I presume it is some kind of moving average, but the valid range is between 0 and 1.
4 Answers
ORIGINAL ANSWER
It is called exponential moving average, below is a code explanation how it is created.
Assuming all the real scalar values are in a list called scalars
the smoothing is applied as follows:
def smooth(scalars: List[float], weight: float) > List[float]: # Weight between 0 and 1
last = scalars[0] # First value in the plot (first timestep)
smoothed = list()
for point in scalars:
smoothed_val = last * weight + (1  weight) * point # Calculate smoothed value
smoothed.append(smoothed_val) # Save it
last = smoothed_val # Anchor the last smoothed value
return smoothed
UPDATED ANSWER
As @SaPropper correctly pointed out, TensorBoard now includes the debiasing factor.

2


This is not the Python equivalent to the TensorBoard implementation Feb 24, 2023 at 16:41

To be more explicit: the TensorBoard implementation currently also has a debiasing factor, as in SaPropper's answer. Mar 13, 2023 at 15:32
Here is the actual piece of source code that performs that exponential smoothing with some additional debiasing explained in the comments to compensate for the choice of the zero initial value:
last = last * smoothingWeight + (1  smoothingWeight) * nextVal
The implementation of EMA smoothing used for TensorBoard can be found here.
The equivalent in Python is actually:
def smooth(scalars: list[float], weight: float) > list[float]:
"""
EMA implementation according to
https://github.com/tensorflow/tensorboard/blob/34877f15153e1a2087316b9952c931807a122aa7/tensorboard/components/vz_line_chart2/linechart.ts#L699
"""
last = 0
smoothed = []
num_acc = 0
for next_val in scalars:
last = last * weight + (1  weight) * next_val
num_acc += 1
# debias
debias_weight = 1
if weight != 1:
debias_weight = 1  math.pow(weight, num_acc)
smoothed_val = last / debias_weight
smoothed.append(smoothed_val)
return smoothed
a scipy solution from https://stackoverflow.com/a/42724386/10805680:
from scipy.signal import lfilter
def smooth(scalars: np.ndarray, weight: float) > np.ndarray:
return lfilter([1.  weight], [1., weight], scalars, zi=[arr[0]])[0]
much faster and numerically stable