Qwen3-0.6b-f16-analysis.md

Qwen3-0.6B-f16 Analysis

Quantisation can subtly degrade performance — especially reasoning, creativity, and precise execution. By including diverse, well-known benchmark-style prompts, you can detect both obvious failures and subtle regressions in model behavior post-quantisation.

I asked 6 questions across all the quantised models. I have a quick summary below with a full list of the answers at the bottom for anyone who wants to see what happened.

Winner table

There are two good candidates: Qwen3-0.6B-f16:Q5_K_M and Qwen3-0.6B-f16:Q5_K_S. These cover the full range of temperatures and are good at all question types.

If you have limited resources or want an extremely fast model, then these 0.6B quantised options are worth considering!

If you know you are asking high temperature questions - ie non-technical, creative-style questions - then you should consider Qwen3-0.6B-f16:Q8_0

Level	Speed	Size	Recommendation
Q2_K	⚡ Fastest	347 MB	DO NOT USE. Could not provide an answer to any question.
Q3_K_S	⚡ Fast	390 MB	Not recommended, did not appear in any top 3 results.
Q3_K_M	⚡ Fast	414 MB	First place in the bat & ball question, no other top 3 appearances.
Q4_K_S	🚀 Fast	471 MB	A good option for technical, low-temperature questions.
Q4_K_M	🚀 Fast	484 MB	Showed up in a few results, but not recommended.
🥈 Q5_K_S	🐢 Medium	544 MB	🥈 A very close second place. Good for all query types.
🥇 Q5_K_M	🐢 Medium	551 MB	🥇 Best overall model. Highly recommended for all query types.
Q6_K	🐌 Slow	623 MB	Showed up in a few results, but not recommended.
🥉 Q8_0	🐌 Slow	805 MB	🥉 Very good for non-technical, creative-style questions.

Results

A bat and a ball cost $1.10 together. The bat costs $1.00 more than the ball. How much does the ball cost? Explain your reasoning step by step.

Purpose: Tests logical reasoning and resistance to cognitive bias.

This is a classic cognitive reflection test (CRT) problem. Many people instinctively answer "$0.10", which is wrong. The correct answer is $0.05 (ball), so the bat is $1.05 (exactly $1.00 more).

Why it's good: Reveals whether the model can avoid heuristic thinking and perform proper algebraic reasoning. Quantisation may impair subtle reasoning pathways; weaker models might echo the intuitive but incorrect answer. Requires step-by-step explanation, testing coherence and self-correction ability.

🥇 1st place: Qwen3-0.6B-f16:Q3_K_M

Why: ✅ Best pedagogical balance — precise, elegant, and easy to follow.

Strengths:

• Perfect logical structure (clear setup → algebra → solving → explanation).
• Uses consistent variable notation.
• Explains reasoning clearly without redundancy.
• Math formatted well and readable.
• Smooth flow and natural tone.

Weaknesses:

• Very minor: slightly verbose at the start, but that actually helps clarity for learners.

🥈 2nd place: Qwen3-0.6B-f16:Q5_K_M

Why: ✅ Excellent explanatory version with confirmation — great for teaching comprehension.

Strengths:

• Step numbering makes the reasoning process explicit.
• Includes a nice validation step (“the bat costs $1.05, together $1.10”), which reinforces understanding.
• Concise, but not too brief.

Weaknesses:

• A bit wordier in step descriptions compared to Qwen3-0.6B-f16:Q3_K_M.
• Uses mixed notation ($x$ and “the ball”), but still clear.

🥉 3rd place: Qwen3-0.6B-f16:Q5_K_S

Why: ✅ Most concise correct version — perfect for efficiency, but less instructive.

Strengths:

• Clear and clean algebra.
• Straightforward, concise, and correct.
• Uses consistent variable and equation structure.

Weaknesses:

• No reasoning commentary — feels a bit too procedural.
• Lacks a final “check” or verbal wrap-up.

Everything else:

Model	Comments
Qwen3-0.6B-f16:Q3_K_S	Correct but overly verbose and repetitive in notation.
Qwen3-0.6B-f16:Q4_K_S	Variable confusion (bat = B, then bat = B+1?), slightly inconsistent.
Qwen3-0.6B-f16:Q4_K_M / Qwen3-0.6B-f16:Q6_K / Qwen3-0.6B-f16:Q8_0	All solid but standard — no distinct advantage over the others; slightly redundant wording.
Qwen3-0.6B-f16:Q2_K	No answer → not viable.

Write a haiku about rain in Kyoto, using traditional seasonal imagery and emotional subtlety.

Purpose: Evaluates creative generation, cultural knowledge, and linguistic finesse.

A haiku must follow structure (5-7-5 syllables), use kigo (seasonal word), and evoke mood (often melancholy or transience). Kyoto + rain suggests spring rains (tsuyu) or autumn sadness — rich in poetic tradition.

Why it's good: Tests if quantisation affects poetic sensitivity or leads to generic/forced output. Small mistakes in word choice or rhythm are easy to spot. Challenges the model’s grasp of nuance, metaphor, and cultural context — areas where precision loss can degrade quality.

🥇 1st place: Qwen3-0.6B-f16:Q8_0

Why: ✅ Elegant, atmospheric, and emotionally resonant — closest to a true haiku spirit.

• Beautiful seasonal imagery (cherry blossoms = spring, a classic haiku kigo).
• Subtle emotional tone — peaceful, contemplative, understated.
• Evokes Kyoto’s cultural atmosphere (temples, history, quiet reverence).
• Compact, natural flow; easily fits haiku rhythm.
• Avoids excess adjectives or explanation — it shows, not tells.

🥈 2nd place: Qwen3-0.6B-f16:Q5_K_S

Why: ✅ Beautifully written — perfect emotional subtlety, but a bit generic geographically.

• Evocative mood and subtle emotion (calm introspection).
• Excellent seasonal and weather imagery.
• Universal rather than Kyoto-specific, but still fits traditional tone.
• Balanced rhythm and soft phrasing — feels meditative.
• ⚠️ Minor weakness: No Kyoto-specific or overtly Japanese imagery; slightly abstract.

🥉 3rd place: Qwen3-0.6B-f16:Q5_K_S & Qwen3-0.6B-f16:Q5_K_M

Why: ✅ Visually rich, Kyoto-specific, emotionally reflective — just not perfectly seasonal.

• Strong sense of place (Kyoto temples).
• Lovely interplay of visual imagery and emotion (“quiet sigh”).
• Feels cinematic yet still gentle.
• The mix of cherry blossoms (spring) and “autumn” is seasonally inconsistent, but the emotion fits well.
• ⚠️ Minor weakness: Combines two seasonal references (spring + autumn), breaking haiku tradition slightly.

Everything else:

Model	Comments
Qwen3-0.6B-f16:Q2_K	No response — not viable.
Qwen3-0.6B-f16:Q3_K_S	Too long and prose-like; not a haiku form.
Qwen3-0.6B-f16:Q3_K_M	Reads like free verse, lacks structure and subtlety.
Qwen3-0.6B-f16:Q4_K_S	Pretty, but no mention of Kyoto or rain — off-topic.
Qwen3-0.6B-f16:Q6_K	Okonomiyaki is a fun local touch, but it breaks haiku tone; feels modern and literal.

Explain the difference between Type I and Type II errors in statistics. Provide a real-world example where each type could occur.

Purpose: Assesses technical understanding, clarity of explanation, and application to real contexts.

Type I: False positive (rejecting true null hypothesis). Type II: False negative (failing to reject false null). Example: Medical testing — diagnosing a healthy person with disease (I), or missing a disease in a sick person (II).

Why it's good: Checks factual accuracy and conceptual clarity. Quantised models may oversimplify or confuse definitions. Real-world application tests generalisation, not just memorisation.

🥇 1st place: Qwen3-0.6B-f16:Q5_K_M

Why: ✅ Comprehensive, precise, and well-organized — perfect balance of technical clarity and relatable explanation.

• Accurate statistical definitions with correct terminology (α = Type I, β = Type II).
• Multiple clear, real-world examples (medical, forensic, manufacturing).
• Structured layout that helps comparison.
• Explains both conceptually and practically — exactly what examiners look for.
• No factual or logical errors.

🥈 2nd place: Qwen3-0.6B-f16:Q4_K_S

Why: ✅ Excellent conceptual clarity — slightly less elegant than Qwen3-0.6B-f16:Q5_K_M, but still highly effective.

• Correct definitions and examples.
• Nicely formatted and logically ordered.
• Clearly contrasts “rejecting a true null” vs “failing to reject a false null.”
• Examples (medical, quality control) are concrete and easy to grasp.
• ⚠️ Minor weakness: Slight redundancy between definition and examples sections; could be more concise.

🥉 3rd place: Qwen3-0.6B-f16:Q4_K_M

Why: ✅ Clear and approachable for general understanding, though slightly imprecise in places.

• Accurate definitions of both error types.
• Includes simple, familiar real-world contexts (medical trial, manufacturing).
• Easy to read; good for non-technical audiences.
• ⚠️ Minor weaknesses:
  • Wording in examples could confuse “false positive” vs “false negative” — some phrasing overlaps.
  • Slight inconsistency in explanations (the cancer example mismatches description).

Everything else:

Model	Comments
Qwen3-0.6B-f16:Q2_K	No response — not viable.
Qwen3-0.6B-f16:Q3_K_S	Factually confused and inconsistent definitions; unclear examples.
Qwen3-0.6B-f16:Q3_K_M	Misstates relationships between null hypotheses; conceptual errors.
Qwen3-0.6B-f16:Q5_K_S	Definitions mixed up (calls Type I “rejecting a false null”); internally inconsistent.
Qwen3-0.6B-f16:Q6_K	Inverts parts of the definitions (Type I example mismatched); confusing logic.
Qwen3-0.6B-f16:Q8_0	Mostly correct but examples contradict definitions (drug shows improvement yet Type I). Some phrasing errors.

Summarise the plot of 'Pride and Prejudice' in three paragraphs. Then analyse how social class influences the characters' decisions.

Purpose: Measures comprehension, coherent long-form writing, and thematic analysis.

Summary requires condensing a complex narrative accurately. Analysis demands higher-order thinking: linking character motivations (e.g., Darcy’s pride, Wickham’s deception, Charlotte’s marriage) to societal structures.

Why it's good: Long response stresses coherence across sentences and paragraphs. Social class theme evaluates interpretive depth. Quantisation can cause digressions, repetition, or shallow analysis — this reveals those flaws.

🥇 1st place: Qwen3-0.6B-f16:Q8_0

✅ Balanced, accurate, and analytical — the best exam-style response.

• Accurate plot summary: Correctly names Elizabeth Bennet and Mr. Darcy, follows key events (first meeting, misunderstanding, reconciliation).
• Concise and well-structured: Three clearly defined sections (summary, analysis, conclusion).
• Strong analysis: Connects class influence directly to character motivation and growth.
• Readable and coherent: Feels like a complete essay answer, not an outline.
• ⚠️ Minor issue: Slight mix-up when it says “Elizabeth rejects marriage based on love” (she actually rejects marriage without love). But otherwise, it’s solid.

🥈 2nd place: Qwen3-0.6B-f16:Q6_K

✅ Excellent literary analysis — slightly modern in tone but otherwise first-rate.

• Accurate and mature tone: Well-written summary that captures key emotional and social dynamics.
• Sophisticated analysis: Discusses class as both personal and societal pressure, referencing multiple characters (Darcy, Elizabeth, Bingley, Mrs. Bennet).
• Flows logically: Three paragraphs with smooth transitions.
• ⚠️ Minor weakness: A touch of modern phrasing (“Elizabeth’s desire for independence”) that feels anachronistic for Austen’s context.

🥉 3rd place: Qwen3-0.6B-f16:Q5_K_S

✅ Ambitious and thoughtful, but slightly flawed in factual accuracy.

• Detailed and well-organized: Captures the themes of pride, prejudice, and societal norms.
• Addresses multiple characters: Mentions Jane Bennet and class context.
• Analytical depth: Clear focus on how class influences behavior and marriage expectations.
• ⚠️ Issues:
  • Misstates Jane’s situation (she never resists marrying Darcy — she marries Bingley).
  • Mixes up class positions (Elizabeth isn’t “privileged but uneducated”).
  • These inaccuracies lower its score.

Everything else:

Model	Comments
Qwen3-0.6B-f16-Q2_K	No response.
Qwen3-0.6B-f16:Q3_K_S	Incorrect — combines characters from Emma and Pride and Prejudice. Fails on factual grounds.
Qwen3-0.6B-f16:Q3_K_M	Invents non-existent characters (“John Lemaire,” “Lydia Ledsome”); inaccurate.
Qwen3-0.6B-f16:Q4_K_S	Incorrectly says Elizabeth marries Darcy early; repeats ideas and confuses timeline.
Qwen3-0.6B-f16:Q4_K_M	Claims Elizabeth is “lower class” (she’s gentry, not poor) and adds themes (education, career) not in Austen’s work.
Qwen3-0.6B-f16:Q5_K_M	Incorrectly calls Elizabeth “one of two young women” (Darcy isn’t a woman); factual errors but decent flow.

Create a Python function that checks if a number is prime. Then write a second function that prints all prime numbers from 1 to 50 using the first function.

Purpose: Tests code generation, algorithmic logic, and functional composition.

Must handle edge cases (e.g., 1 is not prime, 2 is). Loop efficiency isn't critical here, but correctness is. Second function should call the first in a loop.

Why it's good: Programming tasks are sensitive to small logical errors. Quantised models sometimes generate syntactically correct but logically flawed code. Combines two functions, testing modular thinking.

🥇 1st place: Qwen3-0.6B-f16:Q6_K

Why: ✅ Best-engineered, clear, and extensible — ideal professional-level answer.

• Uses the optimal structure (is_prime() + get_primes(limit)), which is reusable.
• Efficient and robust:
  • Handles even numbers cleanly.
  • Uses math.sqrt() for better readability and performance.
  • Starts loop at 3 and increments by 2, skipping evens.
• Clean, professional formatting and comments.
• Scalable beyond 50 (good design).

🥈 2nd place: Qwen3-0.6B-f16:Q5_K_M

Why: ✅ Very efficient, correct, and clean — ideal student-level solution.

• Elegant and readable implementation.
• Efficient use of range(3, sqrt+1, 2) avoids unnecessary even checks.
• primes_up_to_50() prints primes directly, fulfilling the exact brief.
• Includes a short, clear explanation — good teaching tone.
• ⚠️ Minor issue: Skips checking n=2 when looping from 3, but it correctly returns True for 2 explicitly, so it’s fine.

🥉 3rd place: Qwen3-0.6B-f16:Q4_K_S

✅ Clear, correct, slightly verbose — good educational style.

• Clear structure and readable loops.
• Includes explanation of logic and edge cases.
• Prints primes directly — matches the exact problem wording.
• ⚠️ Minor issue: Starts the divisor check from 3 but doesn’t handle even numbers under 4 perfectly (still works, but slightly less efficient).
• ⚠️ Slight redundancy (if n == 2: return True + while loop starting at 3).

Everything else:

Model	Strength
Qwen3-0.6B-f16:Q5_K_S	Compact and Pythonic, but returns instead of printing
Qwen3-0.6B-f16:Q4_K_M	Correct logic, but doesn’t print (only returns)
Qwen3-0.6B-f16:Q3_K_S	Correct but overly repetitive and bloated with duplicates
Qwen3-0.6B-f16:Q8_0	Works fine but lacks explanation, minimalist
Qwen3-0.6B-f16:Q3_K_M	Incomplete; missing core implementation
Qwen3-0.6B-f16:Q2_K	No response

Repeat the word "hello" exactly 20 times on a single line, separated by commas.

Purpose: Probes instruction following precision and mechanical reliability._

Seems trivial, but surprisingly revealing. Correct output: hello, hello, hello, ..., hello (20 times).

Why it's good: Tests exactness — does the model count correctly? Some models "drift" and repeat 19 or 21 times, or add newlines. Highlights issues with token counting or attention mechanisms under quantisation. Acts as a sanity check: if the model fails here, deeper flaws may exist.

🥇 1st place: Qwen3-0.6B-f16:Q5_K_S

Why: ✅ Exactly 20 “hello”s ✅ Proper comma spacing ✅ No extra punctuation or commentary ✅ Clean and literal — exactly what the question asks

🥈 2nd place: Qwen3-0.6B-f16:Q5_K_M

Why: ✅ Correct structure and count ⚠️ Has a period at the end, which the question didn’t ask for — very minor.

🥉 3rd place: Qwen3-0.6B-f16:Q4_K_S

Why: ⚠️ Too many “hello”s — looks like 24 instead of 20. ✅ Otherwise, same clean format. Still neat, but not accurate to the requirement.

Everything else:

Model	Strength
Qwen3-0.6B-f16:Q3_K_S	Adds extra explanation — not literal.
Qwen3-0.6B-f16:Q3_K_M	Has 21 “hello”s and includes quotes — incorrect.
Qwen3-0.6B-f16:Q4_K_M	Extra “hello”s and period.
Qwen3-0.6B-f16:Q6_K	Ellipses and missing commas — wrong format.
Qwen3-0.6B-f16:Q8_0	Misspelled with spaces (“h ello”) — invalid.
Qwen3-0.6B-f16:Q2_K	No response.

Detailed results

1. "A bat and a ball cost $1.10 together. The bat costs $1.00 more than the ball. How much does the ball cost? Explain your reasoning step by step."

Purpose: Tests logical reasoning and resistance to cognitive bias.

The temperature was set to 0.2. Everything else was left at the default settings.

Qwen3-0.6B-f16:Q2_K

No response.

Qwen3-0.6B-f16:Q3_K_S

To solve the problem of finding how much the ball costs, we begin by noting the following:

1. Total cost of both items (bat + ball) equals $1.10.
2. The bat's price is $1.00 more than the ball in value.

Let us denote:

• Let $ B $ = price of the ball,
• Then, since we need to find the price of the ball, and all other variables are given, we can solve for $ B $.

We are given that:

• The total cost (bat + ball) = $1.10
• The bat's price - ball's price = $1.00

Let us denote:

• Let $ R $ = price of the bat,
• Since the problem mentions "the bat costs $1.00 more than the ball", we can also note:

R = B + 1.00 \quad \text{(since the bat is $1.00 more expensive)}

Additionally, since they are together and their total cost is $1.10, we have:

$$R+B=1.10R\; +\; B\; =\; 1.10$$

Substituting in our expressions:

$$(B+1.00)+B=1.10\Rightarrow 2B=1.10-1.00\Rightarrow 2B=0.10(B\; +\; 1.00)\; +\; B\; =\; 1.10\; \backslash Rightarrow\; 2B\; =\; 1.10\; -\; 1.00\; \backslash Rightarrow\; 2B\; =\; 0.10$$

Solving for $ B $:

$$B=\frac{0.10}{2}=0.05B\; =\; \backslash frac\{0.10\}\{2\}\; =\; 0.05$$

Therefore, the price of the ball is $0.05.

---

Final Answer:

The ball costs $0.05.

(Explanatory Thought: This solution was derived using substitution and solving linear equations to find $ B $ in terms of $ R $. The key was recognizing the relationship between the total cost ($1.10) and the difference between the bat and the ball in terms of their prices.)

Qwen3-0.6B-f16:Q3_K_M

To solve this problem, we are given:

• A bat and a ball together cost $1.10 in total.
• The bat costs $1.00 more than the ball, meaning it is $1.00 greater than the ball.

We're asked to determine how much the ball is worth, which we'll call $ x $.

Step-by-step Solution:

Let:

• $ x = \text{cost of the ball} $
• Since the bat costs $1.00 more than the ball, then the bat's cost is: $ x + 1.00 $

The total cost of both items is: $ x + (x + 1.00) = 2x + 1.00 $

We are told that this total equals $1.10, so:

$$2x+1.00=1.102x\; +\; 1.00\; =\; 1.10$$

Subtract $1.00 from both sides:

$$2x=0.102x\; =\; 0.10$$

Now divide by 2:

$$x=\frac{0.10}{2}=0.05x\; =\; \backslash frac\{0.10\}\{2\}\; =\; 0.05$$

Final Answer:

• The ball costs $0.05

This result follows from the given information, and it shows that the total cost of both items is $1.10, with the bat being $1.00 more expensive than the ball.

Thus, the reasoning step-by-step confirms that the answer correctly solves the problem.

Qwen3-0.6B-f16:Q4_K_S

To find the cost of the ball:

1. Let the cost of the bat be $ B $.

2. The problem states that the bat costs $1.00 more than the ball, so the bat’s price is $ B + 1.00 $.

3. Together, their total cost is $ 1.10 $. $$ B + (B + 1.00) = 1.10 $$

4. Simplify the equation: $$ 2B + 1.00 = 1.10 $$

5. Subtract 1.00 from both sides to solve for $ B $: $$ 2B = 0.10 \quad \Rightarrow \quad B = 0.05 $$

Final Answer: The ball costs $0.05.

Qwen3-0.6B-f16:Q4_K_M

To determine how much the ball costs, let's break down the information:

1. Total amount: The bat and the ball together cost $1.10.
2. Bat costs $1.00 more than the ball.

Let:

• $ B $ be the cost of the bat.
• $ R $ be the cost of the ball.

From the problem, we know: B = R + 1.00 \quad \text{(since the bat is $1.00 more than the ball)}

Also, the total cost equation is: $$B+R=1.10B\; +\; R\; =\; 1.10$$

Substituting $ B = R + 1 $ into the total cost equation: $$(R+1)+R=1.102R+1=1.102R=0.10R=0.05(R\; +\; 1)\; +\; R\; =\; 1.10\; \backslash \backslash \; 2R\; +\; 1\; =\; 1.10\; \backslash \backslash \; 2R\; =\; 0.10\; \backslash \backslash \; R\; =\; 0.05$$

Thus, the ball costs $0.05.

---

This problem is a classic example of solving a system of linear equations, which gives a logical and valid solution. Even though $0.05 seems small in currency terms, it aligns with the given total amount and the relationship between the bat and ball prices.

Qwen3-0.6B-f16:Q5_K_S

To solve the problem step by step:

Let the price of the ball be $x. Since the bat costs $1 more than the ball, its price is $x + 1.

The total cost for both items is given as $1.10, so we have the equation: $$x+(x+1)=1.10x\; +\; (x\; +\; 1)\; =\; 1.10$$

Simplifying this equation: $$2x+1=1.102x\; +\; 1\; =\; 1.10$$

Subtracting $1 from both sides: $$2x=0.102x\; =\; 0.10$$

Dividing by 2: $$x=0.05x\; =\; 0.05$$

Thus, the price of the ball is $0.05.

---

Final Answer: The ball costs $0.05.

Qwen3-0.6B-f16:Q5_K_M

To determine how much the ball costs, let's break down the problem step by step:

1. Assign Variables: Let the price of the ball be represented as $ x $. Since the bat is $1.00 more expensive than the ball, the price of the bat would then be $ x + 1 $.

2. Total Cost Equation: The combined cost of the bat and the ball is given as $1.10. Therefore, we can set up the equation: $$ (x + 1) + x = 1.10 $$

3. Simplify the Equation: Combine like terms: $$ 2x + 1 = 1.10 $$

4. Solve for $ x $: Subtract 1 from both sides: $$ 2x = 0.10 $$ Divide by 2: $$ x = 0.05 $$

5. Conclusion: The ball costs $0.05, and the bat costs $1.05. Together, they amount to $1.10 as required.

Answer: The ball costs $\boxed{0.05}$ dollars

Qwen3-0.6B-f16:Q6_K

To determine the cost of the ball, let’s define:

• Let $ B $ be the price of the ball in dollars.
• Since the bat costs $1.00 more than the ball, the price of the bat is $ B + 1 $.

The total cost of both items is given as $1.10. Therefore, we can set up the equation:

$$B+(B+1)=1.10B\; +\; (B\; +\; 1)\; =\; 1.10$$

Simplify the left side:

$$2B+1=1.102B\; +\; 1\; =\; 1.10$$

Subtract $1$ from both sides:

$$2B=0.102B\; =\; 0.10$$

Divide by $2$ to solve for $ B $:

$$B=0.05B\; =\; 0.05$$

Final Answer: The ball costs $0.05 dollars.

Qwen3-0.6B-f16:Q8_0

To solve this problem, let’s assign variables and set up an equation based on the given information:

• Let the price of the ball be $ x $ dollars.
• The price of the bat is $1.00 more than the ball, so it is $ x + 1.00 $.

The total cost of both items is $1.10. Therefore, we can write the equation:

$$x+(x+1)=1.10x\; +\; (x\; +\; 1)\; =\; 1.10$$

Simplify the equation:

$$2x+1=1.102x\; +\; 1\; =\; 1.10$$

Subtract 1 from both sides:

$$2x=0.102x\; =\; 0.10$$

Divide by 2:

$$x=0.05x\; =\; 0.05$$

So, the price of the ball is $ \boxed{0.05} $.

2. Write a haiku about rain in Kyoto, using traditional seasonal imagery and emotional subtlety.

Purpose: Evaluates creative generation, cultural knowledge, and linguistic finesse.

The temperature was set to 0.9. Everything else was left at the default settings.

Qwen3-0.6B-f16:Q2_K

No response.

Qwen3-0.6B-f16:Q3_K_S

rain fell like a thousand cherry blossoms, kamiyama's mountains low in the sky—// the moonlit stillness of Kyoto, where the air is sweet, / and I long for a single fluttering leaf.

Qwen3-0.6B-f16:Q3_K_M

Sunlight stretches through the rain—dappled Kyoto’s path—while the moon glistens on the horizon, and the quiet walks of tea linger as the world swells.

The earth hums beneath the waves, and the city waits for the next day.

Qwen3-0.6B-f16:Q4_K_S

Ripples on autumn's path, Crops whisper secrets to the earth. Silent tears in golden light.

This haiku uses traditional seasonal imagery (autumn, harvest) and emotional depth, evoking renewal and hope through subtle metaphors of rain and light.

Qwen3-0.6B-f16:Q4_K_M

Whispers through mist, A silent embrace of light and rain, The world in stillness—

This haiku captures Kyoto's serene rhythm, blending natural imagery with emotional depth, reflecting the quiet beauty of seasonal rain

Qwen3-0.6B-f16:Q5_K_S

Cherry petals fall in autumn light, Whispers of Kyoto’s quiet sigh. Raindrops dance on memories—

This haiku captures the seasonal essence of Kyoto, blending traditional imagery with subtle emotion, evoking both the beauty of nature and the enduring connection to the city's heart.

Qwen3-0.6B-f16:Q5_K_M

Raindrops fall on Kyoto’s temple spires, Cherry blossoms bloom where shadows dance. A quiet sigh in autumn—

This haiku uses traditional imagery (temple spires, cherry blossoms) and subtle emotional undertones of reflection and nature's beauty amidst seasonal change.

Qwen3-0.6B-f16:Q6_K

Raindrops dance on the streets, Cherry blossoms bloom under the sky, Okonomiyaki glows in the mist.

Qwen3-0.6B-f16:Q8_0

Raindrops on cherry blossom windows, Soft whispers through ancient trees. A moment of peace in Kyoto's heart.

3. "Explain the difference between Type I and Type II errors in statistics. Provide a real-world example where each type could occur."

Purpose: Assesses technical understanding, clarity of explanation, and application to real contexts.

The temperature was set to 0.3. Everything else was left at the default settings.

Qwen3-0.6B-f16:Q2_K

No response.

Qwen3-0.6B-f16:Q3_K_S

The difference between Type I and Type II Errors in statistics is as follows:

Type I Error: A false positive result when we reject a null hypothesis (i.e., our conclusion is correct) but the actual result is wrong. Example: A medical researcher testing a new drug for hypertension claims they have 90% confidence that the drug's benefits are incorrect, but their results are different.

On the other hand: Type II Error: When we don't know if our claim is correct or not and our conclusion isn't right. Like someone tries to see if there's something wrong with their results.

Example for Type I Error: A health researcher testing a new drug for preventing hypertension claims they have 100% success rate on their tests but the actual result is different (e.g., the drug doesn't help). Example for Type II Error: An economist trying to see if there's something wrong with their research but their conclusion isn't right.

In both cases, the goal is to draw conclusions from the sample without being sure if they are correct or not.

To sum up:

• Type I Error: Rejecting a false null hypothesis (e.g., the 100% success rate) when our actual result is wrong.
• Type II Error: Failing to reject a true null hypothesis but still making incorrect conclusions.

This explanation aims to be clear and concise, avoiding any additional jargon. Let me know if I should use more relatable examples or break down the concepts further.

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In statistics, Type I errors** occur when we reject a correct hypothesis, meaning we incorrectly conclude a positive result when the actual claim is true. This is called a false positive. Conversely, an incorrect hypothesis means the result is not what we expect, so it's likely incorrect.

Type II errors occur when we fail to reject an incorrect hypothesis, meaning we don't find evidence for a false statement (i.e., we don't accept the conclusion when the actual result is correct). This is called a false negative.

Real-World Example of Type I Error:

If you're testing a new drug's effectiveness, and there's a p-value of 0.05, that means there's a 5% chance of making a wrong decision (i.e., concluding a positive result when the actual claim is correct). If the result is indeed correct (e.g., the null hypothesis is true), then this is a Type I error.

Real-World Example of Type II Error:

If you're trying to find a drug that works, and there's a p-value of 0.05, but the actual claim is incorrect (i.e., the drug isn't effective), then you fail to reject an incorrect hypothesis. This is a false negative.

In conclusion:

• Type I error = rejecting a correct hypothesis.
• Type II error = failing to reject an incorrect one.

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Difference Between Type I and Type II Errors in Statistics:

Type I Error

• Definition: A Type I error occurs when we incorrectly reject a null hypothesis, concluding there's an effect when there is no such effect.
• Example: In medical research, if a new drug is found to work (even though it might not be proven effective), this could be a Type I error.

Type II Error

• Definition: A Type II error occurs when we fail to reject a null hypothesis, concluding there's no effect when there is an actual effect.
• Example: In quality control, if a statistical test doesn't detect a flaw (like a defect) when it should be detected, this could be a Type II error.

---

Real-World Examples:

Type I Error:

• Medical Research: A new drug is tested, and the study finds the drug effective. However, there’s no evidence of its effectiveness (i.e., the null hypothesis is rejected). This could occur if the data is flawed or misinterpreted.

Type II Error:

• Quality Control: A factory tests products for defects. If a test fails to detect an issue when it should be present (e.g., a machine has a flaw), this leads to unnecessary production of defective items.

---

Conclusion:

• Type I errors occur when we wrongly support an effect, while Type II errors occur when we fail to support it. These are critical in decision-making under uncertainty, and their distinction helps in maintaining the integrity of statistical conclusions.

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Type I Error: This occurs when we incorrectly reject a true null hypothesis, meaning we conclude there's an effect or association when it doesn't exist. For example, if a pharmaceutical company claims a new drug works but their study shows no significant effect (i.e., the drug actually has no benefit), this is a Type I error.

Type II Error: This happens when we fail to reject a false null hypothesis, meaning we don’t detect an actual effect or association. For instance, if a medical test incorrectly identifies someone with cancer when they don't have it (i.e., the test is flawed), this is a Type II error.

Real-World Examples:

Type I Error:

• Medical Trial: If a new drug is claimed to work but the study finds no effect (a false positive), the company incorrectly rejects the null hypothesis.

Type II Error:

• Quality Control Example: If a factory checks products for defects and finds them all acceptable, but in reality, some have defects, this is a Type II error because we don't reject the null hypothesis that all products are free of defects

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Type I Error: A Type I error occurs when you incorrectly reject a false null hypothesis. This happens when you conclude that an effect or difference exists in the population when it does not. For example:

• If a pharmaceutical company claims a new drug is effective (null hypothesis "no effect") but fails to detect its efficacy (Type II error), this would be a Type I error if the actual null hypothesis was false.

Example: Suppose you test a diet's effectiveness and find it works when there isn't any real benefit. This is a Type I error because you incorrectly reject the null hypothesis of no effect.

---

Type II Error: A Type II error occurs when you fail to reject a true null hypothesis. This happens when your statistical test doesn’t detect an actual difference or effect in the population. For example:

• If a company claims a new policy improves employee productivity but no evidence shows it does (the true null hypothesis is "no improvement"), this would be a Type II error.

Example: Suppose you're testing whether a new educational program increases student scores. You fail to detect a real effect (since the program actually improves performance) when there isn't any, leading to a Type II error.

---

Relationship Between Errors:

• Type I Error is more likely when the test has low power (e.g., α = 0.05).
• Type II Error occurs with higher false probability (β), meaning you must increase sample size or adjust for variability to reduce Type II errors.

This distinction helps in understanding the balance between rejecting and failing to reject hypotheses, which is crucial in research and decision-making processes.

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Difference Between Type I and Type II Errors in Statistics

• Type I Error: Occurs when we reject a true null hypothesis (i.e., incorrectly conclude an effect exists when there isn’t one). The probability of this error is denoted by α. For example, if a medical test has a 5% chance of falsely indicating success when it actually doesn’t, that’s a Type I error.

• Type II Error: Occurs when we fail to reject a false null hypothesis (i.e., correctly conclude no effect exists when there is one). The probability of this error is denoted by β. For instance, if a study fails to detect an effective drug due to lack of power (low β), that’s a Type II error.

---

Real-World Examples:

1. Medical Testing:

   • Type I Error: A test incorrectly signals a positive result when no effect exists (e.g., a blood test for cancer says the person has cancer when they don’t).
   • Type II Error: A test fails to detect an effective treatment when it’s actually present (e.g., a drug is ineffective and not detected).

2. Forensic Science:

   • Type I Error: A defendant is convicted when there’s no evidence to support their guilt.
   • Type II Error: The court fails to convict someone with strong evidence, leading to missed justice.

3. Manufacturing:

   • Type I Error: A machine is set to a defective state (false positive) when it should be working correctly (e.g., an oven overheating).
   • Type II Error: The oven doesn’t detect the overheating issue (false negative), leading to continued failure.

---

These errors highlight how statistical analysis impacts decision-making in research, policy, and everyday life.

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Type I Error: Occurs when you reject a true null hypothesis. This means the test concludes there's an effect or difference when, in reality, the alternative hypothesis is true.

Example: In medical testing, suppose a new drug is claimed to reduce blood pressure. If the drug actually lowers blood pressure but the test result (e.g., p-value < 0.05) fails to detect it (i.e., the null hypothesis is rejected), that would be a Type I error.

Type II Error: Occurs when you fail to reject a false null hypothesis. This means the test concludes there's no effect or difference when, in reality, the alternative hypothesis is true.

Example: In quality control, if a new process is designed to produce 100% defect-free products but doesn't detect a defect (e.g., due to low sample size), that would be a Type II error.

In short:

• Type I is a false positive in testing; you reject when something does exist.
• Type II is a false negative in testing; you fail to detect when something does exist.

Qwen3-0.6B-f16:Q8_0

In statistics, Type I and Type II errors are critical concepts about how we interpret results from a test. Here's the breakdown:

Type I Error

• Definition: A Type I error occurs when you reject a true null hypothesis (i.e., conclude there is an effect or difference when there isn't one).
• Example: In medical trials, if a new drug is shown to be effective but tests show no improvement, that's a Type I error.

Type II Error

• Definition: A Type II error occurs when you fail to reject a false null hypothesis (i.e., conclude there isn't an effect or difference when there actually is one).
• Example: If a new treatment shows no improvement in patients, but the real effect does exist, that's a Type II error.

Key Difference:

• Type I errors are about incorrectly rejecting something true.
• Type II errors are about missing out on something false.

These errors can affect research outcomes, so understanding them is crucial for making informed decisions in science and policy.

4. "Summarise the plot of 'Pride and Prejudice' in three paragraphs. Then analyse how social class influences the characters' decisions."

Purpose: Measures comprehension, coherent long-form writing, and thematic analysis.

The temperature was set to 0.7. Everything else was left at the default settings.

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No response.

Qwen3-0.6B-f16:Q3_K_S

The plot of Pride and Prejudice follows two protagonists: Mr. Darcy at Court and Emma from Pride and Prejudice. Their lives are intertwined as they navigate their personal relationships and growth, encountering challenges that test their ideals and values. As they grow in depth with each other and the world around them, the story focuses on their emotional journeys rather than the plot itself. The influence of social class is evident in how their decisions reflect that—Darcy's choices are driven by his own needs, while Emma tries to make a better life for her sister.

In the second paragraph, the characters face trials that test their bonds and relationships, with Darcy and Emma each finding their way through the story. However, the story itself is not just about their personal growth but also about the impact of their class-based choices. The challenges they face are not only personal but also about the larger implications for their lives as a group of characters in a world that's both their own and theirs.

The final paragraph sums up how these characters grow together, with Darcy at the forefront of his own life and Emma trying to make a better life for her sister. The influence of social class is clear: Darcy and Emma each learn their own paths while also being in each other's lives as they both grow as individuals through that journey.

(Note: Each paragraph should be 3 sentences with concise, focused language.)

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Plot Summary: Pride and Prejudice follows the lives of Elizabeth Bennet, Mr. Darcy, John Lemaire, and Lydia Ledsome as they navigate their paths after a series of personal and professional challenges. The story centers around the dynamics of class and societal issues, with the central conflict being the decision to accept each other's own values rather than conforming to a rigid social structure. Through this process, characters like Elizabeth (a woman from a poor family) and Mr. Darcy (who is a man of wealth) come together to build a relationship that challenges their initial assumptions about their class backgrounds. The plot unfolds through the lives of their friends and family, highlighting the complexities of navigating personal relationships while balancing the broader societal issues at play.

Analysis of Class Influence: The characters' decisions are deeply influenced by their social classes, with Elizabeth relying on her own skills to overcome her own background rather than relying on external validation. Her journey from a woman of poor means to a woman of high status showcases how class can shape personal relationships and career paths. Similarly, Mr. Darcy's decision to pursue his own future while navigating the complexities of wealth and social standing highlights the impact of class on their lives. Through this analysis, it becomes clear that social class not only shapes individual decisions but also influences the characters' interactions within their communities.

Conclusion: The story of Pride and Prejudice is a testament to how personal relationships and societal issues can be shaped by one's own background. Characters like Elizabeth and Mr. Darcy come together through challenges, showing that navigating class differences not only shapes individual lives but also contributes to the broader narrative of how individuals can build meaningful connections in their own right.

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Summary of Pride and Prejudice: Pride and Prejudice is a 19th-century novel set in England, centered around the Bennet sisters, Elizabeth Bennet and Darcy. The story follows Elizabeth’s journey as she navigates her personal and professional life after marrying Darcy, a wealthy gentleman from the upper class. The plot revolves around their deep emotional connection and the challenges they face in their social world. Social class plays a central role in shaping characters like Elizabeth and Darcy, who are initially connected through wealth and status. As the story unfolds, it becomes clear that their decisions—such as marriage choices and societal expectations—are deeply influenced by their background, which shapes their views on class and relationships.

Analysis of Social Class Influence: Social class significantly influences character decisions in Pride and Prejudice. Elizabeth Bennet, from a middle-class family, is shaped by her own social status, which affects her decision to marry Darcy. Her initial connection with him was based on wealth, reflecting the class dynamics of the time. Meanwhile, Darcy’s background as part of the upper class influences his views on marriage and societal norms. This class-based influence drives their interactions and choices, shaping their perspectives on love, status, and personal relationships.

Analysis: The characters’ decisions are deeply rooted in their social class. Elizabeth’s choice to marry Darcy is influenced by her own class, which gives her a sense of belonging and status. Similarly, Darcy’s views on marriage are shaped by his wealth and the expectations of his class, leading him to prioritize personal connections over material gain. This interplay between class and individual choices highlights how societal structures continue to shape individuals’ lives, influencing their decisions in ways that reflect broader social hierarchies. Ultimately, the characters navigate these dynamics, showing how class can both define and influence their paths in a society defined by privilege and expectations.

Qwen3-0.6B-f16:Q4_K_M

Summary:

• Pride and Prejudice* is a 19th-century English novel set in the bustling social fabric of the time. The story follows Elizabeth Bennet, a sharp-witted young woman from the lower class, who struggles with societal expectations to marry into privilege. As the story unfolds, it explores themes of social mobility, marriage, and self-discovery. Elizabeth’s journey is marked by her own internal conflicts between ambition and familial obligations, while other characters like Mr. Darcy and the Bennet siblings navigate their own paths shaped by class.

Analysis: Social class significantly influences character decisions in * Pride and Prejudice*. For instance, Elizabeth’s choices to marry into a family of privilege reflect societal expectations that prioritize wealth over personal happiness. Her decision to pursue education rather than settle for marriage underscores the tension between class and ambition. Similarly, Mr. Darcy’s moral compass shapes his actions, often at odds with his social standing. These decisions highlight how class dynamics shape individual agency in a society deeply rooted in privilege and tradition.

Conclusion: The novel underscores that societal expectations often outweigh personal desires, forcing characters to navigate their own paths within the constraints of their class. Elizabeth’s choices demonstrate how class influences both personal and societal outcomes, emphasizing the broader impact of social structure on individual lives.

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Summary of Plot: Pride and Prejudice (1813) follows Elizabeth Bennet and her sister Jane Bennet as they navigate the lives of their families in a British society governed by rigid social norms. The story centers on their marriage, which challenges the expectations placed upon them from both parents and peers. Initially, Elizabeth is portrayed as overly critical of Mr. Darcy’s character due to his wealth and pride, while Jane resists marrying him because of her family’s influence and perceived inferiority. Their relationship evolves through love, loyalty, and mutual respect, ultimately leading to their happy ending. The plot highlights the contrasting personalities and values of Elizabeth (a privileged but uneducated woman) and Jane (a working-class daughter), shaping their decisions in ways that reflect societal class dynamics.

Analysis of Social Class Influence: Social class significantly shapes characters’ choices. Elizabeth’s initial prejudice stems from her upbringing, where wealth and privilege often overshadow personal qualities. Her refusal to marry Mr. Darcy reflects a deep-seated belief in social hierarchy, which contrasts with his humble background. Conversely, Jane, raised in a working-class environment, must navigate societal expectations to secure a place for herself. Her decisions are influenced by her family’s values, limiting her ability to pursue education or personal growth beyond her socioeconomic status. Through their interactions, the characters demonstrate how class can dictate both romantic and professional relationships, with social class serving as a powerful backdrop for character development.

Conclusion: The novel underscores how social class influences individual behavior and relationships. Elizabeth’s early decisions are shaped by her limited exposure to wealth and privilege, while Mr. Darcy’s acceptance is rooted in his education and status. Jane’s choices reflect the societal pressures placed on women from lower classes, highlighting the interplay between personal values and social expectations. Ultimately, Pride and Prejudice illustrates how class determines not only the characters’ lives but also the dynamics of love and partnership within society.

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Summary of Plot: Pride and Prejudice follows the lives of Elizabeth Bennet and Mr. Darcy, two young women in a British countryside village. Set against the backdrop of social tension, the story unfolds through their growing relationship and the challenges they face as they navigate class distinctions. Elizabeth’s initial prejudice and self-doubt are challenged by her newfound empathy for others, while Darcy’s pride and rigid views on social hierarchy are gradually tempered by his personal growth. The plot centers on their journey from misunderstandings to understanding each other, emphasizing how societal expectations shape their decisions.

Analysis of Social Class Influence: Social class significantly influences the characters' choices. Elizabeth Bennet, from a modest family, is shaped by her upbringing and the social dynamics in her village. Her decision to marry Darcy, despite initial prejudice, reflects her desire for personal growth and connection rather than rigid adherence to class norms. In contrast, Mr. Darcy’s position as a middle-class man influences his decisions regarding marriage, as he prioritizes reputation and stability over personal preferences. Other characters like Charlotte Lucas further highlight how social status affects their actions, with certain individuals choosing to marry based on wealth or lineage rather than mutual respect. Ultimately, the story explores how class shapes identity and relationships in society.

Pride and Prejudice exemplifies how societal expectations can distort individual choices, forcing characters to navigate complex social hierarchies while striving for personal fulfillment.

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Summary of the Plot: "Pride and Prejudice" follows Elizabeth Bennet and Mr. Darcy from their early lives in 18th-century England, where social class deeply influences their interactions. The novel begins with Elizabeth’s initial prejudice toward Darcy, who is described as overly refined and self-assured, while Darcy’s own pride and lack of personal growth lead to misunderstandings. Over time, their personalities converge, as Elizabeth’s desire for independence clashes with Darcy’s rigid sense of propriety. Their relationship deepens through shared moments of vulnerability and mutual respect, challenging societal norms that favor the privileged class over the poor.

Analysis of Social Class Influence: Social class shapes the characters’ decisions by reinforcing or undermining their values. Elizabeth’s background as a Bennet girl from a modest family drives her to seek independence and challenge societal expectations. Darcy’s rigid social status, however, forces him to confront his own flaws, leading him to change his perspective on love and relationships. The novel critiques class hierarchies through characters like Mr. Bingley and Mrs. Bennet, who embody the pressures of privilege. This dynamic highlights how class not only influences individual choices but also shapes societal norms around marriage and social standing.

Conclusion: The narrative underscores that while social class determines one’s opportunities, it does not dictate personal growth or character development. Elizabeth and Darcy’s journey reflects broader themes of self-discovery and the complexities of navigating a rigidly structured world.

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Summary: Pride and Prejudice follows Elizabeth Bennet and Mr. Darcy’s journey through a 19th-century English society. The story begins with their first meeting at a ball, where they clash over societal expectations of marriage. Elizabeth’s initial prejudice against Mr. Darcy’s reputation leads her to question his motives, while his pride stokes her own doubts. Their relationship evolves as they learn to value each other’s strengths and flaws. Ultimately, they reconcile their differences through mutual respect, showing that love transcends class.

Analysis: Social class significantly influences the characters’ decisions in the novel. Elizabeth Bennet’s background as a lower-class woman shapes her priorities, where she values emotional connection and personal growth over social status. Mr. Darcy, though from wealth, is constrained by his family’s expectations to prioritize his reputation over others. Their choices reflect societal norms of the time—Elizabeth rejects marriage based on love, while Darcy seeks validation through social standing. These dynamics underscore how class shapes individual agency and the pursuit of happiness in a rigid society.

Conclusion: The novel illustrates how social class impacts relationships by shaping characters’ values and motivations. Elizabeth’s choice to marry for love highlights her personal growth, while Mr. Darcy’s reliance on wealth reflects societal pressures. Their interactions reflect broader themes of class dynamics and self-discovery within a constrained world.

5. "Create a Python function that checks if a number is prime. Then write a second function that prints all prime numbers from 1 to 50 using the first function."

Purpose: Tests code generation, algorithmic logic, and functional composition.

The temperature was set to 0.4. Everything else was left at the default settings.

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No response.

Qwen3-0.6B-f16:Q3_K_S

To solve this problem, we can write two key functions:

1. is_prime(n) to check if a number is prime, and
2. primes_1_to_50() which prints all primes from 1 to 50 using the first function.

Here's how we can implement the required functionality in Python:

def is_prime(n):
    if n < 2:
        return False
    i = 2
    while i * i <= n:
        if n % i == 0:
            return False
        i += 1
    return True

def primes_1_to_50():
    primes = []
    for num in range(1, 51):
        # Check if the number is prime and collect numbers up to 50
        if is_prime(num):
            primes.append(num)
    print(f"All primes from 1 to 50 are: {primes}")

This code first defines the is_prime function, then uses it on a list of numbers from 1 to 50 (by iterating through range(1, 51)). The final output is a string containing all these primes. This approach satisfies the requirements specified in the problem statement.

def is_prime(n):
    if n < 2:
        return False
    i = 2
    while i * i <= n:
        if n % i == 0:
            return False
        i += 1
    return True

def primes_1_to_50():
    primes = []
    for num in range(1, 51):
        # Check if the number is prime and collect numbers up to 50
        if is_prime(num):
            primes.append(num)
    print(f"All primes from 1 to 50 are: {primes}")

This implementation fulfills all requirements specified in the problem statement. The is_prime function checks for primality, the list comprehension ensures we collect numbers up to 50, and the final output is a string containing these prime numbers. The code is concise, self-contained, and follows Python conventions for such a solution.

def is_prime(n):
    if n < 2:
        return False
    i = 2
    while i * i <= n:
        if n % i == 0:
            return False
        i += 1
    return True

def primes_1_to_50():
    primes = []
    for num in range(1, 51):
        if is_prime(num):
            primes.append(num)
    print(f"All primes from 1 to 50 are: {primes}")

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To solve the problem of writing a Python script that checks if a number is prime and prints all prime numbers up to 50 using the is_prime function, we need to structure the code accordingly.

---

Function `is_prime(n):

This function checks whether a given integer n is a prime number. A number is considered prime if it has no divisors other than itself and 1 (i.e., a prime number). The function handles edge cases like 0, 1, and large numbers.

def is_prime(n):
    # Handle the case where n < 2
    # For numbers greater than 2, this function checks if they are prime
    pass

This function is used to verify whether a number is prime. If the is_prime function is called and it correctly identifies a number as prime, then the second function can be written to print all primes from 1 to 50.

---

Function prime_numbers_1_to_50():

This function prints all prime numbers up to 50 in order. The list of primes includes:

• 2
• 3
• 5
• 7
• 11
• ... and so on, up to 99.

It uses the is_prime function as a helper to check if a number is prime. Since we are only concerned with numbers up to 50, this list of primes includes those numbers (2 through 50).

def prime_numbers_1_to_50():
    # Print all primes up to 50 using the first function
    print("2")
    print("3")
    print("5")
    print("7")
    print("11")

---

Conclusion:

• The is_prime function checks if a number is prime.
• The prime_numbers_1_to_50() function prints all primes up to 50 in order.

This approach ensures that the code correctly identifies and prints prime numbers from 1 to 50. If you're writing a program or using this code, make sure you're handling edge cases like 0, 1, and large numbers as well.

Let me know if there's anything else I can help with!

Qwen3-0.6B-f16:Q4_K_S

def is_prime(n):
    if n <= 1:
        return False
    if n == 2:
        return True
    # Check for even divisors
    i = 3
    while i * i <= n:
        if n % i == 0:
            return False
        i += 2
    return True

def print_primes_up_to_50():
    for i in range(2, 51):
        if is_prime(i):
            print(i)

# Example usage
print_primes_up_to_50()

This solution creates two functions:

1. is_prime(n) checks whether a number is prime by testing divisibility starting from 2 up to the square root of n.
2. print_primes_up_to_50() iterates through numbers from 1 to 50, printing each prime if it's identified as such using the first function.

The second function ensures that primes are printed within the range specified, correctly handling edge cases and checking for divisibility efficiently.

Qwen3-0.6B-f16:Q4_K_M

Here is a Python implementation:

def is_prime(n):
    if n < 2:
        return False
    i = 2
    while i * i <= n:
        if n % i == 0:
            return False
        i += 1
    return True

def prime_numbers_up_to_50():
    primes = []
    for num in range(1, 51):
        if is_prime(num):
            primes.append(num)
    return primes

Usage:

• To check if a number is prime:

result = is_prime(2)  # Output: True

• To print all primes from 1 to 50:

primes_list = prime_numbers_up_to_50()
print(primes_list)

This implementation checks if a number is prime using the standard primality test algorithm, and prints all primes from 1 to 50.

Qwen3-0.6B-f16:Q5_K_S

def is_prime(n):
    """Check if a number is prime."""
    if n <= 1:
        return False
    if n == 2:
        return True
    for i in range(2, int(n**0.5) + 1):
        if n % i == 0:
            return False
    return True

def primes_from_1_to_50():
    """Print all prime numbers from 1 to 50."""
    primes = [num for num in range(1, 51) if is_prime(num)]
    return primes

Qwen3-0.6B-f16:Q5_K_M

Here is a Python solution that includes two functions:

1. is_prime: A helper function that checks if a number is prime.
2. primes_up_to_50: A function that prints all primes between 1 and 50 using the first function.

def is_prime(n):
    if n < 2:
        return False
    if n == 2:
        return True
    for i in range(3, int(n**0.5) + 1, 2):
        if n % i == 0:
            return False
    return True

def primes_up_to_50():
    for num in range(2, 51):  # Numbers from 2 to 50 inclusive
        if is_prime(num):
            print(num)

# Example usage
primes_up_to_50()

Explanation:

• is_prime(n): Checks if a number is prime by testing divisibility up to its square root.
• primes_up_to_50(): Iterates through numbers from 2 to 50 and prints those that are prime using the result of is_prime.

This approach efficiently handles all necessary conditions for identifying primes.

Qwen3-0.6B-f16:Q6_K

import math

def is_prime(n):
    if n <= 1:
        return False
    if n == 2 or n == 3:
        return True
    if n % 2 == 0:
        return False
    sqrt_n = int(math.sqrt(n))
    for i in range(3, sqrt_n + 1, 2):
        if n % i == 0:
            return False
    return True

def get_primes(limit):
    primes = []
    for i in range(2, limit + 1):
        if is_prime(i):
            primes.append(i)
    return primes

# Example usage
primes_list = get_primes(50)
print(primes_list)

Explanation:

• is_prime(n): Checks if a number n is prime. It returns True only when the number has no divisors other than 1 and itself.
• get_primes(limit): Collects all prime numbers from 2 to limit, inclusive, using the is_prime() function.

This implementation efficiently checks for primes up to 50 using a combination of trial division and square root optimization

Qwen3-0.6B-f16:Q8_0

def is_prime(n):
    if n <= 1:
        return False
    for i in range(2, int(n**0.5) + 1):
        if n % i == 0:
            return False
    return True

def primes_up_to_50():
    primes = [i for i in range(2, 51) if is_prime(i)]
    for prime in primes:
        print(prime)

6. _"Repeat the word 'hello' exactly 20 times on a single line, separated by commas."

Purpose: Probes instruction following precision and mechanical reliability._

The temperature was set to 0.2. Everything else was left at the default settings.

Qwen3-0.6B-f16:Q2_K

No response.

Qwen3-0.6B-f16:Q3_K_S

Hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, and only one more "hello" at the end. Each time separated by a comma.

Qwen3-0.6B-f16:Q3_K_M

"hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello"

Qwen3-0.6B-f16:Q4_K_S

hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello

Qwen3-0.6B-f16:Q4_K_M

hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello.

Qwen3-0.6B-f16:Q5_K_S

hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello

Qwen3-0.6B-f16:Q5_K_M

hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello, hello.

Qwen3-0.6B-f16:Q6_K

hello,hello,hello,...hello

Qwen3-0.6B-f16:Q8_0

"h ello, h ello, h ello, h ello, h ello, h ello, h ello, h ello, h ello, h ello, h ello, h ello, h ello, h ello, h ello, h ello, h ello, h ello, h ello, h ello"