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\chapter{Communication Protocol} \label{sec:tinyframe} |
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GEX can be controlled through a hardware UART, the USB or over a wireless link. To minimize the firmware complexity, all the three connection methods are handled by the same protocol stack and are interchangeable. |
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The communication is organized in transactions. A transaction consists of one or more messages going in either direction. Messages can be stand-alone, or chained with a response or a follow-up message using the transaction ID. Both peers, GEX and the client application running on the PC, are equal in the communication: either side can independently initiate a transaction at any time. |
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GEX uses a framing library \textit{TinyFrame}, developed likewise by the author, but kept as a separate project for easier re-use in different applications. The library implements frame building and parsing, checksum calculation and a system of message listeners. An interested reader may find more technical details and the API in its documentation. |
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\section{Frame Structure} |
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Message frames have the following structure: |
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\begin{table}[h] |
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\centering |
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%\hspace{-1.5em} |
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\begin{tabular}{rccccccc} |
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\toprule |
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\multicolumn{1}{c|}{} & |
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\multicolumn{5}{c}{Header}& |
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\multicolumn{2}{|c}{Body} \\ |
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\midrule |
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% |
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\textit{Field} & |
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\textbf{SOF} & |
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\textbf{Frame ID} & |
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\makecell{ \Gape{\textbf{Payload}} \\ \Gape{\textbf{Length}} } & |
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\makecell{ \textbf{Frame} \\ \textbf{type} } & |
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\makecell{ \textbf{Header} \\ \textbf{checksum} } & |
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\textbf{Payload} & |
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\makecell{ \textbf{Payload} \\ \textbf{checksum} } \\ |
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% |
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\midrule |
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\textit{Bytes} & |
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1 & |
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2 & |
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2 & |
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1 & |
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1 & |
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... & |
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1 \\ |
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% |
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\bottomrule |
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\end{tabular} |
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\end{table} |
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The field widths shown here are those used in GEX; TinyFrame is flexible and the data type of all fields can be customized, as well as the checksum type. The SOF byte is always 0x01. |
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\textit{Frame ID}, which could be better described as \textit{Transaction ID}, uniquely identifies each transaction. The most significant bit is set to a different value in each peer to avoid ID conflicts, and the rest of the ID field is incremented with each initiated transaction. |
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\section{Message Listeners} |
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After sending a message that should receive a response, the peer registers an \textit{ID listener} with the ID of the sent message. A response reuses the original frame ID and when it is received, this listener is called to process it. ID listeners can also be used to receive multi-part messages re-using the original ID. |
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\textit{Frame type} describes the payload and does not have any prescribed format; the values are defined by application (here, GEX). A \textit{type listener} may be registered to handle all incoming messages with a given frame type. It works in a similar way to an ID listener and has a lower priority. |
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Each message can be handled by only one listener, unless it explicitly requests the message to be passed on to a lower priority one. Messages unhandled by any listener are given to a default listener, which can e.g. write an error to a debug log. |
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\section{Designated Frame Types in GEX} |
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The following table lists all frame types used by GEX. It is divided into four logical sections: General, Bulk Read/Write, Unit Access, and Settings. |
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\begin{table*}[h] |
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\centering |
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\begin{tabular}{clll} |
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\toprule |
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\textbf{Frame type} & \textbf{Function} & \textbf{Note} \\ |
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\midrule |
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0x00 & Success & \textit{Payload depends on context} \\ |
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0x01 & Ping & \textit{GEX responds with Success and its version string} \\ |
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0x02 & Error & \textit{Payload contains the error message} \\ |
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\midrule |
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0x03 & Bulk Read Offer & \textit{An offer of data to read using }0x04 \\ |
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0x04 & Bulk Read Poll & \textit{Requesting to read a block of data} \\ |
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0x05 & Bulk Write Offer & \textit{An offer to receive a bulk write transaction} \\ |
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0x06 & Bulk Data & \textit{Used for both reading and writing} \\ |
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0x07 & Bulk End & \textit{Marks the last "Bulk Data" frame} \\ |
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0x08 & Bulk Abort & \textit{} \\ |
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\midrule |
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0x10 & Unit Request & \textit{Request from PC to a unit} \\ |
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0x11 & Unit Report & \textit{Spontaneous event generated by a unit} \\ |
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\midrule |
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0x20 & List Units & \textit{Read a list of all instantiated units} \\ |
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0x21 & INI Read & \textit{Request a bulk read transaction of an INI file} \\ |
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0x22 & INI Write & \textit{Request a bulk write transaction of an INI file} \\ |
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0x23 & Persist Config & \textit{Write updated configuration to Flash} \\ |
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\bottomrule |
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\end{tabular} |
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\end{table*} |
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\section{Bulk Read and Write Transactions} |
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The bulk read and write transactions are generic, multi-message exchanges which are used to transfer the INI configuration files. They could possibly be used by some future unit requiring to transfer a large amount of data (e.g. to read image data from a camera). |
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The reason for splitting a long file into multiple messages, rather than sending it all in one, lies in the hardware limitations of the platform, specifically its small amount of RAM (the STM32F072 has only 16\,kB). A message cannot be processed until its payload checksum is received and verified; however, the configuration file can have several kilobytes, owning to the numerous explanatory comments, which would require a prohibitively large buffer. Further, the GEX module may need some time to process a part of the message before it can receive more data, which is easily achieved by this multi-part transport where each chunk must be confirmed before proceeding to the next. |
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A read or write transaction can be aborted by a frame 0x08 (Bulk Abort) at any time, though aborting a write transaction may leave the configuration in a corrupt state. As hinted in the introduction of this chapter, a transaction is defined by sharing a common frame ID. Thus, all frames in a bulk transaction must have the same ID, otherwise the ID listeners won't be called and the transaction will fail. |
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\subsection{Bulk Read} |
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To read an INI file, we first send a frame 0x21 (INI Read), specifying the target file in the payload: |
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\begin{minted}{c} |
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struct Payload_INI_Read { |
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uint8_t filenum; // 0 - UNITS.INI, 1 - SYSTEM.INI |
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}; |
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\end{minted} |
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What follows is a standard bulk read transaction with the requested file. |
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GEX offers the file for reading with a frame 0x03 (Bulk Read Offer): |
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\begin{minted}{c} |
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struct Payload_BulkReadOffer { |
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uint32_t total_length; // full size of the file in bytes |
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uint32_t max_chunk_size; // largest chunk that can be read at once |
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}; |
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\end{minted} |
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Now we can proceed to read the file using 0x04 (Bulk Read Poll), which is always responded to with 0x06 (Bulk Data), or 0x07 (Bulk End) if this was the last frame. Data frames have only the useful data as their payload. |
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The 0x04 (Bulk Read Poll) payload specifies how many bytes we want to read: |
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\begin{minted}{c} |
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struct Payload_BulkReadPoll { |
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uint32_t max_chunk_size; // how many bytes to read |
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}; |
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\end{minted} |
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\subsection{Bulk Write} |
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To overwrite an INI file, we first send a frame 0x22 (INI Write), specifying its size in the payload. Which file is written is detected automatically from the first INI section. |
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\begin{minted}{c} |
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struct Payload_INI_Write { |
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uint32_t total_length; // file size in bytes |
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}; |
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\end{minted} |
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The write request is confirmed by a frame 0x05 (Bulk Write Offer): |
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\begin{minted}{c} |
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struct Payload_BulkWriteOffer { |
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uint32_t total_length; // the expected file size in bytes |
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uint32_t max_chunk_size; // largest chunk that can be written at once |
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}; |
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\end{minted} |
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We can now send the file as a series of frames 0x06 (Bulk Data), or 0x07 (Bulk End) in the last frame. Each written chunk is confirmed by 0x00 (Success). |
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\subsection{Persisting the Changed Configuration to Flash} |
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The written INI file is immediately parsed and the settings are applied. However, those changes are not persistent: they exist only in RAM and will be lost when the module restarts. To save the current state to Flash, issue a frame 0x23 (Persist Config). This has the same effect as pressing the LOCK button (or replacing the LOCK jumper) when the INI files are edited using the virtual mass storage. |
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It should be noted that after flashing a firmware, the Flash control registers may remain in an unexpected state and the module must first be manually restarted before attempting to persist settings. Otherwise an assertion will fail and the module is restarted by a watchdog, losing the temporary changes. |
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% TODO there must be a workaround, and then this paragraph can be removed. |
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\section{Reading a List of Units} |
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The frame 0x20 (List Units) requests a list of all available units in the GEX module. The list includes all units' callsigns, names and types. The response payload has the following format (in pseudocode, as it can't be expressed as a C struct like the previous examples): |
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\begin{minted}{c} |
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struct { |
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uint8_t count; |
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for all units { |
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uint8_t callsign; |
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cstring unit_name; // 0-terminated char array |
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cstring driver_name; |
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} |
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} |
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\end{minted} |
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\section{Unit Requests and Reports} |
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Frame types 0x10 (Unit Request) and 0x11 (Unit Report) are dedicated to messages sent to and by unit instances. Each has a fixed header (\textit{inside the payload}) followed by unit-specific data. |
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\subsection{Unit Requests} |
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Unit requests deliver a message from the host to a unit instance. Unit drivers implements different commands, each with its own payload structure. The frame 0x10 (Unit Request) has the following structure: |
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\begin{minted}{c} |
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struct Payload_UnitRequest { |
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uint8_t callsign; |
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uint8_t command; // handled by the unit driver |
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uint8_t payload[]; // size and content depend on the command |
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}; |
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\end{minted} |
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The most significant bit of the command byte (0x80) has a special meaning: when set, the message delivering routine responds with 0x00 (Success) after the command completes, unless an error occurred. That is used to get a confirmation that the message was delivered and the module operates correctly (as opposed to e.g. a lock-up resulting in a watchdog reset). Requests which normally generate a response (e.g. reading a value from the unit) should not be sent with this bit set. As a result of this special treatment of the highest bit, there can be only 127 different commands per unit. |
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\subsection{Unit Reports} |
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Several unit types can produce asynchronous events, such as reporting a pin change or a triggering condition. The event is timestamped and sent with a frame type 0x11 (Unit Report): |
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\begin{minted}{c} |
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struct Payload_UnitRequest { |
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uint8_t callsign; |
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uint8_t report_type; // defines the payload structure |
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uint64_t timestamp; // microseconds since power-on |
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uint8_t payload[]; // size and content depend on the report type |
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}; |
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\end{minted} |
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\chapter{Wireless Interface} |
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Four methods of a wireless connection have been considered: bluetooth (e.g. CC2541), WiFi with ESP8266, LoRA or GFSK with SX1276, and a 2.4\,GHz radio link with NRF24L01+. Bluetooth was dismissed early for its complexity and ESP8266 for its high consumption in continuous reception mode, although both solutions might be viable for certain applications and with more time for evaluation. The SX1276 and NRF24L01+ have both been tested using the first GEX prototype, confirming its usefulness as a hardware development tool. |
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\section{Comparing SX1276 vs. NRF24L01+} |
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