diff --git a/lib/node_modules/@stdlib/math/base/special/cinvf/test/test.native.js b/lib/node_modules/@stdlib/math/base/special/cinvf/test/test.native.js
index 073d46af2cfe..78ea840dc701 100644
--- a/lib/node_modules/@stdlib/math/base/special/cinvf/test/test.native.js
+++ b/lib/node_modules/@stdlib/math/base/special/cinvf/test/test.native.js
@@ -100,7 +100,7 @@ tape( 'the function computes a complex inverse', opts, function test( t ) {
 			t.strictEqual( imag( q ), qim[ i ], 'returns expected imaginary component' );
 		} else {
 			delta = absf( imag( q ) - qim[ i ] );
-			tol = EPS * absf( qim[ i ] );
+			tol = 5 * EPS * absf( qim[ i ] );
 			t.ok( delta <= tol, 'within tolerance. x: '+re[i]+'+ '+im[i]+'i. imag: '+imag( q )+'. expected: '+qim[i]+'. delta: '+delta+'. tol: '+tol+'.' );
 		}
 	}
@@ -136,7 +136,7 @@ tape( 'the function computes a complex inverse (large negative imaginary compone
 			t.strictEqual( imag( q ), qim[ i ], 'returns expected imaginary component' );
 		} else {
 			delta = absf( imag( q ) - qim[ i ] );
-			tol = EPS * absf( qim[ i ] );
+			tol = 5 * EPS * absf( qim[ i ] );
 			t.ok( delta <= tol, 'within tolerance. x: '+re[i]+'+ '+im[i]+'i. imag: '+imag( q )+'. expected: '+qim[i]+'. delta: '+delta+'. tol: '+tol+'.' );
 		}
 	}
@@ -172,7 +172,7 @@ tape( 'the function computes a complex inverse (large negative real components)'
 			t.strictEqual( imag( q ), qim[ i ], 'returns expected imaginary component' );
 		} else {
 			delta = absf( imag( q ) - qim[ i ] );
-			tol = EPS * absf( qim[ i ] );
+			tol = 5 * EPS * absf( qim[ i ] );
 			t.ok( delta <= tol, 'within tolerance. x: '+re[i]+'+ '+im[i]+'i. imag: '+imag( q )+'. expected: '+qim[i]+'. delta: '+delta+'. tol: '+tol+'.' );
 		}
 	}
@@ -208,7 +208,7 @@ tape( 'the function computes a complex inverse (large positive imaginary compone
 			t.strictEqual( imag( q ), qim[ i ], 'returns expected imaginary component' );
 		} else {
 			delta = absf( imag( q ) - qim[ i ] );
-			tol = EPS * absf( qim[ i ] );
+			tol = 5 * EPS * absf( qim[ i ] );
 			t.ok( delta <= tol, 'within tolerance. x: '+re[i]+'+ '+im[i]+'i. imag: '+imag( q )+'. expected: '+qim[i]+'. delta: '+delta+'. tol: '+tol+'.' );
 		}
 	}
@@ -244,7 +244,7 @@ tape( 'the function computes a complex inverse (large positive real components)'
 			t.strictEqual( imag( q ), qim[ i ], 'returns expected imaginary component' );
 		} else {
 			delta = absf( imag( q ) - qim[ i ] );
-			tol = EPS * absf( qim[ i ] );
+			tol = 5 * EPS * absf( qim[ i ] );
 			t.ok( delta <= tol, 'within tolerance. x: '+re[i]+'+ '+im[i]+'i. imag: '+imag( q )+'. expected: '+qim[i]+'. delta: '+delta+'. tol: '+tol+'.' );
 		}
 	}
@@ -280,7 +280,7 @@ tape( 'the function computes a complex inverse (tiny negative imaginary componen
 			t.strictEqual( imag( q ), qim[ i ], 'returns expected imaginary component' );
 		} else {
 			delta = absf( imag( q ) - qim[ i ] );
-			tol = EPS * absf( qim[ i ] );
+			tol = 5 * EPS * absf( qim[ i ] );
 			t.ok( delta <= tol, 'within tolerance. x: '+re[i]+'+ '+im[i]+'i. imag: '+imag( q )+'. expected: '+qim[i]+'. delta: '+delta+'. tol: '+tol+'.' );
 		}
 	}
@@ -316,7 +316,7 @@ tape( 'the function computes a complex inverse (tiny negative real components)',
 			t.strictEqual( imag( q ), qim[ i ], 'returns expected imaginary component' );
 		} else {
 			delta = absf( imag( q ) - qim[ i ] );
-			tol = EPS * absf( qim[ i ] );
+			tol = 5 * EPS * absf( qim[ i ] );
 			t.ok( delta <= tol, 'within tolerance. x: '+re[i]+'+ '+im[i]+'i. imag: '+imag( q )+'. expected: '+qim[i]+'. delta: '+delta+'. tol: '+tol+'.' );
 		}
 	}
@@ -352,7 +352,7 @@ tape( 'the function computes a complex inverse (tiny positive imaginary componen
 			t.strictEqual( imag( q ), qim[ i ], 'returns expected imaginary component' );
 		} else {
 			delta = absf( imag( q ) - qim[ i ] );
-			tol = EPS * absf( qim[ i ] );
+			tol = 5 * EPS * absf( qim[ i ] );
 			t.ok( delta <= tol, 'within tolerance. x: '+re[i]+'+ '+im[i]+'i. imag: '+imag( q )+'. expected: '+qim[i]+'. delta: '+delta+'. tol: '+tol+'.' );
 		}
 	}
@@ -388,7 +388,7 @@ tape( 'the function computes a complex inverse (tiny positive real components)',
 			t.strictEqual( imag( q ), qim[ i ], 'returns expected imaginary component' );
 		} else {
 			delta = absf( imag( q ) - qim[ i ] );
-			tol = EPS * absf( qim[ i ] );
+			tol = 5 * EPS * absf( qim[ i ] );
 			t.ok( delta <= tol, 'within tolerance. x: '+re[i]+'+ '+im[i]+'i. imag: '+imag( q )+'. expected: '+qim[i]+'. delta: '+delta+'. tol: '+tol+'.' );
 		}
 	}