What I meant in my comment is that the naive

```
Unprotect[Integrate];
Integrate[Exp[-y_^2], {y_, -\[Infinity], x_}] := myErf[x]
```

to try to intercept some `Integrate`

evaluations does not work.

*Actually* it does work

```
In[]:= Integrate[Exp[-y^2],{y,-Infinity,z}]
Out[]= myErf[z]
```

(that will teach me for answering a SO question at midnight).
So maybe you don't need the `myIntegrate`

function given below.

Anyway... The two alternatives given in the comment are:

**1)** You could write your own `Erf`

integrator using something like

```
In[1]:= myErf[x_?NumericQ]:=NIntegrate[Exp[-y^2],{y,-\[Infinity],x}]
(* sames as Erf up to constant and scaling *)
In[2]:= Clear[myIntegrate]
myIntegrate[a_. Exp[b_. y_^2], {y_, -\[Infinity], x_}] /; FreeQ[{a, b}, y] := ConditionalExpression[myErf[x], b < 0]
myIntegrate[a_. Exp[b_. y_^2], {y_, xx_, x_}] := myIntegrate[a Exp[b y^2], {y, -\[Infinity], x}] - myIntegrate[a Exp[b y^2], {y, -\[Infinity], xx}]
myIntegrate[a_ + b_, lims__] := myIntegrate[a, lims] + myIntegrate[b, lims] (* assuming this is ok *)
myIntegrate[expr_, lims__] := Integrate[expr, lims]
In[8]:= myIntegrate[a Exp[x]+b Exp[-b x^2],{x,2y,z}]
Out[8]= ConditionalExpression[a (-E^(2 y)+E^z) - myErf[2 y] + myErf[z], b > 0]
```

Where at the end, the remaining integrals are passed to `Integrate`

. But you'd have to be smarter in the pattern matching (maybe including some transformations in intermediate steps) in order to catch all `Erf`

-like functions.

**2)**
You overwrite the `Erf`

-type functions so that they never evaluate using the built-in routines:

```
In[9]:= Clear[myErf];
Unprotect[Erf,Erfc,Erfi];
In[10]:= Erf[x__] := myErf[x]
Erfc[x__]:= myErfc[x]
Erfi[x__]:= myErfi[x]
In[13]:= {Erf[1], Erfc[2], Erfi[\[Pi]], Integrate[E^-x^2,x]}
Out[13]= {myErf[1], myErfc[2], myErfi[\[Pi]], 1/2 Sqrt[Pi] myErf[x]}
```

Where, obviously, you choose your own conventions for the `myErf`

functions.

**Edit:**
The simplest and maybe safest/softest method (thanks to Leonid) of doing what you want is to just `Block[{Erf=...},...]`

and let the Mathematica integrator do all of the work.
For example you `myErf`

was given as

```
In[1]:= myErf[x] == Integrate[Exp[-y^2/2], {y, -Infinity, x}]
Out[1]= myErf[x]==Sqrt[Pi/2] (1+Erf[x/Sqrt[2]])
```

So to solve the integral in your original post,

```
In[2]:= Block[{Erf = (Sqrt[2/Pi]*myErf[Sqrt[2] #] - 1 &)},
Integrate[Exp[-y^2 + y/2], {y, x, Infinity}]]
Out[2]= (E^(1/16)(Sqrt[\[Pi]] (-1 + 4 x + Sqrt[(-1 + 4 x)^2]) +
Sqrt[2] (1 - 4 x) myErf[Sqrt[2] Sqrt[(-(1/4) + x)^2]])
)/(2 Sqrt[(1 - 4 x)^2])
```

**Edit 2:**
Maybe you just need to be able to translate to and from `myErf`

expressions.
This means that it won't be automatic, but it will be flexible. Try

```
In[1]:= toMyErf=(FunctionExpand[#]/.Erf:>(Sqrt[2/Pi]*myErf[Sqrt[2] #]-1&)&);
fromMyErf=(#/.myErf:>(Sqrt[Pi/2] (1+Erf[#/Sqrt[2]])&)&);
In[3]:= Integrate[Exp[-y^2+y/2],{y,x,Infinity}]//toMyErf
Out[3]= 1/2 E^(1/16) Sqrt[\[Pi]] (2-Sqrt[2/\[Pi]] myErf[Sqrt[2] (-(1/4)+x)])
In[4]:= D[x*myErf[x+x^2],x]//fromMyErf//toMyErf
Out[4]= E^(-(1/2) (x+x^2)^2) x (1+2 x)+myErf[x+x^2]
```

Note that the `FunctionExpand`

command is there to rewrite `Erfc[x]`

as `1-Erf[x]`

. You might want to implement that part slightly better.

`Integrate`

like that. The only two options I can think of is 1) You write your own integration function that searches for the`Erf`

type integrands then passes the rest back to Integrate. 2) You catch and rewrite the`Erf`

's after mma's`Integrate`

has done its magic. – Simon Feb 5 '11 at 12:28