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WIP: Add new course material on CAN (Convertisseur Analogique Numérique) with definitions, sampling, and conversion examples
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---
title: Le CAN
subject: Cours
Add PDF export functionality and integrate courstex submodule
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export:
- format: pdf
template: courstex
WIP: Add new course material on CAN (Convertisseur Analogique Numérique) with definitions, sampling, and conversion examples
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kernelspec:
name: python3
display_name: Python 3
abbreviations:
CAN: Convertisseur Analogique Numérique
---
# Définition
:::{prf:definition} CAN
:nonumber: true
Un convertisseur analogique-numérique est un dispositif électronique dont la fonction est de traduire une grandeur analogique en une valeur numérique codée sur plusieurs bits. Le signal converti est généralement une tension électrique.
Source : Article _[Convertisseur analogique-numérique](http://fr.wikipedia.org/wiki/Convertisseur_analogique-num%C3%A9rique)_ de [Wikipédia en français](https://fr.wikipedia.org/) ([auteurs](http://fr.wikipedia.org/w/index.php?title=Convertisseur_analogique-num%C3%A9rique&action=history))
:::
# L'échantillonage du signal
L'échantillonage du signal est la prise d'une valeur à un intervalle régulier de temps. L'intervalle entre deux valeurs s'appelle **période d'échantillonage**. On la note $T_e$ (en secondes). On parle aussi de **fréquence d'échantillonage** $f_e=\frac{1}{T_e}$ (en Hertz), qui correspond au nombre de valeurs prises chaque seconde.
Le **quantum** correspond au plus petit écart quantifiable (la "hauteur d'une marche"). On le note $q$ et son unité est celle du signal d'entrée (généralement le Volt).
La **tension de pleine échelle** ou **tension de référence** est la tension maximale quantifiable par le CAN. On la note $V_\text{pe}$ ou $V_\text{ref}$.
Le nombre de valeurs que peut générer le convertisseur se note $N$ et dépend du nombre de bits $n$ du convertisseur. Ainsi : $N=2^n$.
On obtient la relation suivante : $q=\frac{V_\text{pe}}{N}=\frac{V_\text{pe}}{2^n}$.
# Exemple de conversion
On donne en @fig:exemple-can l'exemple d'un CAN de tension de référence 5 V fonctionnant sur 3 bits avec une fréquence d'échantillonage de 2 Hz.
La **caractéristique** du CAN est la courbe représentant la valeur numérique en sortie en fonction de la valeur analogique en entrée (@fig:carac-can).
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::::{figure}
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:label: fig:exemple-can
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:::{code-cell} python
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:tags: [remove-input]
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import matplotlib.pyplot as plt
from matplotlib import ticker
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import numpy as np
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from scipy.interpolate import CubicSpline
from scipy.stats import qmc
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rng = np.random.default_rng(50)
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n = 20
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t_max = 8
n_interp = t_max * 100 + 1
t_base = np.linspace(0, t_max, n)
lhs = (qmc.LatinHypercube(d=n-2, rng=rng).random(1)[0] - .5) * t_max/n
t = t_base + np.concatenate(([0], lhs, [0]))
t = t_base
s = 5 * rng.random(n)
t_interp = np.linspace(0, t_max, n_interp)
s_interp = np.clip(CubicSpline(t, s)(t_interp), 0, 5)
s_n = np.full_like(t_interp[::50], np.nan)
s_n = np.floor(s_interp[::50] * 8 / 5)
s_n[s_n == 8] = 7
fig, ax = plt.subplots()
ax2 = ax.twinx()
ax.plot(t_interp, s_interp, lw=3)
ax2.scatter(t_interp[::50], s_n, color="C1")
ax.grid(False, axis="y")
ax.grid(True, axis="x", which="both")
ax2.grid(True)
ax.set(
xlim=(0, t_max),
ylim=(-.5, 5.5),
xlabel="Temps (s)",
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)
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ax.set_ylabel("Signal analogique (V)", color="C0")
ax2.set(
ylim=(-8/5*.5, 8/5*5.5),
WIP: Add new course material on CAN (Convertisseur Analogique Numérique) with definitions, sampling, and conversion examples
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)
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ax2.set_ylabel("Signal numérique", color="C1")
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ax.yaxis.set_major_locator(ticker.MultipleLocator(1))
ax.xaxis.set_major_locator(ticker.MultipleLocator(1))
ax.xaxis.set_minor_locator(ticker.MultipleLocator(.5))
ax2.set_yticks(np.arange(9), np.concatenate((np.arange(8), [""])))
WIP: Add new course material on CAN (Convertisseur Analogique Numérique) with definitions, sampling, and conversion examples
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Refactor signal visualizations to use Matplotlib, removing Altair dependencies and updating figure configurations for clarity
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arr = ax2.annotate("", xy=(0, 0), xytext=(0.5, 0), arrowprops=dict(arrowstyle="<->"))
ax2.annotate("$T_e$", (0.5, 1), xycoords=arr, ha="center", va="bottom")
WIP: Add new course material on CAN (Convertisseur Analogique Numérique) with definitions, sampling, and conversion examples
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Refactor signal visualizations to use Matplotlib, removing Altair dependencies and updating figure configurations for clarity
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arr2 = ax2.annotate("", xy=(0.5, 0), xytext=(0.5, 1), arrowprops=dict(arrowstyle="<->"))
ax2.annotate("$q$", (1, 0.5), xycoords=arr2, ha="left", va="center")
WIP: Add new course material on CAN (Convertisseur Analogique Numérique) with definitions, sampling, and conversion examples
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arr3 = ax2.annotate("", xy=(1, 0), xytext=(1, 8), arrowprops=dict(arrowstyle="<->"))
Refactor figures in documentation to use consistent syntax and improve layout; update myst.yml to remove obsolete output settings.
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ax2.annotate("$V_{pe}$", (1, 0.5), xycoords=arr3, ha="left", va="center");
:::
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Signal analogique et signal numérisé.
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::::
WIP: Add new course material on CAN (Convertisseur Analogique Numérique) with definitions, sampling, and conversion examples
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Refactor figures in documentation to use consistent syntax and improve layout; update myst.yml to remove obsolete output settings.
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::::{figure}
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:label: fig:carac-can
Refactor figures in documentation to use consistent syntax and improve layout; update myst.yml to remove obsolete output settings.
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:::{code-cell} python
WIP: Add new course material on CAN (Convertisseur Analogique Numérique) with definitions, sampling, and conversion examples
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:tags: [remove-input]
Refactor signal visualizations to use Matplotlib, removing Altair dependencies and updating figure configurations for clarity
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import matplotlib.pyplot as plt
from matplotlib import ticker
WIP: Add new course material on CAN (Convertisseur Analogique Numérique) with definitions, sampling, and conversion examples
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import numpy as np
N = 8
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s_n = np.arange(N)
s_a = np.linspace(0, 5, N+1)
fig, ax = plt.subplots()
ax.stairs(s_n, s_a, color="C1", lw=3, baseline=None)
ax.set(
yticks=s_n,
xlabel="Signal analogique (V)",
ylabel="Signal numérique",
WIP: Add new course material on CAN (Convertisseur Analogique Numérique) with definitions, sampling, and conversion examples
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)
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ax.set_xticks(s_a, [f"{v:.3f}" for v in s_a], rotation=45, ha="right", rotation_mode="anchor")
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ax.set_aspect(5/8, "datalim")
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arr4 = ax.annotate(
"", xy=(s_a[0], 0), xytext=(s_a[1], 0), arrowprops=dict(arrowstyle="<->")
)
ax.annotate("$q$", (0.5, 1), xycoords=arr4, ha="center", va="bottom")
WIP: Add new course material on CAN (Convertisseur Analogique Numérique) with definitions, sampling, and conversion examples
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Refactor signal visualizations to use Matplotlib, removing Altair dependencies and updating figure configurations for clarity
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arr5 = ax.annotate(
"", xy=(s_a[0], 1.5), xytext=(s_a[-1], 1.5), arrowprops=dict(arrowstyle="<->")
)
Refactor figures in documentation to use consistent syntax and improve layout; update myst.yml to remove obsolete output settings.
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ax.annotate("$V_{pe}$", (0.5, 1), xycoords=arr5, ha="center", va="bottom");
:::
WIP: Add new course material on CAN (Convertisseur Analogique Numérique) with definitions, sampling, and conversion examples
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Caractéristique du CAN.
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::::
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