\documentclass{beamer} % % Choose how your presentation looks. % % For more themes, color themes and font themes, see: % http://deic.uab.es/~iblanes/beamer_gallery/index_by_theme.html % \mode { \usetheme{Singapore} % or try Darmstadt, Madrid, Warsaw, ... \usecolortheme[RGB={3,138,94}]{structure} \usefonttheme{structurebold} % or try serif, structurebold, ... \setbeamertemplate{navigation symbols}{} \setbeamertemplate{headline}{} %\setbeamertemplate{caption}[numbered] \setbeamertemplate{footline}[frame number] } \usepackage[english]{babel} \usepackage[utf8x]{inputenc} \usepackage{fancyvrb} \usepackage{tcolorbox,listings} \usepackage{textpos} \usepackage{setspace} % Default fixed font does not support bold face \DeclareFixedFont{\ttb}{T1}{txtt}{bx}{n}{7} % for bold \DeclareFixedFont{\ttm}{T1}{txtt}{m}{n}{7} % for normal % Custom colors \usepackage{color} \definecolor{deepblue}{rgb}{0,0,0.5} \definecolor{deepred}{rgb}{0.6,0,0} \definecolor{deepgreen}{rgb}{0,0.5,0} 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for the emulated \end{textblock*}} \usepackage{hyperref} \definecolor{darkgreen}{rgb}{0.0,0.5,0.0} \title[LoRa]{A Brief Introduction to \includegraphics[trim=0 4cm 0 0, scale=0.15]{images/lora.jpg}} \author{Simon Pirkelmann} \institute{\includegraphics[scale=0.5]{images/iR.pdf}} \date{December 2nd, 2019} \AfterPreamble{\hypersetup{ urlcolor=blue, }} \begin{document} \begin{frame} \titlepage \end{frame} % Uncomment these lines for an automatically generated outline. \begin{frame}{Outline} \tableofcontents \end{frame} \section{LoRa} \subsection{Motivation} \begin{frame}{Motivation} \begin{itemize} \item Example: monitor well-being of honey bees\\[0.5cm] \includegraphics[scale=0.10]{images/honeybee.png} \hspace{0.5cm} \includegraphics[scale=0.055]{images/weight.png} \includegraphics[scale=0.045]{images/temperature.jpg} \includegraphics[scale=0.60]{images/humidity.jpg}\\[0.3cm] \hspace{6cm} \includegraphics[scale=0.04]{images/distance.jpg} \hspace{0.5cm} \includegraphics[scale=0.15]{images/no-electricity.png} \\ \pause \begin{minipage}{0.40\textwidth} \vspace{-2cm} \item Requirements: \begin{itemize} \setlength{\itemsep}{0pt} \item Low data rate (a few bytes per day) \item Low power consumption \item Low cost \item Long range \end{itemize} \end{minipage} \pause \begin{minipage}{0.45\textwidth} \hspace{0.2cm} Options: \begin{itemize} \setlength{\itemsep}{0pt} \item Data line (e.g. ethernet) \item Wifi, Bluetooth \item Cellular \end{itemize} \end{minipage} \vspace{0.1cm} \pause \item Solution: LPWAN (\textbf{L}ow-\textbf{P}ower \textbf{W}ide-\textbf{A}rea \textbf{N}etwork) \begin{itemize} \item \textbf{LoRa}, \textbf{LoRaWAN}, \textbf{TheThingsNetwork} \item SigFox, NB-IoT, Weightless, ... \end{itemize} \end{itemize} \end{frame} \subsection{LoRa facts} \begin{frame}{LoRa Facts} \begin{reference}{0mm}{70mm} https://www.thethingsnetwork.org/docs/lorawan/ \end{reference} \begin{itemize} \item Developed by \textbf{Semtech} (originally by Cycleo)\\ \hspace{0.3 cm}\textbf{Note:} parts of the PHY layer are \textbf{proprietary}! \item Frequency: \textbf{868 MHz} \textbf{SRD} band (in the EU) \item \textbf{25 mW} transmission power \item Bandwidth: \textbf{125} to \textbf{500 kHz} \item Data rate between \textbf{250 Bit/sec} and 21 \textbf{kBit/sec} \\ \hspace{0.3 cm}\textbf{BUT}: not made for a lot of data \item Low cost: \textbf{$\sim $10 EUR} CAPEX (for nodes), almost no OPEX \item Low power: devices can last \textbf{years on battery} \item Long distance: up to \textbf{10 km} range \end{itemize} \only<2>{ \begin{textblock*}{100mm}(-5mm,-65mm) \textblockcolour{white} \begin{exampleblock}{LoRa distance record} \includegraphics[scale=0.3]{images/distance_record.png} \end{exampleblock} \end{textblock*} } \end{frame} \begin{frame}{LoRa facts} \begin{reference}{0mm}{75mm} https://www.thethingsnetwork.org/docs/lorawan/ \end{reference} LoRa is \textbf{NOT} for: \begin{itemize} \item Realtime data - only small packets, every couple of minutes \item Phone calls - you can do that with GPRS/3G/LTE \item Controlling lights in your house - check out ZigBee or BlueTooth \item Sending photos, watching Netflix - check out WiFi \end{itemize} Important: \includegraphics[trim=0cm 4cm 0 0cm, scale=0.11]{images/lora.jpg} $\leftrightarrow$ \includegraphics[trim=0cm 4cm 0 0cm,scale=0.15]{images/lorawan.jpg} $\leftrightarrow$ \includegraphics[trim=0cm 4cm 0 0cm,scale=0.06]{images/ttn.png}\\[0.3cm] \begin{itemize} \item \textbf{LoRa}: PHY layer $\Rightarrow$ modulation technique \item \textbf{LoRaWAN}: Network protocol \item \textbf{TheThingsNetwork (TTN)}: Network server, handles routing of data to the \textit{cloud} \end{itemize} \end{frame} \subsection{PHY layer: modulation and demodulation} \begin{frame}{Digital modulation} \begin{itemize} \item \textbf{A}mplitude \textbf{S}hift \textbf{K}eying (ASK) \end{itemize} \includegraphics[scale=0.35]{images/unmodulated.png} \includegraphics[scale=0.35]{images/amplitude_modulation.png} \end{frame} \begin{frame}{Digital modulation} \begin{reference}{0mm}{75mm} https://en.wikipedia.org/wiki/Chirp\_spread\_spectrum \end{reference} \begin{itemize} \item \textbf{F}requency \textbf{S}hift \textbf{K}eying (FSK) \end{itemize} \includegraphics[scale=0.35]{images/unmodulated.png} \includegraphics[scale=0.35]{images/frequency_modulation.png} \end{frame} \begin{frame}{Digital modulation} \begin{itemize} \item Used by LoRa: \textbf{C}hirp \textbf{S}pread \textbf{S}pectrum (CSS) modulation \begin{center} \includegraphics[scale=0.3]{images/chirp.png} \includegraphics[scale=0.3]{images/chirp_spectrogram.png} \end{center} \begin{itemize} \item Chirp = frequency change over time\\ \end{itemize} \end{itemize} \end{frame} \begin{frame}{LoRa modulation} \begin{itemize} \item LoRa uses \textbf{Up-Chirps} (frequency increases) and \textbf{Down-Chirps} (frequency decreases) \end{itemize} \includegraphics[scale=0.3]{images/lora_upchirp.png} \includegraphics[scale=0.3]{images/lora_downchirp.png} %\item Messages always start with 8 Up-Chirps \end{frame} \begin{frame}{Example LoRa packet} \begin{reference}{0mm}{70mm} Thanks Valentin and Stefan (DM4SG) for providing this data \end{reference} \begin{center} \includegraphics<1>[scale=0.2]{images/lora_signal.png} \includegraphics<2>[scale=0.2]{images/lora_signal_2.png} \includegraphics<3>[scale=0.2]{images/lora_signal_3.png} \end{center} \end{frame} \begin{frame}{Chirps and Symbols} \begin{overlayarea}{\textwidth}{\textheight} \begin{center} \includegraphics<1>[scale=0.4]{images/lora_symbols_0.png} \includegraphics<2>[scale=0.4]{images/lora_symbols_1.png} \includegraphics<3>[scale=0.4]{images/lora_symbols_2.png} \includegraphics<4>[scale=0.4]{images/lora_symbols_3.png} \includegraphics<5>[scale=0.4]{images/lora_symbols_4.png} \includegraphics<6>[scale=0.4]{images/lora_symbols_5.png} \end{center} \only<2->{ Time of frequency jump determines which data is encoded\\ } \begin{center} \only<3>{Example: \texttt{data = }\texttt{00000}} \only<4>{Example: \texttt{data = }\texttt{00010}} \only<5>{Example: \texttt{data = }\texttt{00011}} \only<6>{Example: \texttt{data = }\texttt{10110}} \end{center} \end{overlayarea} \end{frame} \begin{frame}{Spreading factor} \begin{itemize} \item Number of bits per symbol is determined by \textbf{spreading factor} (SF) \begin{center} \includegraphics<1>[scale=0.5]{images/lora_spreading_factors.png} \end{center} \item Possible values: SF7 - SF12\\ \hspace{0.5cm} SF7: 7 bits per symbol \\ \hspace{0.5cm} SF12: 12 bits per symbol \item Spreading factor influences max. range \end{itemize} \end{frame} \begin{frame}{Demodulation} \begin{itemize} \item Signal is multiplied by (mixed with) Down-Chirp \item Fourier Transform \end{itemize} \end{frame} \begin{frame}{Forward error coding} \begin{itemize} \item For each symbol several \textbf{parity bits} are added (= redundant information) \\ Reason: allows to detect and fix errors that occur during transmission (due to interference, etc.) \item \textbf{Coding rate} determines number of parity bits:\\ \hspace{0.25cm} CR 4/5 : of 5 bits transmitted, 4 bits are actual data\\ \hspace{1.5cm}$\vdots$\\ \hspace{0.25cm} CR 4/8 : of 8 bits transmitted, 4 bits are actual data \item Additionally: \textbf{C}yclical \textbf{R}edundancy \textbf{C}heck (CRC) \end{itemize} \end{frame} \begin{frame}{LoRa package format} \begin{reference}{0mm}{70mm} Source: SX1276/77/78/79 datasheet \end{reference} \includegraphics[scale=.3]{images/lora_packet_structure.png} \begin{itemize} \item Header: contains information about \begin{itemize} \item payload length \item coding rate \item CRC present? \end{itemize} \item Implicit header mode: no header sent \end{itemize} \end{frame} \begin{frame}{Data rate and air time} \begin{itemize} \item Data rate depends on bandwidth (BW), spreading factor (SF) and coding rate (CR)\\[0.3cm] \begin{minipage}{0.4\textwidth} \textbf{Symbol duration}: \begin{equation*} T_{sym} = \frac{2^{SF}}{BW} \end{equation*} \end{minipage} \begin{minipage}{0.5\textwidth} \textbf{Symbol rate}: \begin{equation*} R_{sym} = \frac{1}{T_{sym}} \end{equation*} \end{minipage} \item \textbf{Data rate}: \begin{equation*} R_{data} = \underbrace{SF}_{\# \text{bits per symbol}} \cdot \underbrace{R_{symb}}_{\text{symbol rate}} \cdot \underbrace{\frac{4}{4 + CR}}_{\text{coding rate}} \end{equation*} \item Example data rates:\\ \begin{tabular}{lll|lr} SF7 &BW250 &CR4/5 & $\approx 10.9$ &$\tfrac{kbit}{s}$ \\ \hline SF7 &BW125 &CR4/5 & $\approx 5.5$ &$\tfrac{kbit}{s}$ \\ \hline SF12 &BW125 &CR4/5 & $\approx 0.29$ & $\tfrac{kbit}{s}$ \end{tabular} %\item Sync word: \url{https://forum.chirpstack.io/t/relation-between-sync-word-private-network-and-end-nodes/191/17} \end{itemize} \end{frame} \begin{frame}{Time-On-Air} \begin{reference}{0mm}{65mm} According to \textit{Allgemeinzuteilung von Frequenzen zur Nutzung durch Funkanwendungen mit geringer Reichweite für nicht näher spezifizierte Anwendungen; Non-specific Short Range Devices (SRD)}, Bundesnetzagentur, 2018 \end{reference} \begin{itemize} \item Comply with \textbf{duty cycles} of the SRD band: \begin{tabular}{l|r|r} Frequency & Duty Cycle & ERP \\ \hline 868,0 - 868,6 MHz & 1 \% & 25 mW \end{tabular} \item This amounts to $\approx 30$ seconds of transmission time per hour (maximum!). Try to keep it way below. \item Airtime calculator: \url{https://www.loratools.nl/\#/airtime} \item Example: \texttt{20 bytes} payload \\ $\rightarrow$ max. 25 messages per hour on SF12 \\ $\rightarrow$ max. 600 messages per hour on SF7 \\ \end{itemize} \end{frame} \section{Playground Part I} \begin{frame}[fragile]{Playground Part I} \begin{itemize} \item Module used: \textbf{Wemos® TTGO LORA32 868Mhz ESP32} \begin{minipage}{0.6\textwidth} \begin{small} \begin{itemize} \item ESP32 \item LoRa Chip SX1276 \item OLED display \item Antenna (needs to be connected!) \end{itemize} \end{small} \end{minipage}% \begin{minipage}{0.4\textwidth} \includegraphics[scale=0.075]{images/ttgo_module.JPG} \end{minipage} \item Programmable in MicroPython thanks to \texttt{uPyLora} library by lemariva (\url{https://github.com/lemariva/uPyLora}) \begin{spacing}{0.52} \begin{python} from lora_transceiver import LoRaTransceiver from uPySensors.ssd1306_i2c import Display disp = Display() # create transceiver lora = LoRaTransceiver(display=disp) # send a string lora.send_string("hello world!") # send some raw binary data lora.send([0x01, 0x02, 0x03]) \end{python} \end{spacing} \item Have a look at SX1276 datasheet \end{itemize} \end{frame} \begin{frame}[fragile]{Playground Part I} \begin{itemize} \item Receiving data: \begin{spacing}{0.52} \begin{python} from lora_transceiver import LoRaTransceiver from uPySensors.ssd1306_i2c import Display disp = Display() # create transceiver lora = LoRaTransceiver(display=disp) # start receiving data (and output on the screen) lora.recv() \end{python} \end{spacing} \item Change LoRa parameters \begin{spacing}{0.52} \begin{python} # change the spreading factor lora.setSpreadingFactor(10) # change the frequency lora.setFrequency(868.1e6) # change signal bandwidth lora.setSignalBandwidth(250e3) # change sync word lora.setSyncWord(0x34) \end{python} \end{spacing} \item Task: \textit{Turn off your neighbors LED!} \end{itemize} \end{frame} \section{LoRaWAN or 'How to send data to the cloud'} \begin{frame}{Introduction} \begin{reference}{2mm}{70mm} https://www.thethingsnetwork.org/forum/t/limitations-data-rate-packet-size-30-seconds-uplink-and-10-messages-downlink-per-day-fair-access-policy-guidelines/1300 \end{reference} \textbf{Outline:} \begin{itemize} \item Extensions: LoRaWAN \begin{itemize} \item explain basic idea (getting your sensor data online) \item network topology \item protocol \item encryption \item Fair use policy \url{https://www.thethingsnetwork.org/forum/t/limitations-data-rate-packet-size-30-seconds-uplink-and-10-messages-downlink-per-day-fair-access-policy-guidelines/1300} \end{itemize} \item Practical part II: playing around with MicroPython LoRa modules, getting data into the cloud \end{itemize} \end{frame} \section{Practical Part II} \begin{frame}[fragile] \begin{itemize} \item Set device address, network and application key \item Encrypt data (done by uLoRaWAN) \item Encode data (as in Part I) \item Send data ... \end{itemize} On the receiver side: \begin{itemize} \item ... receive data \item Decrypt data (using keys) \item Decode data (as in Part I) \item Do something with the data \end{itemize} Best practices to reduce payload size: \url{https://www.thethingsnetwork.org/forum/t/best-practices-to-limit-application-payloads/1302}\\ Cayenne Low Power Payload (LPP) \end{frame} \end{document}