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rapport/introduction.tex

@@ -1,23 +1,12 @@
 % !TeX root = main.tex
 \chapter{Introduction}\label{cha:intro}
-
-Ta bort när klar
-
-\squareit{
-For a product to be put on the market there are many regulations which the product must follow, e.g. electrical safety, material regulations, documentation, quality systems, electromagnetic compatibility (EMC), radio regulations etc. To test products against these requirements in a unified manner, standards are used. A standard defines how a product should be tested and the accepted result that need to be achieved in order to ensure that the product complies with the regulations. There are many standards for many different types of regulations and usually a single product must comply with several of these. It is also common that one standard references another standard, or specific parts of another standard, instead of redefining some tests.
-
-% https://europa.eu/youreurope/business/product/product-rules-specifications/index_en.htm besökt 2019-06-19
-}
-
-The ISO 7637 standard, \emph{Road vehicles -- Electrical disturbances from conduction and coupling}, and ISO 16750, \emph{Road vehicles -- Environmental conditions and testing for electrical and electronic equipment}, are international standards that apply to products in road vehicles with a nominal supply voltage of 12 V or 24 V. The standards states, here put in a very condensed form, that the product shall withstand a sufficient amount of disturbances applied to its power supply. The reason for this is that there can be many voltage surges and much noise in a vehicle's power supply lines. In general, the source of disturbances and noise in a vehicle origins from inductance in other devices connected to the power line, the cables and the vehicles alternator in combination with switching of loads or the supply. \cite{iso7637-2, iso16750-2}
-
-\todo[Mention that the standard also addresses emission, but that the report only focuses on immunity]
+The ISO 7637 standard, \emph{Road vehicles -- Electrical disturbances from conduction and coupling}, and ISO 16750, \emph{Road vehicles -- Environmental conditions and testing for electrical and electronic equipment}, are international standards that apply to products in road vehicles with a nominal supply voltage of 12 V or 24 V. The standards states, here put in a very condensed form, that the product shall withstand a sufficient amount of disturbances applied to its power supply. The reason for this is that there can be many voltage surges and much noise in a vehicle's power supply lines. In general, the source of disturbances and noise in a vehicle origins from inductance in other devices connected to the power line, the cables and the vehicles alternator in combination with switching of loads or the supply. \cite{iso_7637_2, iso_16750_2}
 
 To test if a product comply with this standard, there is equipment which simulates different events on the power supply. The standard defines the different scenarios, raise and fall times of test pulses, repetition times etc. It also defines the functional requirements of the equipment during these tests for what is considered a passed or a failed test. \cite{iso7637-2, iso16750-2}
 
 \section{Motivation}
 
-The standard defines all the timing requirements that must be met, and also specifies the load conditions for which the requirements apply \cite{iso7637-2}. From time to time the standards are revised, which might alter the requirements form the previous versions of the standard. New equipment is guaranteed by its manufacturer to do the tests according to the latest standard, as long as it is regularly sent in for calibration and maintenance. New equipment costs a great amount of money and might not even be affordable by smaller test labs, and can thus inhibit labs from performing tests for this standard.
+The standard defines all the timing requirements that must be met, and also specifies the load conditions for which the requirements apply \cite{iso7637-2}. From time to time the standards are revised, which may alter the requirements form the previous versions of the standard. New equipment is guaranteed by its manufacturer to do the tests according to the latest standard, as long as all the maintenance instructions are followed which might include sending the equipment in for calibration and service. New equipment cost lots of money amount of money and might not even be affordable by smaller test labs, and can thus inhibit labs from performing tests for this standard.
 
 An appealing alternative would be the possibility to reuse the test equipment that was used along with the older revision of the standard, as long as it is capable of performing sufficient tests reliable. For this to be of any value the test equipment must be verified in some way to be able to guarantee that the tests are performed according to the new standard.
 
@@ -71,6 +60,8 @@ This paper only considers the following test equipment for the real implementati
     \end{tabularx}
 \end{table}
 
+\todo[Mention that the standard also addresses emission, but that the report only focuses on immunity]
+
 %The methods used might be applicable to other similar standards and equipment.
 
 \section{Report structure}

rapport/methods.tex

@@ -75,7 +75,7 @@ The advantage of this, on top of the advantages of alternative 2, is that there
 The disadvantage of this would be that the embedded attenuators might prove difficult to design. They need to be accurate up to high frequencies, be tolerable to high voltage, dissipate the power necessary and also be electrically safe.
 
 \section{Design of dummy loads}
-Each dummy load must withstand the applied test pulses, and preferably the worst possible test pulse for the specific dummy load even though it might not be intended. The dummy loads must have a tolerance of \SI{1}{\percent} or less and be non-inductive. \cite{iso-7637-2}
+Each dummy load must withstand the applied test pulses, and preferably the worst possible test pulse for the specific dummy load even though it might not be intended. The dummy loads must have a tolerance of \SI{1}{\percent} or less and be non-inductive. \cite{iso_7637_2}
 
 The dummy loads consists of one or more resistors. When determining whether the resistors withstands the test pulses, the parameters of interest are power dissipation, maximum voltage and maximum energy applied over time.
 
@@ -117,7 +117,7 @@ The voltages used in the calculations are specified in \autoref{tab:dummy_load_w
 \subsection{PCB}
 Since the dummy loads consists of many discrete resistors, it was decided to design a PCB to connect them. This also gives good mechanical control of the resistors and the possibility to design for good heat dissipation.
 
-Because of the high voltages present on the board it was decided to keep a minimum of 3mm functional isolation creepage distance between all traces on the board, in line with the EN 60664-1 standard \cite{en-60664-1}. The board was perforated to allow for better air flow past the resistors. The mounting holes for the card was placed in a \SI[product-units=single]{105 x 105}{\milli\meter} square, allowing for a \SI{120}{\milli\meter} fan to be mounted on top of the card using mounting hardware.
+Because of the high voltages present on the board it was decided to keep a minimum of 3mm functional isolation creepage distance between all traces on the board, in line with the EN 60664-1 standard \cite{en_60664_1}. The board was perforated to allow for better air flow past the resistors. The mounting holes for the card was placed in a \SI[product-units=single]{105 x 105}{\milli\meter} square, allowing for a \SI{120}{\milli\meter} fan to be mounted on top of the card using mounting hardware.
 
 A two layer board was chosen, and all of the traces were mirrored on both layers to get as much conductive cross sectional area as possible, and thus lowering the resistance and voltage drop in the traces. The PCB was ordered with \SI{60}{\micro\meter} thick copper layer to further extend the cross sectional areas. The width of the traces for the \SI{2}{\ohm} load was chosen as wide as possible, since the pulse currents are the highest for this one. \todo[kolla så detta är sant]
 

rapport/myrefs.bib

@@ -1,5 +1,5 @@
 
-@techreport{iso-7637-1,
+@techreport{iso_7637_1,
     author= {ISO} ,
     type = {Standard},
     key = {ISO 7637-1:2015},
@@ -10,7 +10,7 @@
     institution = {ISO/TC 22/SC 32}
 }
 
-@techreport{iso-7637-2,
+@techreport{iso_7637_2,
     author= {ISO} ,
     type = {Standard},
     key = {ISO 7637-2:2011},
@@ -21,7 +21,7 @@
     institution = {ISO/TC 22/SC 32}
 }
 
-@techreport{iso-7637-3,
+@techreport{iso_7637_3,
     author= {ISO} ,
     type = {Standard},
     key = {ISO 7637-3:2016},
@@ -32,7 +32,7 @@
     institution = {ISO/TC 22/SC 32}
 }
 
-@techreport{iso-7637-5,
+@techreport{iso_7637_5,
     author= {ISO} ,
     type = {Standard},
     key = {ISO 7637-5:2016},
@@ -43,7 +43,7 @@
     institution = {ISO/TC 22/SC 32}
 }
 
-@techreport{iso-16750-2,
+@techreport{iso_16750_2,
     author= {ISO} ,
     type = {Standard},
     key = {ISO 16750-2:2012},
@@ -54,7 +54,7 @@
     institution = {ISO/TC 22/SC 32}
 }
 
-@techreport{en-60664-1,
+@techreport{en_60664_1,
     author= {ISO} ,
     type = {Standard},
     key = {EN 16664-1:2007},

rapport/results.tex

@@ -68,7 +68,7 @@ The 3rd alternative was chosen because of the convenience of a fully automatic s
 \section{Design of dummy loads}
 
 \todo[flytta till resultat]
-The values measured are, presented in \autoref{tab:four-wire-result}, are well within the \SI{1}{\percent} specified by the standard \cite{iso-7637-2}.
+The values measured are, presented in \autoref{tab:four-wire-result}, are well within the \SI{1}{\percent} specified by the standard \cite{iso_7637_2}.
 
 \begin{table}[h]
 %\begin{adjustbox}{width=\columnwidth,center}

rapport/theory.tex

@@ -26,20 +26,20 @@ To get hold of a copy of a standard, one need to buy it from ISO or one of its r
 \textbf{The ISO~7637 standard}, \emph{Road vehicles — Electrical disturbances from
 conduction and coupling}, concerns the electrical environment in road vehicles. The standard consists of, at the time of writing, four parts.
 
-Part 1, \emph{Definitions and general considerations}, defines some abbreviations and technical terms that are used throughout the standard. It also describes the scope of where the standard is intended to be applied. \cite{iso-7637-1}
+Part 1, \emph{Definitions and general considerations}, defines some abbreviations and technical terms that are used throughout the standard. It also describes the scope of where the standard is intended to be applied. \cite{iso_7637_1}
 
-Part 2, \emph{Electrical transient conduction along supply lines only}, defines the test procedures related to disturbances that are carried along the supply lines of a product. Both emission, disturbances created by the DUT, and immunity, the DUT's capability to withstand disturbances, are covered. This part defines the test pulses, and the verification of the same, that are of interest to this project. \cite{iso-7637-2}
+Part 2, \emph{Electrical transient conduction along supply lines only}, defines the test procedures related to disturbances that are carried along the supply lines of a product. Both emission, disturbances created by the DUT, and immunity, the DUT's capability to withstand disturbances, are covered. This part defines the test pulses, and the verification of the same, that are of interest to this project. \cite{iso_7637_2}
 
-Part 3, \emph{Electrical transient transmission by capacitive and inductive coupling via lines other than supply lines}, defines immunity tests against disturbances on other interfaces that the power supply. It focuses on test setups and different ways of coupling the signals. \cite{iso-7637-3}
+Part 3, \emph{Electrical transient transmission by capacitive and inductive coupling via lines other than supply lines}, defines immunity tests against disturbances on other interfaces that the power supply. It focuses on test setups and different ways of coupling the signals. \cite{iso_7637_3}
 
-Part 5, \emph{Enhanced definitions and verification methods for harmonization of pulse generators according to ISO~7637}, proposes an alternative verification method of the test pulses defined in ISO~7637-2. The main difference from the method described in ISO~7637-2 is that $U_A$ should not only be 0~V during the verification, but also be set to $U_N$. This will not be considered deeply in this report, since it is only a proposal and makes the verification equipment more difficult. \cite{iso-7637-5}
+Part 5, \emph{Enhanced definitions and verification methods for harmonization of pulse generators according to ISO~7637}, proposes an alternative verification method of the test pulses defined in ISO~7637-2. The main difference from the method described in ISO~7637-2 is that $U_A$ should not only be 0~V during the verification, but also be set to $U_N$. This will not be considered deeply in this report, since it is only a proposal and makes the verification equipment more difficult. \cite{iso_7637_5}
 
 The ISO~16750, \emph{Road vehicles -- Environmental conditions and testing for electrical and electronic equipment}, concerns different environmental factors that a product might face in a vehicle, such as mechanical shocks, temperature changes and acids. Part 2, \emph{Electrical Loads}, of the standard deals with some electrical aspects that was previously part of the ISO~7637 standard. This is the only part of ISO~16750 that will be considered.
-\cite{iso-16750-1, iso-16750-2}
+\cite{iso-16750-1, iso_16750_2}
 
 \section{Test pulses}
 
-All test pulses defined in ISO~7637 and ISO~16750 are supposed to simulate events that can occur in a real vehicle's electrical environment, that products must be able to withstand. The properties of these test pulses are well defined, to allow for unified testing regardless of which test lab that performs the test. In the real world, however, the disturbances might of course differ from the test pulses since a real case environment is not controlled. \cite{iso-7637-2,iso-16750-2, comparison_iso_7637_real_world}
+All test pulses defined in ISO~7637 and ISO~16750 are supposed to simulate events that can occur in a real vehicle's electrical environment, that products must be able to withstand. The properties of these test pulses are well defined, to allow for unified testing regardless of which test lab that performs the test. In the real world, however, the disturbances might of course differ from the test pulses since a real case environment is not controlled. \cite{iso_7637_2,iso_16750_2, comparison_iso_7637_real_world}
 
 The test pulses of interest defined in ISO~7637 are denoted \emph{Test pulse 1}, \emph{Test pulse 2a}, \emph{Test pulse 3a} and \emph{Test pulse 3b}. The test pulse of interest defined in ISO~16750 is denoted \emph{Load dump Test A}. There are more pulses and tests defined in these standards, but those are not in the scope of this thesis.
 
@@ -62,7 +62,7 @@ This pulse simulates the event of a load, parallel to the DUT, is disconnected.
 \todo[Två bilder, en på kurvan och en på kretsen som orsakar den. En tabell med parametervärden.]
 
 \subsection{Test pulse 3a and 3b}
-Test pulse 3a and 3b simulates transients ``which occur as a result of the switching process'' as stated in \cite{iso-7637-2}. The formulation is not very clear, but is interperted and explained by Frazier and Alles \cite{comparison_iso_7637_real_world} to be the result of a mechanical switch brekaking an inductive load. These transients are very short, compared to the other pulses, and the repetition time is very short. The pulses are sent in bursts, grouping a number of pulses together and separating groups by a fixed time.
+Test pulse 3a and 3b simulates transients ``which occur as a result of the switching process'' as stated in \cite{iso_7637_2}. The formulation is not very clear, but is interperted and explained by Frazier and Alles \cite{comparison_iso_7637_real_world} to be the result of a mechanical switch brekaking an inductive load. These transients are very short, compared to the other pulses, and the repetition time is very short. The pulses are sent in bursts, grouping a number of pulses together and separating groups by a fixed time.
 
 These pulses contain high frequency components, up to 100~MHz, and special care must be taken when running tests with them as well as when verifying them.
 
@@ -82,7 +82,7 @@ During a test, the nominal voltage is first applied between the plus and minus t
 \todo[Snygg bild på uppkoppling och kopplingsnätverk.].
 
 \subsection{Mathematical description}
-All of the test pulses applied to the vehicle equipment can individually be described mathematically by variations of the double exponential function shown in \autoref{eq:doubleexp} and \autoref{fig:doubleexp}. The properties of interest, the ones which are specified in the standards, are the surge voltage $ U_s $, the rise time $ t_r $, the duration $ t_d $ and the repetition time $ t_1 $. \cite{iso-7637-2}
+All of the test pulses applied to the vehicle equipment can individually be described mathematically by variations of the double exponential function shown in \autoref{eq:doubleexp} and \autoref{fig:doubleexp}. The properties of interest, the ones which are specified in the standards, are the surge voltage $ U_s $, the rise time $ t_r $, the duration $ t_d $ and the repetition time $ t_1 $. \cite{iso_7637_2}
 
 How $k$, $\alpha$ and $beta$ are related to these properties will be described in more detail in \autoref{sec:double_exponential_function}.
 
@@ -106,11 +106,11 @@ How $k$, $\alpha$ and $beta$ are related to these properties will be described i
 \end{figure}
 
 \subsection{Verification}
-The test pulses are to be verified before they are applied to the DUT. The voltage levels and the timings are to be measured, with and without a matched load attached $R_L$ = $R_i$. The standard omits the rise time constraint when the load is attached, except for pulse 3a and 3b. \cite{iso-7637-2}
+The test pulses are to be verified before they are applied to the DUT. The voltage levels and the timings are to be measured, with and without a matched load attached $R_L$ = $R_i$. The standard omits the rise time constraint when the load is attached, except for pulse 3a and 3b. \cite{iso_7637_2}
 
-The verification is to be conducted with $U_A$ set to 0. There is, however, a proposal to set $U_A$ to the actual nominal voltage during the verification process, as the behaviour of the pulse generators has proven differ in this case \cite{iso-7637-5}. In this project $U_A = 0$ will be used.
+The verification is to be conducted with $U_A$ set to 0. There is, however, a proposal to set $U_A$ to the actual nominal voltage during the verification process, as the behaviour of the pulse generators has proven differ in this case \cite{iso_7637_5}. In this project $U_A = 0$ will be used.
 
-The limits, and tolerances, for the pulses are summarised in \autoref{tab:verification-list}. The matched loads are to be within 1\% of the nominal value. \cite{iso-7637-2}
+The limits, and tolerances, for the pulses are summarised in \autoref{tab:verification-list}. The matched loads are to be within 1\% of the nominal value. \cite{iso_7637_2}
 
 \begin{table}[h]
 \begin{adjustbox}{width=\columnwidth,center}