abs (x, /)
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Calculates the absolute value for each element x_i of the input array x . |
acos (x, /)
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Calculates an implementation-dependent approximation of the principal value of the inverse cosine for each element x_i of the input array x . |
acosh (x, /)
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Calculates an implementation-dependent approximation to the inverse hyperbolic cosine for each element x_i of the input array x . |
add (x1, x2, /)
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Calculates the sum for each element x1_i of the input array x1 with the respective element x2_i of the input array x2 . |
asin (x, /)
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Calculates an implementation-dependent approximation of the principal value of the inverse sine for each element x_i of the input array x . |
asinh (x, /)
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Calculates an implementation-dependent approximation to the inverse hyperbolic sine for each element x_i in the input array x . |
atan (x, /)
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Calculates an implementation-dependent approximation of the principal value of the inverse tangent for each element x_i of the input array x . |
atan2 (x1, x2, /)
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Calculates an implementation-dependent approximation of the inverse tangent of the quotient x1/x2 , having domain [-infinity, +infinity] x [-infinity, +infinity] (where the x notation denotes the set of ordered pairs of elements (x1_i, x2_i) ) and codomain [-π, +π] , for each pair of elements (x1_i, x2_i) of the input arrays x1 and x2 , respectively. |
atanh (x, /)
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Calculates an implementation-dependent approximation to the inverse hyperbolic tangent for each element x_i of the input array x . |
bitwise_and (x1, x2, /)
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Computes the bitwise AND of the underlying binary representation of each element x1_i of the input array x1 with the respective element x2_i of the input array x2 . |
bitwise_left_shift (x1, x2, /)
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Shifts the bits of each element x1_i of the input array x1 to the left by appending x2_i (i.e., the respective element in the input array x2 ) zeros to the right of x1_i . |
bitwise_invert (x, /)
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Inverts (flips) each bit for each element x_i of the input array x . |
bitwise_or (x1, x2, /)
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Computes the bitwise OR of the underlying binary representation of each element x1_i of the input array x1 with the respective element x2_i of the input array x2 . |
bitwise_right_shift (x1, x2, /)
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Shifts the bits of each element x1_i of the input array x1 to the right according to the respective element x2_i of the input array x2 . |
bitwise_xor (x1, x2, /)
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Computes the bitwise XOR of the underlying binary representation of each element x1_i of the input array x1 with the respective element x2_i of the input array x2 . |
ceil (x, /)
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Rounds each element x_i of the input array x to the smallest (i.e., closest to -infinity ) integer-valued number that is not less than x_i . |
clip (x, /, min=None, max=None)
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Clamps each element x_i of the input array x to the range [min, max] . |
conj (x, /)
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Returns the complex conjugate for each element x_i of the input array x . |
copysign (x1, x2, /)
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Composes a floating-point value with the magnitude of x1_i and the sign of x2_i for each element of the input array x1 . |
cos (x, /)
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Calculates an implementation-dependent approximation to the cosine for each element x_i of the input array x . |
cosh (x, /)
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Calculates an implementation-dependent approximation to the hyperbolic cosine for each element x_i in the input array x . |
divide (x1, x2, /)
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Calculates the division of each element x1_i of the input array x1 with the respective element x2_i of the input array x2 . |
equal (x1, x2, /)
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Computes the truth value of x1_i == x2_i for each element x1_i of the input array x1 with the respective element x2_i of the input array x2 . |
exp (x, /)
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Calculates an implementation-dependent approximation to the exponential function for each element x_i of the input array x (e raised to the power of x_i , where e is the base of the natural logarithm). |
expm1 (x, /)
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Calculates an implementation-dependent approximation to exp(x)-1 for each element x_i of the input array x . |
floor (x, /)
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Rounds each element x_i of the input array x to the greatest (i.e., closest to +infinity ) integer-valued number that is not greater than x_i . |
floor_divide (x1, x2, /)
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Rounds the result of dividing each element x1_i of the input array x1 by the respective element x2_i of the input array x2 to the greatest (i.e., closest to +infinity ) integer-value number that is not greater than the division result. |
greater (x1, x2, /)
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Computes the truth value of x1_i > x2_i for each element x1_i of the input array x1 with the respective element x2_i of the input array x2 . |
greater_equal (x1, x2, /)
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Computes the truth value of x1_i >= x2_i for each element x1_i of the input array x1 with the respective element x2_i of the input array x2 . |
hypot (x1, x2, /)
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Computes the square root of the sum of squares for each element x1_i of the input array x1 with the respective element x2_i of the input array x2 . |
imag (x, /)
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Returns the imaginary component of a complex number for each element x_i of the input array x . |
isfinite (x, /)
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Tests each element x_i of the input array x to determine if finite. |
isinf (x, /)
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Tests each element x_i of the input array x to determine if equal to positive or negative infinity. |
isnan (x, /)
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Tests each element x_i of the input array x to determine whether the element is NaN . |
less (x1, x2, /)
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Computes the truth value of x1_i < x2_i for each element x1_i of the input array x1 with the respective element x2_i of the input array x2 . |
less_equal (x1, x2, /)
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Computes the truth value of x1_i <= x2_i for each element x1_i of the input array x1 with the respective element x2_i of the input array x2 . |
log (x, /)
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Calculates an implementation-dependent approximation to the natural (base e ) logarithm for each element x_i of the input array x . |
log1p (x, /)
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Calculates an implementation-dependent approximation to log(1+x) , where log refers to the natural (base e ) logarithm, for each element x_i of the input array x . |
log2 (x, /)
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Calculates an implementation-dependent approximation to the base 2 logarithm for each element x_i of the input array x . |
log10 (x, /)
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Calculates an implementation-dependent approximation to the base 10 logarithm for each element x_i of the input array x . |
logaddexp (x1, x2, /)
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Calculates the logarithm of the sum of exponentiations log(exp(x1) + exp(x2)) for each element x1_i of the input array x1 with the respective element x2_i of the input array x2 . |
logical_and (x1, x2, /)
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Computes the logical AND for each element x1_i of the input array x1 with the respective element x2_i of the input array x2 . |
logical_not (x, /)
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Computes the logical NOT for each element x_i of the input array x . |
logical_or (x1, x2, /)
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Computes the logical OR for each element x1_i of the input array x1 with the respective element x2_i of the input array x2 . |
logical_xor (x1, x2, /)
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Computes the logical XOR for each element x1_i of the input array x1 with the respective element x2_i of the input array x2 . |
maximum (x1, x2, /)
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Computes the maximum value for each element x1_i of the input array x1 relative to the respective element x2_i of the input array x2 . |
minimum (x1, x2, /)
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Computes the minimum value for each element x1_i of the input array x1 relative to the respective element x2_i of the input array x2 . |
multiply (x1, x2, /)
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Calculates the product for each element x1_i of the input array x1 with the respective element x2_i of the input array x2 . |
negative (x, /)
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Computes the numerical negative of each element x_i (i.e., y_i = -x_i ) of the input array x . |
not_equal (x1, x2, /)
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Computes the truth value of x1_i != x2_i for each element x1_i of the input array x1 with the respective element x2_i of the input array x2 . |
positive (x, /)
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Computes the numerical positive of each element x_i (i.e., y_i = +x_i ) of the input array x . |
pow (x1, x2, /)
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Calculates an implementation-dependent approximation of exponentiation by raising each element x1_i (the base) of the input array x1 to the power of x2_i (the exponent), where x2_i is the corresponding element of the input array x2 . |
real (x, /)
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Returns the real component of a complex number for each element x_i of the input array x . |
remainder (x1, x2, /)
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Returns the remainder of division for each element x1_i of the input array x1 and the respective element x2_i of the input array x2 . |
round (x, /)
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Rounds each element x_i of the input array x to the nearest integer-valued number. |
sign (x, /)
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Returns an indication of the sign of a number for each element x_i of the input array x . |
signbit (x, /)
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Determines whether the sign bit is set for each element x_i of the input array x . |
sin (x, /)
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Calculates an implementation-dependent approximation to the sine for each element x_i of the input array x . |
sinh (x, /)
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Calculates an implementation-dependent approximation to the hyperbolic sine for each element x_i of the input array x . |
square (x, /)
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Squares each element x_i of the input array x . |
sqrt (x, /)
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Calculates the principal square root for each element x_i of the input array x . |
subtract (x1, x2, /)
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Calculates the difference for each element x1_i of the input array x1 with the respective element x2_i of the input array x2 . |
tan (x, /)
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Calculates an implementation-dependent approximation to the tangent for each element x_i of the input array x . |
tanh (x, /)
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Calculates an implementation-dependent approximation to the hyperbolic tangent for each element x_i of the input array x . |
trunc (x, /)
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Rounds each element x_i of the input array x to the nearest integer-valued number that is closer to zero than x_i . |