Depending on your data you can level the measured values by calculating an average.

Using a certain number of previous results

```
int values[BUFLEN];
value = // your new raw measured value
index = index++ % BUFLEN;
values[index] = value;
avg = 0;
for(int i=0; i<BUFLEN; i++) {
avg = avg + values[i] / BUFLEN; // evenly weighted
}
```

You can use uneven weights, too, if you want to. Also, this loop can be optimized if you are using equal weights.

Using a floating average

```
avg = (avg * 0.9) + (value * 0.1) // slow response
avg = (avg * 0.5) + (value * 0.5) // fast response
float q = // new ratio
avg = (avg * (1.0 - q)) + (value * q) // general solution
```

The floating average (mathematically) is an weighted sum of all elements, where the weights are q^{N-i} where `N`

is the total measured values and `i`

is the running index of the element. All elements are involved in the average, not just a limited number of elements.

You can check what is the frequency of the mistaken measures, what is the distance from the average, what response do you expect your (calculated) measures to follow the real processes, etc.

Also, if you have discrete values (integers), you have to be careful using the rounding thing. I recommend to do all calculations in floating point, then round the result to the nearest integer. But store the calculated average in floating point for the next round.

**Update:**

To reflect your question about being *up-to-date* and *accurate* at the same time:

The problem is that we are not sure whether the latest data is showing a tendency or is a result of an erroneous reading. I'll show you an example:

```
SEQ1: 15 15 14 15 15 [10] 6 6 5 6 6
SEQ2: 15 15 14 15 15 [10] 20 15 14 15 15
```

So, what does `[10]`

means in each sequence: In the first one, it represents a serious movement, a trend. In the second one, it is just a misread. But when you have just read `[10]`

, you have no idea what will be the next one. So, you have to **delay** the effect of that read. So, it will not be *up-to-date*.

Similarly, you are using an average value, which is a **calculated** value. so, it won't be *accurate*.

It is a **balancing situation**. The more up-to-date the value is, the less accurate (more exposed to misreads). The more accurate your data is, the bigger the delay. Based on the data series, you have to choose it wisely.

I have calculated three scenarios for you, using the second (floating average) algorithm. The value of `q`

is set to *lazy*, *normal* or *eager*.

```
SEQ1: 15 15 14 15 15 10 6 6 5 6 6
// q=0.25, "lazy"
Avg 15.00 15.00 14.75 14.81 14.86 13.64 11.73 10.30 8.98 8.23 7.67
Rounded 15 15 15 15 15 14 12 10 9 8 7
// q=0.5, "normal"
Avg 15.00 15.00 14.50 14.75 14.88 12.44 9.22 7.61 6.30 6.15 6.08
Rounded 15 15 15 15 15 12 9 7 6 6 6
// q=0.75, "eager"
Avg 15.00 15.00 14.25 14.81 14.95 11.23 7.31 6.33 5.33 5.83 5.96
Rounded 15 15 14 15 15 11 7 6 5 5 6
```

You can see that the *lazy* calculation still have not reached to `6`

after 5 iteration, maybe 3 more is needed.

The *normal* was almost not error-prone, (14.5 was just rounded up), but could follow the trend almost immediately.

The *eager* was eagerly following the measures, adding just a slight alleviation to the curve. It could not even detect the 15-14-15 erroneous read.

The best value *for the series above* would be around `0.4`

- `0.45`

I think. It is worth to play around with a sample of *your real measurement data* to see what is the behavior of what parameter value.

Actually my favorite is **floating average** algorithm, it's easy to implement and gives a good result (if parameterized well).