Solution: We compute the number of distinct permutations of 10 sensors: 4 red (R), 5 green (G), and 1 blue (B). The number of sequences is:

Solution: How to Compute Distinct Permutations of 10 Sensors with Repeated Colors

When designing systems involving sequences of objects—like arranging colored sensors—understanding the number of distinct arrangements is crucial for analysis, scheduling, or resource allocation. In this problem, we explore how to calculate the number of unique permutations of 10 sensors consisting of 4 red (R), 5 green (G), and 1 blue (B).

The Challenge: Counting Distinct Permutations with Repetitions

Understanding the Context

If all 10 sensors were unique, the total arrangements would be $10!$. However, since sensors of the same color are indistinguishable, swapping two red sensors does not create a new unique sequence. This repetition reduces the total number of distinct permutations.

To account for repeated elements, we use a well-known formula in combinatorics:

If we have $n$ total items with repeated categories of sizes $n_1, n_2, ..., n_k$, where each group consists of identical elements, the number of distinct permutations is given by:

\[
\frac{n!}{n_1! \cdot n_2! \cdot \ldots \cdot n_k!}
\]

Solution with distinct permutations. | Download Scientific Diagram

Image Gallery

$Find the number \mathrm{n} of distinct permutations that can be formed fr..$

Solved How many distinct permutations can be made from the | Chegg.com

Solved 2.34 (a) How many distinct permutations can be made | Chegg.com

Solved: Thin Pan pt ppers as) How many distinct permutations can be ...

Key Insights

Applying the Formula to Our Sensor Problem

For the 10 sensors:
- Total sensors, $n = 10$
- 4 red sensors → $n_R = 4$
- 5 green sensors → $n_G = 5$
- 1 blue sensor → $n_B = 1$

Plug into the formula:

\[
\ ext{Number of distinct sequences} = \frac{10!}{4! \cdot 5! \cdot 1!}
\]

Step-by-step Calculation

🔗 Related Articles You Might Like:

📰 You Won’t Believe Which Habits Shape Tomorrow’s Leaders—Step Inside Now 📰 Education Unleashed: The Hidden Truth Behind Next-Gen Learning Breakthroughs 📰 You Won’t Believe These Cleats Hurt Your Little League Dreams 📰 Flights To Wpb Fl 6502389 📰 Insiders Reveal Oracle Confs Most Shocking Announcements You Need To Know 5819955 📰 Connect 4 Online 2 Player The Ultimate Free Game Thatll Keep You Hooked 1177074 📰 Shoulder Pads Football 1400473 📰 Apple Competitors Are Crushing The Giantheres Which Companies Are Stealing Market Share 8029169 📰 Sarah Carter Actress 8492302 📰 From Superman To Shirtless Henry Cavills Bareback Look Photo Shocked Fans Everywhere 6249555 📰 Marx And Marx 3574808 📰 Free Fps Shooting Games 9249939 📰 This Simple Conversion Could Save You Hourssee How 5160931 📰 Unreal Engine 4 Pc Specs 1781377 📰 Tyler Perrys Sistas 9903614 📰 Secure Your Childs Financial Legacy With A Custodial Brokerage Accountdont Miss Out 7506445 📰 Los Angeles Rams Vs Bengals Match Player Stats 518971 📰 Private Moments Revealed Can You Guess This Puppys Daily Routine 4234700

Final Thoughts

Compute factorials:
$10! = 3628800$
$4! = 24$
$5! = 120$
$1! = 1$
Plug in:

\[
\frac{3628800}{24 \cdot 120 \cdot 1} = \frac{3628800}{2880}
\]

Perform division:

\[
\frac{3628800}{2880} = 1260
\]

Final Answer

There are 1,260 distinct permutations of the 10 sensors (4 red, 5 green, and 1 blue).

Why This Matters

Accurately calculating distinct permutations helps in probability modeling, error analysis in manufacturing, logistical planning, and algorithmic design. This method applies broadly whenever symmetries or redundancies reduce the effective number of unique arrangements in a sequence.