ddrg/math_formulas · Datasets at Hugging Face

id int64 -30,985 55.9k	text stringlengths 5 437k
10,063	e^x = \sum_{n=0}^\infty x^n/n! > \tfrac{1}{n!}\cdot x^n
29,508	-z\cdot (\epsilon + g) = (g + \epsilon)\cdot (-z)
-19,476	2/3\cdot \frac71 = 2\cdot \frac13/(\tfrac{1}{7})
19,028	\frac{3*5}{2}8 = 60
8,603	\frac{\frac{1}{6}}{\frac16 + 5 \cdot \dfrac16/7} = 7/12
-24,757	\cos{13\cdot \pi/12} = \frac{1}{4}\cdot \left(-\sqrt{6} - \sqrt{2}\right)
5,356	z \Rightarrow (z^2 - 3 \cdot z + 1)^2 - 3 \cdot (z^2 - 3 \cdot z + 1) + 1 = z^2 - 3 \cdot z + 1 = z
8,632	\alpha x^9 \cdot \left(x + 1\right) = x^9 \alpha + \alpha x^{10}
6,081	x x + z^2 \alpha^2 + \alpha z x*2 = (x + z \alpha)^2
47,283	3*3! = 18
9,048	\left( 5, 9, 0\right) = ( x, y, \nu) + ( 2, 1, -5) \Rightarrow ( 2 + x, 1 + y, \nu + 5 \cdot (-1)) = \left( 5, 9, 0\right)
13,958	(1 + z + z^2)^n = (\frac{1 - z^3}{1 - z})^n = \left(1 - z^3\right)^n \cdot \left(1 - z\right)^{-n}
-29,016	0.48\cdot 23.9 = 11.472
-9,158	49(-1) - 7k = -77 - k7
5,341	\frac{1}{2} \cdot m = \frac{1}{2^m} \cdot 2^{m + (-1)} \cdot m
42,178	k + 1 + n + 1 = k + n + 1 + 1
15,792	(e^{i\cdot \theta})^n = e^{i\cdot n\cdot \theta} = \cos{n\cdot \theta} + i\cdot \sin{n\cdot \theta}
-7,930	\frac{1}{41} \cdot (72 + 8 \cdot i - 90 \cdot i + 10) = (82 - 82 \cdot i)/41 = 2 - 2 \cdot i
19,599	(f\cdot b)^{i + 2} = f^{i + 2}\cdot b^{i + 2} = f^{i + 1}\cdot f\cdot b^{i + 1}\cdot b
4,534	3 \left((-1) + x x\right) + 4 = 1 + x^2 \cdot 3
11,689	2 \times 2^k = 2^{k + 1} \times ...
23,383	3/514/52 + 4/51\frac{48}{52} = \frac{1}{52}*4
6,806	\frac{24}{24 + 10} = \frac{1}{34} \cdot 24 = \frac{12}{17}
4,798	beb = beb
22,913	x^l = \left((x^{1/q})^q\right)^l = (x^{1/q})^{q \cdot l}
3,881	(3\cdot z + 1)\cdot (1 + z)^4 = 1 + 7\cdot z + 18\cdot z^2 + z \cdot z^2\cdot 22 + 13\cdot z^4 + 3\cdot z^5
-11,432	(z + 2(-1))^2 + h = (z + 2\left(-1\right))(z + 2(-1)) + h = z * z - 4*z + 4 + h
929	x^2 + xb \Rightarrow -(\frac{1}{2}b)^2 + (x + b/2) * (x + b/2)
23,445	(b + 1) \times (b + 1) = b \times b + 2 \times b + 1 = b^2 + 1 = b^1 + 1 - b \times b + b + 1 = -b = -b = b
14,236	k \cdot y = (k + 0) \cdot y = k \cdot y + 0 \cdot y
31,649	0 = p^2 \implies p = 0
7,751	2\times (\arctan(\infty) - \arctan\left(-\infty\right)) = 2\times \pi
20,199	e^{Y + R} = e^R e^Y \implies 0 = (R, Y)
9,966	\dfrac{1 - r^{n + 1}}{1 - r} = \frac{1}{1 - r}*(1 - r^{1 + n})
13,742	1 + 3^{1 + k} = 1 + 3^k\cdot 3
30,259	B = \sqrt{B*A} \Rightarrow 0 = B\text{ or }B = A
7,829	\theta = \frac{180}{\pi} \cdot \theta \cdot \tfrac{1}{180} \cdot \pi
29,354	h > -1 rightarrow 0 < 1 + h
33,595	20^2 + 21 \cdot 21 = 29^2
21,456	\frac{1}{0 (-1) + 1} = 1
27,719	\cos(f_1 + f_2) = \cos(f_1) \cdot \cos(f_2) - \sin(f_1) \cdot \sin(f_2)
28,257	64z^29 = 249z z = 216*z^2
15,202	\mathbb{E}(Z) = \mathbb{E}(\sum_{i=1}^l Z_i) = \sum_{i=1}^l \mathbb{E}(Z_i)
14,830	\frac{1}{12}\left(2^6 + 82^2 + 32^22^2\right) = 12
30,257	4^{2n} + (-1) = 16^n + (-1) = (16 + (-1)) (16^{n + (-1)} + 16^{n + 2(-1)} + ... + 1)
-23,163	-5/4 \cdot 2 = -5/2
4,796	(b \cdot \tfrac{a}{b})^2 = b \cdot a \cdot b \cdot \frac{a}{b}/b = b \cdot \frac{a^2}{b}
20,810	((1 + x)^l)^2 = \left(1 + x\right)^{2l}
22,400	\dfrac{1}{f\cdot 4}\cdot (\vartheta\cdot f\cdot 4 + f^2\cdot y^2\cdot 4 + 4\cdot f\cdot U\cdot y) = \vartheta + f\cdot y^2 + y\cdot U
31,819	e^t = 1 + t + t^2/2! + \dotsm > \frac{t^2}{2}
-11,936	8.712*0.01 = \frac{1}{100} 8.712
6,327	\cos(π\times 2 - v) = \cos(-v + 4\times π)
-20,554	\frac{1}{80 \cdot y} \cdot (y \cdot 70 + 60) = 10/10 \cdot \frac{y \cdot 7 + 6}{y \cdot 8}
-29,319	-7 - i\cdot 17 = 3 + 10\cdot (-1) - i\cdot 17
33,630	p^9 = (p^3)^3 = (p + 1)^3 = p * p * p + 1 = p + 2 = p + (-1)
39,088	{l \choose l - k} = {l \choose k}
-1,680	\pi/6 + 3/2\cdot \pi = \pi\cdot 5/3
-3,925	\frac{8}{4} \cdot \frac{r^3}{r^4} = \frac{r^3 \cdot 8}{4 \cdot r^4}
22,131	\frac{y^2 + 5\cdot y + 3}{y^2 + y + 3} = 1 + \tfrac{4\cdot y}{y^2 + y + 3} \approx 1 + \frac{4}{y}
-18,301	\dfrac{36\cdot (-1) + y^2 - 5\cdot y}{4\cdot y + y \cdot y} = \dfrac{1}{(4 + y)\cdot y}\cdot (4 + y)\cdot (9\cdot \left(-1\right) + y)
17,159	\frac{3}{5}\cdot l = \frac{1}{100}\cdot 60\cdot l
28,314	\beta^2 - \beta + 1 = 0 = \beta^3 + 2 \cdot \beta + 1\Longrightarrow \beta^2 = \beta \cdot \beta^2
-20,247	\frac{s \cdot 42}{s \cdot (-24)} \cdot 1 = -\frac74 \cdot \frac{(-6) \cdot s}{s \cdot (-6)}
11,406	(\omega + b)\cdot g = g\cdot \omega + g\cdot b
14,665	((1 + x)^{1/2} x + y) (-x*\left(x + 1\right)^{1/2} + y) = -x^2 + y^2 - x^3
3,491	\left(z + 3\right)^{1 / 2} (z + 5 \left(-1\right))^{1 / 2} = (\left(z + 3\right) (z + 5 (-1)))^{1 / 2} = (z z - 2 z + 15 (-1))^{1 / 2} = (\left(z + (-1)\right)^2 - 4^2)^{\tfrac{1}{2}}
3,998	26 + 9\left(-1\right) = 17
-2,154	11/6 \pi + 3/4 \pi = \pi \frac{31}{12}
14,094	w\times x\times 3 + 15\times \left(-1\right) = 0 \Rightarrow x = 5/w
7,502	\frac{8}{1/3}\frac{1}{27} = 8/9
-9,498	5 + x30 = 5 + x235
29,718	v\cdot f_2 + b_2\cdot u + v\cdot f_1 + b_1\cdot u = u\cdot \left(b_2 + b_1\right) + v\cdot (f_1 + f_2)
17,372	\frac{1}{(1 - x)^2} \cdot (1 + x^{m + 1} \cdot m - x^m \cdot (m + 1)) = 1 + x \cdot 2 + 3 \cdot x^2 + \dots + x^{m + (-1)} \cdot m
11,104	g \cdot g \cdot h = h \cdot g \cdot g
-20,119	\frac{1}{x \cdot 3 + 6} \cdot (20 + 10 \cdot x) = \frac{10}{3} \cdot \frac{1}{x + 2} \cdot (2 + x)
27,258	\left(1 + 2 + 3 + 4 + 5\right)60/5111 = 19980
-3,951	\frac{d^5}{d^5} \cdot \dfrac{1}{55} \cdot 44 = \dfrac{44 \cdot d^5}{d^5 \cdot 55}
40,668	0 - -1 = \left(-1\right) \cdot \left(-1\right)
51,395	\tan{3 \cdot \theta} = -\tfrac{\tan{\theta} + \tan{2 \cdot \theta}}{1 - \tan{\theta} \cdot \tan{2 \cdot \theta}} = -\tan(\theta + 2 \cdot \theta) = \tan{-3 \cdot \theta}
12,452	2 - x^2 - z^2 = x^2 \Rightarrow x \cdot x + z^2/2 = 1
-1,639	\pi \dfrac{1}{12}17 - \frac{23}{12} \pi = -\frac{\pi}{2}
-23,188	(-3) \cdot (-3) = 9
9,783	\|\frac{1}{jd + b}\| = \frac{1}{\|dj + b\|}
23,810	\tanh{x} = \sinh{x}/\cosh{x} = \frac{1}{1 + e^{-2x}}(1 - e^{-2*x})
8,863	\dfrac145 + \frac{1}{2}5 = \dfrac{15}{4}
5,227	\sigma^2 + x^2 - \sigma\cdot x\cdot 2 = (x - \sigma)^2
-5,490	\frac{6}{2\cdot (q + 2)\cdot (7 + q)} = \frac{3}{\left(q + 2\right)\cdot (q + 7)}\cdot \frac22
1,805	\frac{1}{k^3}\cdot k \cdot k = 1/k
-26,563	7 + 14z + 7z * z = 7\left(1 + 2z + z^2\right) = 7*\left(1 + z\right)^2
19,878	\cos^2(r) - \sin^2(r) = \cos(r\cdot 2)
-20,870	\frac{1}{-32 k + 28 (-1)}(20 + 40 k) = 4/4 \frac{1}{7(-1) - 8k}\left(k\cdot 10 + 5\right)
10,963	39 * 39 + 52^2 = 65 * 65 = 25 * 25 + 60 * 60
-26,365	-\frac{3}{4}\cdot \left(-3/4\right) = 9/16
11,978	27/9 = \frac{27\cdot \tfrac{1}{9}}{9\cdot \frac19} = 3/1 = 3
32,389	12 \times 12 \times 12 + 1 \times 1 \times 1 = 1729
-26,646	(9\cdot x^4 + 10)\cdot (9\cdot x^4 + 10\cdot (-1)) = (x^4\cdot 9)^2 - 10^2
-22,760	\frac{28 \cdot 3}{28 \cdot 2} = \tfrac{84}{56}
-6,514	\frac{1}{(a + 9) (a + 3(-1))} = \dfrac{1}{27 (-1) + a^2 + a*6}
23,439	-z(-J) = Jz
14,552	\dfrac{1}{\cos(x)(1 + \sin\left(x\right))}(2 + 2\sin(x)) = \frac{1}{\cos(x)}2 = 2*\sec(x)

10,063

e^x = \sum_{n=0}^\infty x^n/n! > \tfrac{1}{n!}\cdot x^n

29,508

-z\cdot (\epsilon + g) = (g + \epsilon)\cdot (-z)

-19,476

2/3\cdot \frac71 = 2\cdot \frac13/(\tfrac{1}{7})

19,028

\frac{3*5}{2}8 = 60

8,603

\frac{\frac{1}{6}}{\frac16 + 5 \cdot \dfrac16/7} = 7/12

-24,757

\cos{13\cdot \pi/12} = \frac{1}{4}\cdot \left(-\sqrt{6} - \sqrt{2}\right)

5,356

z \Rightarrow (z^2 - 3 \cdot z + 1)^2 - 3 \cdot (z^2 - 3 \cdot z + 1) + 1 = z^2 - 3 \cdot z + 1 = z

8,632

\alpha x^9 \cdot \left(x + 1\right) = x^9 \alpha + \alpha x^{10}

6,081

x x + z^2 \alpha^2 + \alpha z x*2 = (x + z \alpha)^2

47,283

3*3! = 18

9,048

\left( 5, 9, 0\right) = ( x, y, \nu) + ( 2, 1, -5) \Rightarrow ( 2 + x, 1 + y, \nu + 5 \cdot (-1)) = \left( 5, 9, 0\right)

13,958

(1 + z + z^2)^n = (\frac{1 - z^3}{1 - z})^n = \left(1 - z^3\right)^n \cdot \left(1 - z\right)^{-n}

-29,016

0.48\cdot 23.9 = 11.472

-9,158

49*(-1) - 7*k = -7*7 - k*7

5,341

\frac{1}{2} \cdot m = \frac{1}{2^m} \cdot 2^{m + (-1)} \cdot m

42,178

k + 1 + n + 1 = k + n + 1 + 1

15,792

(e^{i\cdot \theta})^n = e^{i\cdot n\cdot \theta} = \cos{n\cdot \theta} + i\cdot \sin{n\cdot \theta}

-7,930

\frac{1}{41} \cdot (72 + 8 \cdot i - 90 \cdot i + 10) = (82 - 82 \cdot i)/41 = 2 - 2 \cdot i

19,599

(f\cdot b)^{i + 2} = f^{i + 2}\cdot b^{i + 2} = f^{i + 1}\cdot f\cdot b^{i + 1}\cdot b

4,534

3 \left((-1) + x x\right) + 4 = 1 + x^2 \cdot 3

11,689

2 \times 2^k = 2^{k + 1} \times ...

23,383

3/51*4/52 + 4/51*\frac{48}{52} = \frac{1}{52}*4

6,806

\frac{24}{24 + 10} = \frac{1}{34} \cdot 24 = \frac{12}{17}

4,798

b*e*b = b*e*b

22,913

x^l = \left((x^{1/q})^q\right)^l = (x^{1/q})^{q \cdot l}

3,881

(3\cdot z + 1)\cdot (1 + z)^4 = 1 + 7\cdot z + 18\cdot z^2 + z \cdot z^2\cdot 22 + 13\cdot z^4 + 3\cdot z^5

-11,432

(z + 2*(-1))^2 + h = (z + 2*\left(-1\right))*(z + 2*(-1)) + h = z * z - 4*z + 4 + h

929

x^2 + x*b \Rightarrow -(\frac{1}{2}*b)^2 + (x + b/2) * (x + b/2)

23,445

(b + 1) \times (b + 1) = b \times b + 2 \times b + 1 = b^2 + 1 = b^1 + 1 - b \times b + b + 1 = -b = -b = b

14,236

k \cdot y = (k + 0) \cdot y = k \cdot y + 0 \cdot y

31,649

0 = p^2 \implies p = 0

7,751

2\times (\arctan(\infty) - \arctan\left(-\infty\right)) = 2\times \pi

20,199

e^{Y + R} = e^R e^Y \implies 0 = (R, Y)

9,966

\dfrac{1 - r^{n + 1}}{1 - r} = \frac{1}{1 - r}*(1 - r^{1 + n})

13,742

1 + 3^{1 + k} = 1 + 3^k\cdot 3

30,259

B = \sqrt{B*A} \Rightarrow 0 = B\text{ or }B = A

7,829

\theta = \frac{180}{\pi} \cdot \theta \cdot \tfrac{1}{180} \cdot \pi

29,354

h > -1 rightarrow 0 < 1 + h

33,595

20^2 + 21 \cdot 21 = 29^2

21,456

\frac{1}{0 (-1) + 1} = 1

27,719

\cos(f_1 + f_2) = \cos(f_1) \cdot \cos(f_2) - \sin(f_1) \cdot \sin(f_2)

28,257

6*4*z^2*9 = 24*9*z * z = 216*z^2

15,202

\mathbb{E}(Z) = \mathbb{E}(\sum_{i=1}^l Z_i) = \sum_{i=1}^l \mathbb{E}(Z_i)

14,830

\frac{1}{12}*\left(2^6 + 8*2^2 + 3*2^2*2^2\right) = 12

30,257

4^{2n} + (-1) = 16^n + (-1) = (16 + (-1)) (16^{n + (-1)} + 16^{n + 2(-1)} + ... + 1)

-23,163

-5/4 \cdot 2 = -5/2

4,796

(b \cdot \tfrac{a}{b})^2 = b \cdot a \cdot b \cdot \frac{a}{b}/b = b \cdot \frac{a^2}{b}

20,810

((1 + x)^l)^2 = \left(1 + x\right)^{2l}

22,400

\dfrac{1}{f\cdot 4}\cdot (\vartheta\cdot f\cdot 4 + f^2\cdot y^2\cdot 4 + 4\cdot f\cdot U\cdot y) = \vartheta + f\cdot y^2 + y\cdot U

31,819

e^t = 1 + t + t^2/2! + \dotsm > \frac{t^2}{2}

-11,936

8.712*0.01 = \frac{1}{100} 8.712

6,327

\cos(π\times 2 - v) = \cos(-v + 4\times π)

-20,554

\frac{1}{80 \cdot y} \cdot (y \cdot 70 + 60) = 10/10 \cdot \frac{y \cdot 7 + 6}{y \cdot 8}

-29,319

-7 - i\cdot 17 = 3 + 10\cdot (-1) - i\cdot 17

33,630

p^9 = (p^3)^3 = (p + 1)^3 = p * p * p + 1 = p + 2 = p + (-1)

39,088

{l \choose l - k} = {l \choose k}

-1,680

\pi/6 + 3/2\cdot \pi = \pi\cdot 5/3

-3,925

\frac{8}{4} \cdot \frac{r^3}{r^4} = \frac{r^3 \cdot 8}{4 \cdot r^4}

22,131

\frac{y^2 + 5\cdot y + 3}{y^2 + y + 3} = 1 + \tfrac{4\cdot y}{y^2 + y + 3} \approx 1 + \frac{4}{y}

-18,301

\dfrac{36\cdot (-1) + y^2 - 5\cdot y}{4\cdot y + y \cdot y} = \dfrac{1}{(4 + y)\cdot y}\cdot (4 + y)\cdot (9\cdot \left(-1\right) + y)

17,159

\frac{3}{5}\cdot l = \frac{1}{100}\cdot 60\cdot l

28,314

\beta^2 - \beta + 1 = 0 = \beta^3 + 2 \cdot \beta + 1\Longrightarrow \beta^2 = \beta \cdot \beta^2

-20,247

\frac{s \cdot 42}{s \cdot (-24)} \cdot 1 = -\frac74 \cdot \frac{(-6) \cdot s}{s \cdot (-6)}

11,406

(\omega + b)\cdot g = g\cdot \omega + g\cdot b

14,665

((1 + x)^{1/2} x + y) (-x*\left(x + 1\right)^{1/2} + y) = -x^2 + y^2 - x^3

3,491

\left(z + 3\right)^{1 / 2} (z + 5 \left(-1\right))^{1 / 2} = (\left(z + 3\right) (z + 5 (-1)))^{1 / 2} = (z z - 2 z + 15 (-1))^{1 / 2} = (\left(z + (-1)\right)^2 - 4^2)^{\tfrac{1}{2}}

3,998

26 + 9\left(-1\right) = 17

-2,154

11/6 \pi + 3/4 \pi = \pi \frac{31}{12}

14,094

w\times x\times 3 + 15\times \left(-1\right) = 0 \Rightarrow x = 5/w

7,502

\frac{8}{1/3}\frac{1}{27} = 8/9

-9,498

5 + x*30 = 5 + x*2*3*5

29,718

v\cdot f_2 + b_2\cdot u + v\cdot f_1 + b_1\cdot u = u\cdot \left(b_2 + b_1\right) + v\cdot (f_1 + f_2)

17,372

\frac{1}{(1 - x)^2} \cdot (1 + x^{m + 1} \cdot m - x^m \cdot (m + 1)) = 1 + x \cdot 2 + 3 \cdot x^2 + \dots + x^{m + (-1)} \cdot m

11,104

g \cdot g \cdot h = h \cdot g \cdot g

-20,119

\frac{1}{x \cdot 3 + 6} \cdot (20 + 10 \cdot x) = \frac{10}{3} \cdot \frac{1}{x + 2} \cdot (2 + x)

27,258

\left(1 + 2 + 3 + 4 + 5\right)*60/5*111 = 19980

-3,951

\frac{d^5}{d^5} \cdot \dfrac{1}{55} \cdot 44 = \dfrac{44 \cdot d^5}{d^5 \cdot 55}

40,668

0 - -1 = \left(-1\right) \cdot \left(-1\right)

51,395

\tan{3 \cdot \theta} = -\tfrac{\tan{\theta} + \tan{2 \cdot \theta}}{1 - \tan{\theta} \cdot \tan{2 \cdot \theta}} = -\tan(\theta + 2 \cdot \theta) = \tan{-3 \cdot \theta}

12,452

2 - x^2 - z^2 = x^2 \Rightarrow x \cdot x + z^2/2 = 1

-1,639

\pi \dfrac{1}{12}17 - \frac{23}{12} \pi = -\frac{\pi}{2}

-23,188

(-3) \cdot (-3) = 9

9,783

|\frac{1}{jd + b}| = \frac{1}{|dj + b|}

23,810

\tanh{x} = \sinh{x}/\cosh{x} = \frac{1}{1 + e^{-2*x}}*(1 - e^{-2*x})

8,863

\dfrac145 + \frac{1}{2}5 = \dfrac{15}{4}

5,227

\sigma^2 + x^2 - \sigma\cdot x\cdot 2 = (x - \sigma)^2

-5,490

\frac{6}{2\cdot (q + 2)\cdot (7 + q)} = \frac{3}{\left(q + 2\right)\cdot (q + 7)}\cdot \frac22

1,805

\frac{1}{k^3}\cdot k \cdot k = 1/k

-26,563

7 + 14*z + 7*z * z = 7*\left(1 + 2*z + z^2\right) = 7*\left(1 + z\right)^2

19,878

\cos^2(r) - \sin^2(r) = \cos(r\cdot 2)

-20,870

\frac{1}{-32 k + 28 (-1)}(20 + 40 k) = 4/4 \frac{1}{7(-1) - 8k}\left(k\cdot 10 + 5\right)

10,963

39 * 39 + 52^2 = 65 * 65 = 25 * 25 + 60 * 60

-26,365

-\frac{3}{4}\cdot \left(-3/4\right) = 9/16

11,978

27/9 = \frac{27\cdot \tfrac{1}{9}}{9\cdot \frac19} = 3/1 = 3

32,389

12 \times 12 \times 12 + 1 \times 1 \times 1 = 1729

-26,646

(9\cdot x^4 + 10)\cdot (9\cdot x^4 + 10\cdot (-1)) = (x^4\cdot 9)^2 - 10^2

-22,760

\frac{28 \cdot 3}{28 \cdot 2} = \tfrac{84}{56}

-6,514

\frac{1}{(a + 9) (a + 3(-1))} = \dfrac{1}{27 (-1) + a^2 + a*6}

23,439

-z*(-J) = J*z

14,552

\dfrac{1}{\cos(x)*(1 + \sin\left(x\right))}*(2 + 2*\sin(x)) = \frac{1}{\cos(x)}*2 = 2*\sec(x)