n=500, 90% Confidence Interval
Result using an example sample mean of 20.6 and standard deviation of 3.1. Use the calculator below to enter your own sample statistics.
Confidence Interval
20.3719 – 20.8281
Example
With a sample of 500, a mean of 20.6, and a standard deviation of 3.1, you can be 90% confident the true population mean falls between 20.372 and 20.828.
Margin of Error
± 0.2281 (1.11%)
Critical Z-Value
1.645
Standard Error
0.1386
Range Width
0.4562
Confidence region under the normal curve
What Is a Confidence Interval?
A confidence interval is a range of values, built around a sample estimate, within which the true population parameter likely falls. A 95% confidence interval doesn't mean there's a 95% chance the true mean is inside this specific interval — it means that if you repeated the same sampling process many times and built an interval each time, about 95% of those intervals would contain the true population mean.
The core formula is x̄ ± Z × (σ / √n), where x̄ is the sample mean,
Z is the critical value for your chosen confidence level, σ is the standard
deviation, and n is the sample size.
Common Critical Z-Values
| Confidence Level | Critical Z-Value |
|---|---|
| 80% | 1.282 |
| 90% | 1.645 |
| 95% | 1.960 |
| 98% | 2.326 |
| 99% | 2.576 |
Why Larger Samples Narrow the Interval
The margin of error shrinks with the square root of the sample size, so quadrupling your sample only halves the margin of error — a classic case of diminishing returns that explains why polls and studies often need very large samples to shrink an already-narrow interval further.
Confidence Level vs. Precision Tradeoff
Choosing a higher confidence level (say 99% instead of 90%) widens the interval, because you're demanding more certainty that the true value is captured. There's no free lunch: more confidence always costs precision unless you also increase the sample size.
When This Formula Applies
This z-based formula assumes the population standard deviation is known, or that the sample is large enough (typically n ≥ 30) for the sample standard deviation to be a reliable stand-in. For smaller samples with an unknown population standard deviation, a t-distribution-based interval is more appropriate.
Example — Your Current Inputs
With a sample of 500, a mean of 20.6, and a standard deviation of 3.1, you can be 90% confident the true population mean falls between 20.372 and 20.828.
Additional Example — Political Poll
A poll of 1,000 voters finds 52% support for a candidate. At 95% confidence with a standard deviation typical of proportion data, the margin of error works out to roughly ±3.1 points — the familiar "margin of error" figure reported alongside most published polls.
About These Parameters
- Sample Size, Mean & Standard Deviation
- These three numbers summarize your sample data — how many observations you collected, their average, and how spread out they are.
- Confidence Level
- How certain you want to be that the interval captures the true population value. 95% is the most common default across scientific research and polling.
Frequently Asked Questions
Does a 95% CI mean there's a 95% chance the true mean is in this range?
Not quite — the true mean either is or isn't in any specific interval. The 95% refers to the long-run reliability of the method: 95% of intervals built this way, across repeated sampling, would contain the true value.
Why did my interval get wider when I increased confidence?
A higher confidence level uses a larger critical z-value, which widens the margin of error — you're trading precision for certainty.
What if I don't know the population standard deviation?
For large samples, the sample standard deviation is a good enough substitute. For small samples, a t-distribution-based confidence interval — which uses slightly wider critical values — is more statistically appropriate.