The rising factorial 
,
sometimes also denoted 
(Comtet 1974, p. 6) or 
(Graham et al. 1994, p. 48), is defined
by
 |
(1)
|
This function is also known as the rising factorial power (Graham et al. 1994, p. 48) and frequently called the Pochhammer symbol in the theory of special functions. The rising factorial is implemented in the Wolfram Language as Pochhammer[x, n].
The rising factorial is related to the gamma function 
by
 |
(2)
|
where
 |
(3)
|
and is related to the falling factorial 
by
 |
(4)
|
The usual factorial is therefore related to the rising factorial by
 |
(5)
|
for nonnegative integers 
(Graham et al. 1994, p. 48).
Note that in combinatorial usage, the falling factorial is denoted 
and the rising factorial is denoted 
(Comtet 1974, p. 6; Roman 1984, p. 5; Hardy
1999, p. 101), whereas in the calculus of finite
differences and the theory of special functions, the falling
factorial is denoted 
and the rising factorial is denoted 
(Roman 1984, p. 5; Abramowitz and Stegun 1972, p. 256;
Spanier 1987). Extreme caution is therefore needed in interpreting the meanings of
the notations 
and 
.
In this work, the notation 
is used for the rising factorial, despite the
fact that Pochhammer symbol, which is another
name for the rising factorial, is universally denoted 
.
The rising factorial arises in series expansions of hypergeometric functions and generalized hypergeometric functions.
The first few rising factorials are
 |  |  |
(6)
|
 |  |  |
(7)
|
 |  |  |
(8)
|
 |  |  |
(9)
|
 |  |  |
(10)
|
The derivative of the rising factorial is
![d/(dx)x^((n))=x^((n))[psi^((0))(x+n)-psi^((0))(x)],](/images/equations/RisingFactorial/NumberedEquation6.svg) |
(11)
|
where 
is the digamma function.
." Ch. 18 in