Well, dealing with symbolic expressions in Mathematica, it's best to keep things exact, ie avoid approximate numbers:

```
In[36]:= pdf = PiecewiseExpand[Rationalize[E^(-(x^2/2) - y^2/2)*
(-1 + E^(-1.*(x + 0.1*y)*UnitStep[x + 0.1*y]))^2],
Element[{x, y}, Reals]]
Out[36]= Piecewise[{{E^(-2*x - x^2/2 - y/5 - y^2/2)*(-1 +
E^(x + y/10))^2, 10*x + y >= 0}}, 0]
```

In order to attack the problem, it is better to change variables:

```
In[56]:= cvr =
First[Solve[{10 x + y == u, (10 y - x)/101 == v}, {x, y}]]
Out[56]= {x -> (10 u)/101 - v, y -> u/101 + 10 v}
```

Notice that coefficients were chosen so that jacobian is a unity:

```
In[42]:= jac = Simplify[Det[Outer[D, {x, y} /. cvr, {u, v}]]]
Out[42]= 1
```

After the change of variables, you see that the density factorizes into a product:

```
In[45]:= npdf = FullSimplify[jac*pdf /. cvr]
Out[45]= Piecewise[{{E^(-(u/5) - u^2/202 - (101*v^2)/2)*(-1 +
E^(u/10))^2, u >= 0}}, 0]
```

That is, now variables 'u' and 'v' are independent. The 'v' variable is `NormalDistribution[0, 1/101]`

, while the 'u' variable is a little more complicated, but can now be handled by `ProbabilityDistribution`

.

```
In[53]:= updf =
Refine[npdf/nc, u >= 0]/PDF[NormalDistribution[0, 1/Sqrt[101]], v]
Out[53]= (E^(-(u/5) - u^2/202)*(-1 + E^(u/10))^2*Sqrt[2/(101*Pi)])/
(1 - 2*E^(101/200)*Erfc[Sqrt[101/2]/10] +
E^(101/50)*Erfc[Sqrt[101/2]/5])
```

So you can now define the joint distribution for vector `{u,v}`

:

```
dist = ProductDistribution[NormalDistribution[0, 1/101],
ProbabilityDistribution[updf, {u, 0, Infinity}]];
```

Since the relationship between `{u,v}`

and `{x,y}`

is known, generating of `{x,y}`

variates is easy:

```
XYRandomVariates[len_] :=
RandomVariate[dist, len].{{-1, 10}, {10/101, 1/101}}
```

You can encapsulate the accumulated knowledge using `TransformedDistribution`

:

```
origdist =
TransformedDistribution[{(10 u)/101 - v,
u/101 + 10 v}, {Distributed[v, NormalDistribution[0, 1/101]],
Distributed[u, ProbabilityDistribution[updf, {u, 0, Infinity}]]}];
```

E.g.:

```
In[68]:= Mean[RandomVariate[origdist, 10^4]]
Out[68]= {1.27198, 0.126733}
```