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Merge pull request zcash#782 from TomTaehoonKim/fix/typo
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Fix typo
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str4d authored Jun 27, 2023
2 parents eec65ea + 1f6aaae commit c05547a
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2 changes: 1 addition & 1 deletion book/src/background/polynomials.md
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Expand Up @@ -242,7 +242,7 @@ Now, we can write our polynomial as a linear combination of Lagrange basis funct

$$A(X) = \sum_{i = 0}^{n-1} a_i\mathcal{L_i}(X), X \in \mathcal{H},$$

which is equivalent to saying that $p(X)$ evaluates to $a_0$ at $\omega^0$,
which is equivalent to saying that $A(X)$ evaluates to $a_0$ at $\omega^0$,
to $a_1$ at $\omega^1$, to $a_2$ at $\omega^2, \cdots,$ and so on.

When working over a multiplicative subgroup, the Lagrange basis function has a convenient
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2 changes: 1 addition & 1 deletion book/src/design/proving-system/circuit-commitments.md
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Expand Up @@ -59,7 +59,7 @@ arguments are independent.)

Let $c$ be the number of columns that are enabled for equality constraints.

Let $m$ be the maximum number of columns that can accommodated by a
Let $m$ be the maximum number of columns that can be accommodated by a
[column set](permutation.md#spanning-a-large-number-of-columns) without exceeding
the PLONK configuration's maximum constraint degree.

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2 changes: 1 addition & 1 deletion book/src/design/proving-system/vanishing.md
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Expand Up @@ -55,7 +55,7 @@ $$\mathbf{H} = [\text{Commit}(h_0(X)), \text{Commit}(h_1(X)), \dots, \text{Commi

## Evaluating the polynomials

At this point, all properties of the circuit have been committed to. The verifier now
At this point, we have committed to all properties of the circuit. The verifier now
wants to see if the prover committed to the correct $h(X)$ polynomial. The verifier
samples $x$, and the prover produces the purported evaluations of the various polynomials
at $x$, for all the relative offsets used in the circuit, as well as $h(X)$.
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