It states that the more trials you conduct, the more likely the experimental probability will match the theoretical probability.

It suggests that theoretical probability is always higher than experimental probability.

It indicates that theoretical probability is irrelevant in experiments.

It implies that experimental probability never changes regardless of the number of trials.

It guarantees that experimental probability will always match theoretical probability.

It allows you to simulate coin flips and observe the proportion of heads.

It lets you change the theoretical probability of a coin flip.

It predicts the outcome of each coin flip.

Because theoretical probability is always inaccurate.

Because the coin used in the experiment is biased.

Because experimental probability is calculated differently.

Because a small number of trials can lead to significant variations.

It converges towards theoretical probability.

It diverges further from theoretical probability.

It remains constant regardless of the number of tosses.

It becomes more unpredictable.

The experimental probability is more than 70%.

The experimental probability is less than 30%.

The experimental probability is still different from the theoretical probability.

The experimental probability is exactly 50%.

It makes divergence inevitable.

It increases the likelihood of divergence.

It decreases the likelihood of divergence.

It has no effect on the likelihood of divergence.

The experimental probability will always be less than the theoretical probability.

The experimental probability will exactly match the theoretical probability.

The experimental probability will become unpredictable.

The experimental probability will remain constant.