Chapter DWhen computers seePage 8 of 8

When computers see

Ship and explain the 3×3 plus-sign image classifier

Page 8 advances one concrete 3×3 plus-sign image classifier: explain the decision, run the code, inspect failure, measure evidence, and keep only what is ready to ship.

~14 minMastery and shipping

Before you start

Why this matters

Without running code, predict the output of this page's example and name the intermediate value that would prove your prediction. Then write one sentence answering: “What could look successful while actually being wrong?” For this stage, focus on fragile pixel classifier. Keep the prediction nearby; comparing it with the real output is the first debugging exercise, not a quiz about syntax.

1Learn the idea

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Build focus

The final artifact is a Python classifier with shape validation, an abstain-friendly confidence margin, and a compact robustness report. A reviewer should be able to reproduce the demo from one command, see the expected result, run the tests, and find the known limitations. Shipping does not mean claiming the toy solves every version of the problem. It means the intended case is measurable, failures are legible, and the previous working artifact remains recoverable.

The artifact's user-facing goal is specific: classify a tiny pixel grid as plus or other while keeping the pixels, score, threshold, and prediction visible. Its accepted input is exactly three rows of three binary brightness values. Those statements are intentionally narrower than “build an AI system.” Narrow scope lets us inspect every input and expected result, and it prevents a toy result from being presented as a production claim. This final smoke check summarizes the evidence you will present during the two-minute demo.

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Run the example

Save this as lesson.py and run python3 lesson.py. It uses only the language standard library, so the example is reproducible offline.

report={'clean_accuracy':1.0,'flip_accuracy':0.89,'threshold':4,'limitations':['rotation','larger images']}
assert report['clean_accuracy']>=.9
print(report)

Expected output: clean and pixel-flip accuracy plus limitations. Exact floating-point formatting may vary slightly, but the asserted behavior must not. Read the output as evidence about this stage, not merely proof that the interpreter started.

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Debug the stage

Print the 3×3 grid, flattened indices, five selected pixels, score, threshold, and label. If a rotated or shifted plus fails, that is an invariance limitation rather than a Python bug. Enumerate all nine single-pixel flips instead of trying one convenient corruption. Shape and binary-value errors should stop before scoring so malformed images cannot masquerade as confident predictions.

At the mastery and shipping stage, save the smallest failing fixture beside the expected result. Change one cause at a time and rerun the exact command printed above; that makes the repair reviewable and keeps this chapter's progressive artifact reproducible.

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Evaluate before continuing

Use named positive and negative grids to compute confusion counts, then report every single-pixel-flip result. Accuracy alone hides whether the toy misses pluses or calls unrelated lines pluses, so include recall and false-positive count. Keep the threshold in the report and test a rotated plus separately. This evaluates a handcrafted detector, not a camera-ready vision model.

For this mastery and shipping page, preserve the fixture and result as evidence for the next page. Label observations separately from conclusions: a passing assertion establishes the behavior it names, while broader usefulness requires the chapter's full evaluation set and stated operating limits.

Checking tutor…

Continue learning · glossary & guides
  • [ ] Can a second person run the demo without coaching?
  • [ ] Are expected output, evaluation evidence, and limitations visible?
  • [ ] Has the failure and recovery path been rehearsed?
  • [ ] Can I identify exactly which pixels contribute to the plus score?

Glossary: computer vision · Glossary: convolutional neural network

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