliers_num = [364, 365, 368, 370, 371, 372, 380, 405, 410, 418] else: outliers_num = np.union1d(outliers_num_leverage, outliers_num_cook_distance) outliers_num = np.union1d(outliers_num, outliers_num_s) lm_remove = sm.OLS(y_remove, sm.add_constant(X_remove)).fit() X_remove = np.delete(X, outliers_num, 0) y_remove = np.delete(y, outliers_num, 0) s_remove = np.delete(s, outliers_num, 0) # Page1 n_interval = 50 lmbda_list = np.linspace(-2, 2, n_interval) llf_list = np.zeros(n_interval) for i in range(lmbda_list.shape[0]): llf_list[i] = stats.boxcox_llf(lmbda_list[i], y_remove) fig, ax = plt.subplots(figsize=(8,4)) plt.plot(lmbda_list, llf_list) plt.xlabel('Lambda value') plt.ylabel('Log likelihood') plt.title('Box-Cox Transformation Curve') plt.show() # Page 2 # Generate diagnostic plots before removing outliers before = True # Change this variable to False to generate diagnostic plot after removing outliers if before: model_residuals = lm.resid model_norm_residuals = lm.get_influence().resid_studentized_internal model_leverage = lm.get_influence().hat_matrix_diag model_cooks = lm.get_influence().cooks_distance[0]