Why the Event $ z \geq 100 $ Has Probability Zero: A Simple Explanation

In probability theory, understanding the likelihood of specific events is crucial for modeling and decision-making in fields ranging from finance to engineering. One common question is: What is the probability that a continuous random variable $ Z $ exceeds a large value, such as $ z \geq 100 $? The intuitive answer is often “zero” — but what does this really mean? This article explains why the event $ z \geq 100 $ has probability zero, grounded in the fundamentals of continuous probability distributions.

Understanding the Context

Understanding Continuous Random Variables

First, it’s essential to distinguish between discrete and continuous random variables. For discrete variables (like the roll of a die), probabilities are assigned to distinct outcomes, such as $ P(X = 6) = \frac{1}{6} $. In contrast, continuous random variables (such as time, temperature, or measurement errors) take values over an interval, like all real numbers within $ [a, b] $. Because of this continuous nature, outcomes at single points — and even over intervals — often have zero probability.

The Probability of Single Points Is Zero

Zero-probability events | They are not impossible

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Zero-probability events | They are not impossible
Zero-probability events | They are not impossible
Zero-probability events | They are not impossible
Zero-probability events | They are not impossible
Zero-probability events | They are not impossible

Key Insights

In continuous probability, the probability that $ Z $ takes any exact value $ z $ is zero:

$$
P(Z = z) = 0 \quad \ ext{for any real number } z.
$$

This occurs because the “width” of a single point is zero. The probability over an interval is defined as the integral of the probability density function (PDF), $ f_Z(z) $, over that interval:

$$
P(a \leq Z \leq b) = \int_a^b f_Z(z) \, dz.
$$

Since the integral sums up infinitesimal probabilities over small intervals, the total probability of hitting exactly one value — say, $ z = 100 $ — amounts to zero.

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f(x) = 4\left(\left(x + \frac{3}{2}\right)^2 - \frac{9}{4}\right) + 9 = 4\left(x + \frac{3}{2}\right)^2 - 9 + 9 = 4\left(x + \frac{3}{2}\right)^2
項 \(4\left(x + \frac{3}{2}\right)^2\) は常に非負であり、\(\left(x + \frac{3}{2}\right)^2 = 0\) のときに最小値 0 を取ります。これは \(x = -\frac{3}{2}\) のときに起こります。
\(x = -\frac{3}{2}\) を元の関数に代入します:

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Final Thoughts

Why $ z \geq 100 $ Has Probability Zero

Now, consider the event $ z \geq 100 $. Geometrically, this corresponds to the probability of $ Z $ being in the unbounded tail extending from 100 to infinity:

$$
P(Z \geq 100) = \int_{100}^{\infty} f_Z(z) \, dz.
$$

Even if $ f_Z(z) $ is small beyond 100, integrating over an infinite range causes the total probability to approach zero — provided the integral converges. For well-behaved distributions (such as normal, exponential, or uniform on finite intervals extended safely), this integral is finite, confirming:

$$
P(Z \geq 100) = 0.
$$

This result reflects a key property of continuous distributions: events defined at or above a specific threshold typically have zero probability unless part of a larger interval.

Intuition Behind Zero Probability

Think of the probability as “mass” distributed over the number line. In a continuous distribution, this mass is spread so thinly that any single point, or any small interval at the tail, contains effectively no probability. It’s not that the event is impossible, but its likelihood in the continuous sense is zero — much like the chance of randomly selecting the exact decimal 0.500000… from a uniform distribution on $ [0,1] $.