X-Git-Url: https://git.martlubbers.net/?a=blobdiff_plain;f=appx%2Fmtask_aux.tex;h=28532c2acd6b0243ba989e87c4de162e1027daa9;hb=529531e1028ae26ab889456d65958794154d5b25;hp=220053ae38823473947ab203ee788a09106e9a0d;hpb=382f9709a872c0dfdb86e1184d07224a47c8eff3;p=phd-thesis.git

diff --git a/appx/mtask_aux.tex b/appx/mtask_aux.tex
index 220053a..28532c2 100644
--- a/appx/mtask_aux.tex
+++ b/appx/mtask_aux.tex
@@ -11,7 +11,7 @@
 \section{Peripherals}\label{sec:aux_peripherals}
 This section shows the peripherals not mentioned in \cref{chp:top4iot}.
 All constructors use \gls{HOAS} to create a type safe sensor object from a connection specification that can be used to interact with the sensor.
-The measurement tasks all yield unstable values contaning the measured value.
+The measurement tasks all yield unstable values containing the measured value.
 The auxiliary functions such as calibration yield stable values indicating the result.
 Tasks suffixed with the backtick (\cleaninline{'}) indicate variants for which the timing interval can be specified (see \cref{chp:green_computing_mtask}).
 
@@ -35,7 +35,7 @@ class AirQualitySensor v where
 
 \subsection{Gesture sensor}
 The \gls{MTASK} language supports one type (\emph{PAJ7620} connected via \gls{I2C}) of gesture sensors.
-The \emph{PAJ7620} contains an optical CMOS array that measures the reflection of the on-board \gls{IR} \gls{LED} to detect up to several different gestures.
+The \emph{PAJ7620} contains an optical CMOS array that measures the reflection of the on-board \gls{IR} \gls{LED} to detect up to several gestures.
 The complete interface containing the constructor and the measurement task is shown in \cref{lst:mtask_gesture}.
 
 \begin{lstClean}[label={lst:mtask_gesture},caption={Gesture sensor interface in \gls{MTASK}.}]
@@ -64,7 +64,7 @@ class LightSensor v where
 
 \subsection{Motion detection sensor}
 The \gls{MTASK} language supports motion sensing using a \gls{PIR} sensor through a type class that only contains macros.
-\gls{PIR} sensors detect motion by the \gls{IR} reflection through a number of fresnel lenses and communicates through a digital \gls{GPIO} pin.
+\gls{PIR} sensors detect motion by the \gls{IR} reflection through a number of Fresnel lenses and communicates through a digital \gls{GPIO} pin.
 Therefore, a \gls{PIR} is nothing more than a \cleaninline{DPIN} according to \gls{MTASK} but for uniformity, a type class is available (see \cref{lst:mtask_pir}).
 
 \begin{lstClean}[label={lst:mtask_pir},caption={\Gls{PIR} sensor interface in \gls{MTASK}.}]
@@ -97,7 +97,7 @@ where
 \end{lstClean}
 
 \subsection{\IIC{} buttons}
-The \gls{MTASK} language supports one type of \gls{I2C} buttons (the \gls{I2C} buttons from the \gls{WEMOS} d1 mini \gls{OLED} shield).
+The \gls{MTASK} language supports one type of \gls{I2C} buttons (the \gls{I2C} buttons from the \gls{WEMOS} D1 mini \gls{OLED} shield).
 The buttons from this shield provide more information than just the status (see \cleaninline{ButtonStatus}).
 The complete interface containing the constructor and the measurement tasks is shown in \cref{lst:mtask_i2cbutton}.
 
@@ -116,7 +116,7 @@ class i2cbutton v where
 \end{lstClean}
 
 \subsection{LED matrix}
-The \gls{MTASK} language supports one type of \gls{LED} matrix (the $8\times8$ \gls{LED} matrix shield for the \gls{WEMOS} d1 mini).
+The \gls{MTASK} language supports one type of \gls{LED} matrix (the $8\times8$ \gls{LED} matrix shield for the \gls{WEMOS} D1 mini).
 Instead of containing a \gls{TOP}-like interface, the \gls{ARDUINO} interface is directly translated to \gls{MTASK}.
 As a result, every task immediately returns a stable value indicating the result.
 The complete interface containing the constructor and the interaction tasks is shown in \cref{lst:mtask_ledmatrix}.