Thoughts on Teaching Math with technology

Saturday, January 24, 2026

"Fiber" for the Mind: Using Data Visualization to Teach Fractions

For many students, the word "fractions" triggers an immediate mental block. It’s the point where math often stops feeling like a count of physical objects—three apples, four pencils—and starts feeling like a series of abstract rules. Why do we flip the second number when we divide? Why is $1/4$ smaller than $1/2$ when 4 is clearly bigger than 2?

In the 2026 classroom, we are solving this "abstraction gap" by treating fractions as data visualization. By using professional tools like Tableau or everyday software like Google Sheets, we can give students "fiber for the mind"—substance that is easy to digest, keeps the brain engaged, and provides a clear structure to complex information.

From Worksheets to Visual Stories

Traditionally, fractions are taught using a "pizza" or a "pie." While effective for basics, these static shapes struggle to explain larger-scale proportions or real-world application. Data visualization software changes the game by allowing students to turn raw numbers into interactive proportions.

Imagine a lesson where students don't just look at $3/10$ on a page, but instead import a dataset of their class’s favorite snacks. Using a Treemap in Tableau, the software creates nested rectangles where the size of each box is perfectly proportional to its fraction of the total. Students can see that if "Fruit" is $1/4$ of the snacks, it takes up exactly one quarter of the screen’s area.

Why do tools like google sheets and tableau work? They provide instant feedback. In a Google Sheet, a student can change a denominator and watch a pie chart or bar graph shift in real-time. This instant "cause and effect" builds an intuitive understanding of how the size of the "whole" changes when the "parts" are modified.

Second, these programs allow students to compare visualizations. One of the hardest concepts for students is comparing fractions with different denominators. In a digital environment, students can stack two bar charts side-by-side. Seeing a bar representing $2/3$ clearly stretching past a bar representing $5/8$ provides a "Eureka!" moment that a common denominator calculation on paper often fails to deliver.

Finally, it allows students to put factions into a real-world context. Data viz allows teachers to use "messy" real-world data. Students can analyze the fraction of the Earth's surface covered by oceans versus land, or the fraction of a 24-hour day spent sleeping. When the fraction represents something real, the math becomes a tool for discovery rather than a chore.

Perhaps the greatest benefit of using tech to teach fractions is the ability to manipulate the "whole." In a digital space, the "whole" isn't just a circle on a page; it’s a dynamic entity. Students can use "Slicers" in Tableau to filter data, watching how the fraction of "red cars" changes when they look at the whole parking lot versus just the SUVs. This teaches proportional reasoning, a critical skill for higher-level algebra and statistics.

By the time these students enter the workforce, they won't be drawing circles on paper to explain proportions; they’ll be using dashboards. By teaching fractions through data visualization, we aren't just hitting math standards—we are building the digital literacy required for the modern world. We are moving math away from "finding the answer" and toward "telling a story."

Let me know what you think, I'd love to hear. Come back Wednesday for a sample 30 minute lesson using google sheets.

Note: Tableau is a paid data package that allows a 30 day trial without a credit card.

Friday, January 23, 2026

Scripting the Struggle: How to Design a "Thinking Out Loud" Protocol for Any Math Topic

If you’ve decided to embrace metacognitive modeling, you might find that "thinking out loud" is harder than it looks. When you’ve mastered a mathematical concept, your brain performs the steps so fast that you often skip the very hurdles your students are tripping over. To effectively model the "messy middle," you need more than just a lesson plan; you need a.

A TOL script isn’t a word-for-word speech. Instead, it’s a mental map that forces you to narrate your choices, your doubts, and your corrections. Here is how to build one for any topic, from simple addition to complex calculus.

Step one is to identify the places students will have issues. This means you need to solve the problem yourself and pay attention to where a student is likely to fail. Is it a sign change? Is it the order of operations? Is it the vocabulary in the word problem? In your script, these potholes become your "Pause Points." Instead of gliding over them, you will intentionally slow down and narrate your decision-making process at these exact moments.

Step 2 is to use the "Three-Voice" Framework.A great TOL script uses three distinct "voices" to show the different layers of mathematical thinking:

The Strategist (The "Why"): Explains the choice of method.
- Scripting Tip: Use phrases like, "I see a squared term here, so my brain is reaching for the Quadratic Formula tool."
The Executor (The "How"): Narrates the actual calculation.
- Scripting Tip: Use phrases like, "I'm moving the constant to the other side of the equals sign, so I need to use the inverse operation."
The Critic (The "Wait, What?"): This is the most important voice. It questions the work and looks for errors.
- Scripting Tip: Use phrases like, "Wait, that number looks way too small for an area. Let me double-check my multiplication."

Step 3 is to script the "U-Turn" at the appropriate spot. To truly reduce math anxiety, your script must include an intentional "wrong turn." Choose a common misconception and narrate yourself falling into it—then, model how to get out.

Example Script for a Negative Sign Error:

"Okay, I'm distributing the $-3$ into the parentheses. So, $-3$ times $x$ is $-3x$ , and $-3$ times $5$ is... $15$ . [Pause]Wait, let me look at that again. I’m multiplying a negative by a positive. My 'Critic' voice is telling me that should be a negative. If I hadn't caught that, the whole problem would have crumbled. Let me fix that to $-15$ before I move on."

Step for is to include the final sanity check. Conclude your script by modeling how to verify an answer without looking at the back of the book. Narrate the process of estimation or plugging the answer back into the original equation. This teaches students that "finishing" isn't the final step—"verifying" is.

Script Component	Purpose	Example Phrase
The Hook	Connect to prior knowledge	"This looks like the problems we did yesterday, but with a twist..."
The Pivot	Change strategy when stuck	"That approach is getting messy. Let me try a different path."
The Reflection	Summarize the logic	"The big takeaway here wasn't the number 42; it was how we isolated $y$ ."

When you use a TOL script, you stop being a "deliverer of truth" and start being a "co-navigator." You show students that the goal of math isn't to be a calculator; it's to be a logical architect. By scripting your struggle, you give them a blueprint for their own. Let me know what you think, I'd love to hear. Have a great day.

Wednesday, January 21, 2026

Metacognitive Modeling: The Power of Thinking Out Loud (and Making Mistakes)

For years, the image of the "perfect" math teacher was someone who glided through equations with effortless precision. We stood at the whiteboard, chalk or stylus in hand, producing flawless solutions that seemed to appear by magic. But for a student struggling with math anxiety, this display of perfection doesn’t inspire—it intimidates. It creates the illusion that "math people" simply know the answer, leaving the student to feel that their own struggle is a sign of personal failure.

In 2026, the most effective math educators are intentionally shattering this glass ceiling through Metacognitive Modeling. This isn't just about showing the steps; it’s about narrating the "messy middle" of the thinking process—including the wrong turns.

Metacognition is "thinking about thinking." In a math context, modeling this means the teacher narrates their internal monologue while solving a problem. Instead of saying, "Next, we divide by 2," the teacher says, "I'm looking at this $2x$ and I want to isolate the $x$ . My brain is telling me to subtract 2, but wait—that’s not right, because the 2 is multiplied. I need to do the inverse operation. Let me try dividing instead."

By "thinking out loud," you pull back the curtain on the logical "debugging" that happens inside an expert’s mind.

One of the most powerful tools in a teacher's arsenal is the intentional, narrated error. When a teacher makes a mistake, catches it, and "debugs" it in real-time, three things happen. First it normalized struggle. Students see that mistakes are a natural part of the mathematical process, not a dead end. This directly lowers cortisol levels and reduces math anxiety.

Second, students learn how to check their own work. They hear the specific questions an expert asks themselves: "Does this answer make sense in the context of the problem?" or "Did I carry the negative sign?"

Finally, there is a subtle shift in classroom power dynamics. Students become "detectives" looking for the teacher's slip-ups, which keeps them hyper-focused on the logic of the problem.

So how do you implement this shift in your classroom. Moving from "Direct Instruction" to "Metacognitive Modeling" requires a shift in how you prepare your lessons. Begin by talking about the why inanition to the what. Instead of stating a formula, explain why your brain chose that specific tool from your "mathematical toolbox." Rather than being correct all the time, pretend to hit a wall occasionally. Say, "I’ve reached a point where my numbers are getting way too large. This usually means I missed a simplification step earlier. Let’s go back and look."

Always use thinking prompts such as:

- "My first instinct was to..., but then I realized..."
- "I'm feeling a little confused by this wording, so I'm going to draw a picture to see if that helps."
- "I'm checking my estimate—105 seems too high for this, where did I go wrong?"

Remember math anxiety often stems from a fear of the "unknown" and a pressure for speed. Metacognitive modeling slows down the pace. It proves that math is a deliberate, reflective act rather than a race to a result. When students hear their teacher struggle and succeed, they gain the "cognitive permission" to do the same.

In 2026, we are teaching students that being good at math isn't about never getting stuck—it's about knowing exactly what to do when you are. Let me know what you think, I'd love to hear. Have a great day.

Monday, January 19, 2026

AI as the "Tutor, Not the Answer Key": The Shift from Shortcuts to Scaffolding

For years, the math teacher’s greatest classroom adversary was the "photo-solver" app. Students could snap a picture of an equation and instantly receive the final answer, bypassing the struggle that actually leads to learning. In 2026, however, the narrative has shifted. Instead of banning artificial intelligence, savvy educators are transforming it into a sophisticated Socratic tutor.

The goal? Moving AI from being an "answer key" to a "scaffold." When used correctly, generative AI doesn't just give students the what; it guides them through the how and the why.

The reason many teachers are wary of AI is that, by default, chatbots like to be helpful—and in AI terms, "helpful" usually means giving the answer as fast as possible. To use AI as a tutor, we have to change its "personality" through precise prompt engineering.

Imagine giving your students a prompt template to paste before they ask for help:

"You are a patient Socratic math tutor. I am working on [topic]. I will provide a problem, and I want you to give me a small hint to help me take the next step. Do NOT give me the final answer. If I get stuck, ask me a guiding question instead of showing the work."

By setting these "guardrails," the AI stops being a shortcut and starts acting as a digital coach that mirrors the way a teacher circulates the room.

There are three ways to use AI for "Intelligent Hints. First one is to set up an "Identify the Error" challenge. Instead of having the AI solve a problem, have it generate three different "solved" versions of a complex equation—two of which contain a common student mistake. Ask the students to use the AI to explain why the error occurred. This moves the student from a passive consumer to an active critic.

Next is the progressive hint system where teachers can use AI to generate "Tiered Hint Cards." For a difficult word problem, the AI can create:

Hint 1: A conceptual clue (e.g., "Think about whether this problem is asking for a total or a part").
Hint 2: A formulaic clue (e.g., "The Pythagorean theorem might be useful here").
Hint 3: A visual setup (e.g., "Try drawing a right triangle and labeling the legs $a$ and $b$ ").

Finally is the rubber ducking partner. In programming, "rubber ducking" is explaining your code out loud to find bugs. Students can use AI as their "duck." They explain their step-by-step logic to the AI, and the AI is prompted to only respond with: "I follow your logic up to step two, but can you explain how you moved from $2x = 10$ to $x = 2$ ?"

Comparison: Answer Key vs. AI Tutor

Feature	AI as Answer Key	AI as Socratic Tutor
Student Output	Copy-pasting	Critical thinking & explaining
Cognitive Load	Near zero	High (Active processing)
Feedback Loop	Result-oriented	Process-oriented
Long-term Retention	Minimal	High (Neural connections formed)

The most "intelligent" part of this beauty? It frees the teacher. While the AI handles the routine "How do I start this?" questions, you are free to engage in high-level discussions, facilitate group work, and provide emotional support to students who are truly frustrated. In 2026, AI isn't replacing the teacher; it’s providing every student with a personal tutor so the teacher can focus on being a mentor. Let me know wha you think, I'd love to hear. Have a great day.

Wednesday, January 14, 2026

A 15-Minute Small Group Intervention Template

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In Algebra 1, integer errors are often the "silent killers" of student success. A student might understand the complex logic of a multi-step equation, but if they think $-5 - 8 = -3$ , the entire problem collapses. When your Diagnostic Checklist reveals a cluster of students struggling with these foundations, it’s time for a surgical strike: the Small Group Intervention.

This 15-minute template is designed to move students from confusion to "Aha!" by focusing on conceptual visualization rather than just memorizing "rules" that they often scramble.

📋 The "Integer Power Hour" (15-Minute Session)

Phase	Time	Activity
1. The Visual Hook	3 Mins	Use Positive/Negative Counters or a Number Line to model one "addition" and one "subtraction" problem.
2. Guided Discourse	5 Mins	The "Think-Aloud": Students explain where they are moving on the number line and why.
3. The "Conflict" Zone	5 Mins	Tackle the "Double Negative" specifically: $x - (-y)$ .
4. Quick Check	2 Mins	Three rapid-fire problems on a mini-whiteboard to check for immediate mastery.

🛠️ Step-by-Step Strategy

Step 1: The "Battle" Model (Concrete)

For students who struggle with abstract rules, use the Counter Method.

Positive counters are "heroes," and negative counters are "villains."
When they meet, they "cancel each other out" (Zero Pairs).
The Task: "Model $-5 + 3$ . Who wins the battle? By how many?"

Step 2: The Vertical Number Line (Pictorial)

Traditional horizontal number lines can be confusing (left/right vs. less/more). A vertical number line (like a thermometer) is often more intuitive.

Up is adding; Down is subtracting.
The Task: "Start at $-2$ . If you subtract $6$ , are you getting colder (down) or warmer (up)?"

Step 3: Explaining the "Double Negative"

This is the most common error in Algebra. Use the "Opposition" logic:

"If subtraction means 'move down,' then subtracting a negative must mean 'do the opposite of moving down.' So, we move up."

📝 The Mini-Intervention Script

Teacher: "Let's look at $-4 - (-6)$ . Most people want to make this $-10$ or $-2$ . Let's use our 'Opposite' rule. If I'm at $-4$ and I'm told to subtract, I usually go down. But I'm subtracting a 'negative.' What is the opposite of down?" Student: "Up?"Teacher: "Exactly. So, $-4 - (-6)$ becomes $-4 + 6$ . Start at $-4$ on your vertical line and move up $6$ spaces. Where do you land?"

✅ Success Criteria (The Exit Ticket)

Before the group returns to the main activity, they must solve these three problems correctly on their mini-whiteboards:

$-9 + 4$
$-3 - 7$
$5 - (-2)$

Why This Works

Small group intervention works because it lowers the affective filter. Students who are too intimidated to admit they don't know "middle school math" in front of the whole class feel safe to ask "Wait, why?" in a group of three. By focusing on the visual "why" instead of "Keep-Change-Change," you are building a mental map that sticks.

This concludes spiral reviews from how to create them, to a sample, to creating a diagnostic sheet, to small group intervention. Coming next, we'll look at how to create a diagnostic sheet for any activity in Math and how to create the small group interventions. Let me know what you think, I'd love to hear. Have a great day.

Monday, January 12, 2026

The Week 1 Diagnostic: Turning "Circulating" into "Data Collecting"

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The first week of Algebra 1 is often a whirlwind of syllabus reviews and icebreakers. However, for a math teacher, the most valuable moments happen during those 5–8 minutes of Spiral Review. As you walk among the desks (or boards), you aren't just checking for "right or wrong"; you are performing a clinical diagnosis of your students' mathematical foundations.

To make this process effective, you need a system. A Diagnostic Checklist allows you to move past the vague feeling of "the class is struggling with negatives" to the specific data point: "60% of Period 3 forgets to distribute the negative sign."

📋 The Algebra 1 Week 1 Diagnostic Checklist

Use this checklist as you circulate. Instead of marking names, many teachers use tally marks or a simple code ( $M$ for Mastery, $P$ for Partial, $B$ for Barrier) to identify trends across the whole class.

1. Integer Fluency (The "Engine")

[ ] The Subtraction Trap: Can the student solve $-8 - 5$ without getting $-3$ ?
[ ] Double Negatives: Do they recognize that $-(-x)$ becomes $+x$ ?
[ ] Sign Consistency: In multiplication, do they correctly identify that a negative times a negative is a positive?
[ ] Zero Concept: Do they understand that $-5 + 5 = 0$ ?

2. Operational Hierarchy (Order of Operations)

[ ] Left-to-Right Rule: Do they handle multiplication and division as they appear from left to right, or do they always do multiplication first? (e.g., $12 \div 3 \times 2$ )
[ ] Parentheses as Groups: Do they recognize that $2(5+3)$ requires the addition inside first, or do they try to subtract the $2$ from a previous term?
[ ] Exponents vs. Multiplication: Do they understand that $4^2$ is $16$ and not $8$ ?

3. Algebraic Literacy (Variables & Expressions)

[ ] "Invisible" Coefficients: Do they recognize that $x$ is the same as $1x$ ?
[ ] Like Term Discrimination: Can they see that $4x$ and $4x^2$ are "different animals" and cannot be added together?
[ ] Substitution Logic: When $x = -2$ , do they correctly calculate $x^2$ as $4$ (positive)?

4. Equation Foundations

[ ] Inverse Operation Choice: If they see $x + 5$ , do they automatically know to subtract $5$ ?
[ ] Equality Maintenance: Do they perform the operation on both sides of the equal sign?
[ ] Reciprocal Awareness: If they see $\frac{x}{3} = 5$ , do they know to multiply by $3$ ?

🛠️ How to Use This Data in Real-Time

Once you have your tallies, don't wait for the unit test to address the gaps. Use these "On-the-Fly" adjustments:

The "Two-Minute Warning": If you see 10 students making the same mistake on $-8 - 5$ , stop the class. Put that one problem on the board, discuss the number line movement, and then let them get back to work.
Targeted Small Groups: Use your checklist to pull 3–4 students to a small table for a "flash" intervention on a specific skill (like the Distributive Property) while the rest of the class moves to the next task.
Adjust the Next Day's Spiral: If the checklist shows that "Order of Operations" was a disaster, make all fiveproblems on tomorrow's spiral review focus on different versions of that one skill.

📊 Why a Checklist Matters

By Friday, you will have a clear map of your classroom's "minefields." This data is far more useful than a quiz grade because it tells you exactly why a student is failing to solve an equation. Is it the Algebra logic, or is it the $7th$ grade integer rules? With your diagnostic in hand, you finally have the answer. Let me know what you think, I'd love to hear. Have a great day.

Friday, January 9, 2026

A Sample Week 1 Algebra 1 Spiral Review

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To help you get started on creating good spiral reviews, I've made a sample template for the first week of Algebra I. Remember, the first week of Algebra 1 is about more than just finding $x$ ; it’s about diagnosing what survived the "summer slide" and rebuilding the foundational confidence students need for higher-level abstraction. By implementing a Spiral Review on day one, you establish a routine that says: "We don't just learn this for the test; we learn this for life."

Following the "Rule of Five" (5 problems, 5-8 minutes), here is a sample template for your first week of Algebra 1. This sequence focuses on Pre-Algebra essentials: integer fluency, order of operations, and basic expression manipulation.

📅 The Week 1 Daily Template

Monday: The Integer Reset

Focus: Addition/Subtraction of signed numbers.

$-8 + 15$
$-12 - (-5)$
$3(4 - 7)$
Translate to an expression: "Five less than a number $n$ ."
Quick Challenge: Is $-4^2$ the same as $(-4)^2$ ? Explain.

Tuesday: Order of Operations & Mult/Div

Focus: Handling negatives in multiplication and the hierarchy of operations.

$-6 \times (-9)$
$24 \div (-3) \times 2$ (Watch for the left-to-right trap!)
$10 - 2(5 + 3)$
Combine Like Terms: $4x + 7 - x + 2$
Evaluate $3x + 5$ when $x = -2$ .

Wednesday: The Distributive Shift

Focus: Removing parentheses and managing the negative sign outside a group.

$-15 \div (-5) + (-2)$
Simplify: $3(x + 4)$
Simplify: $-2(x - 5)$
Solve the one-step equation: $x - (-8) = 15$
If $a = 3$ and $b = -4$ , find $a - b$ .

Thursday: Two-Step Foundations

Focus: Bridging the gap between expressions and equations.

$\frac{-20}{4} - 6$
Simplify: $5(2x - 1) + 3x$
Solve: $2x + 5 = 13$
Write an equation: "Double a number $y$ is 20."
What is the reciprocal of $- \frac{2}{3}$ ?

Friday: The "Mix-It-Up" Review

Focus: Interleaving the week's skills to check for retention.

$-7 + (-3) - (-10)$
Simplify: $-(4x - 9)$
Evaluate $x^2 - 5$ when $x = -3$ .
Solve: $\frac{x}{3} = -4$
The Thinking Task: Pick any number. Multiply it by 2, add 10, divide by 2, and subtract your original number. What is the result? Does it always work?

💡 Implementation Best Practices

The "No-Calculator" Zone: For this specific Week 1 review, encourage students to work without calculators. This allows you to see if their struggle is with the Algebraic concept or simple Integer fluency.
Vertical Non-Permanent Surfaces (VNPS): As we discussed in the "Building Thinking Classrooms" post, try having students do these five problems standing at the boards in their random groups on a Wednesday or Friday to keep the energy high.
The Power of the Pen: Have students use a specific color (like red or green) to make corrections. This makes it easy for you to circulate and see common "hot spots" (like subtracting a negative) that might need a 2-minute mini-lesson.

📊 Why This Works

By the time you reach Friday, a student has practiced integer operations five days in a row. They aren't just "remembering" the rules; they are developing automaticity. This frees up their cognitive "RAM" to handle the harder concepts you'll introduce in Week 2, like multi-step equations and literal equations. Let me know what you think, I'd love to hear. Have a great day.