You have the mode and the standard deviation of the log-normal distribution. To use the `rvs()`

method of scipy's `lognorm`

, you have to parameterize the distribution in terms of the shape parameter `s`

, which is the standard deviation `sigma`

of the underlying normal distribution, and the `scale`

, which is `exp(mu)`

, where `mu`

is the mean of the underlying distribution.

You pointed out that making this reparameterization requires solving a quartic polynomial. For that, we can use the `numpy.poly1d`

class. Instances of that class have a `roots`

attribute.

A little algebra shows that `exp(sigma**2)`

is the unique positive real root of the polynomial

```
x**4 - x**3 - (stddev/mode)**2 = 0
```

where `stddev`

and `mode`

are the given standard deviation and mode of the log-normal distribution, and for that solution, the `scale`

(i.e. `exp(mu)`

) is

```
scale = mode*x
```

Here's a function that converts the mode and standard deviation to the shape and scale:

```
def lognorm_params(mode, stddev):
"""
Given the mode and std. dev. of the log-normal distribution, this function
returns the shape and scale parameters for scipy's parameterization of the
distribution.
"""
p = np.poly1d([1, -1, 0, 0, -(stddev/mode)**2])
r = p.roots
sol = r[(r.imag == 0) & (r.real > 0)].real
shape = np.sqrt(np.log(sol))
scale = mode * sol
return shape, scale
```

For example,

```
In [155]: mode = 123
In [156]: stddev = 99
In [157]: sigma, scale = lognorm_params(mode, stddev)
```

Generate a sample using the computed parameters:

```
In [158]: from scipy.stats import lognorm
In [159]: sample = lognorm.rvs(sigma, 0, scale, size=1000000)
```

Here's the standard deviation of the sample:

```
In [160]: np.std(sample)
Out[160]: 99.12048952171304
```

And here's some matplotlib code to plot a histogram of the sample, with a vertical line drawn at the mode of the distribution from which the sample was drawn:

```
In [176]: tmp = plt.hist(sample, normed=True, bins=1000, alpha=0.6, color='c', ec='c')
In [177]: plt.xlim(0, 600)
Out[177]: (0, 600)
In [178]: plt.axvline(mode)
Out[178]: <matplotlib.lines.Line2D at 0x12c5a12e8>
```

The histogram:

If you want to generate the sample using `numpy.random.lognormal()`

instead of `scipy.stats.lognorm.rvs()`

, you can do this:

```
In [200]: sigma, scale = lognorm_params(mode, stddev)
In [201]: mu = np.log(scale)
In [202]: sample = np.random.lognormal(mu, sigma, size=1000000)
In [203]: np.std(sample)
Out[203]: 99.078297384090902
```

I haven't looked into how robust `poly1d`

's `roots`

algorithm is, so be sure to test for a wide range of possible input values. Alternatively, you can use a solver from scipy to solve the above polynomial for `x`

. You can bound the solution using:

```
max(sqrt(stddev/mode), 1) <= x <= sqrt(stddev/mode) + 1
```

`r = lognorm.rvs(s, size=1000)`

where`s`

is the shape parameter for the distribution.modeand standard deviation (notwith a given mean and standard deviation).4more comments