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| learn:instrumentation:tutorials:ad2-protocol-analyzer:start [2018/01/11 19:15] – James Colvin | learn:instrumentation:tutorials:ad2-protocol-analyzer:start [2021/06/02 23:45] (current) – Arthur Brown | ||
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| - | ====== Using the Protocol Analyzer ====== | + | ====== Using the Protocol Analyzer |
| - | When working on any digital logic project, communication between hardware, sensors, or main boards happens with various communication protocols. Logic analyzers can be useful when trying to discover if communication between components is working, but once you find out which component isn't working, a protocol analyzer is a must. | + | ~~REDIRECT> |
| - | + | ~~NOSEMANTIC~~ | |
| - | With a protocol analyzer, you can connect to a piece of hardware, power, and read or write to it. For example, if I have a SPI light sensor and I'm not receiving data, I can quickly check to see if the hardware is malfunctioning by connecting it and getting data. I can also quickly adjust settings to see if maybe the clock frequency or something else specified is incorrect. | + | {{tag>redirect}} |
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| - | The Analog Discovery 2 provides a pattern generator that can be used to test communication protocols. This is also true of the Digital Discovery, original Analog Discovery, and Electronics Explorer board. | + | |
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| - | We will go through the logic analyzer interface, how to use it, and an example. | + | |
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| - | ==== Inventory ==== | + | |
| - | * [[http:// | + | |
| - | * You may also use the Digital Disovery, [[http:// | + | |
| - | * [[http:// | + | |
| - | * A computer with USB port to run the software | + | |
| - | * [[http:// | + | |
| - | * A [[http:// | + | |
| - | * The [[http:// | + | |
| - | * This tutorial will demonstrate how to use the Protocol Analyzer with the Pmod ALS, which communicates via SPI. If you have another SPI sensor, the steps will be very similar. | + | |
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| - | ====== Step 1: The Protocol Analyzer ====== | + | |
| - | The first thing we'll do to familiarize ourselves with the protocol | + | |
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| - | On the left-hand side is a button for each of the tools. Clicking on the button labeled // | + | |
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| - | There are three main menus in the main window: //File//, // | + | |
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| - | The //File// menu allows you to open a specific configuration of the Protocol Analyzer, save the current configuration, | + | |
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| - | The //Control// menu allows you to run and stop the Protocol Analyzer. When you want to read or write a specific piece of data, you will need to make sure that the overall tool is running before you can read, write, or execute. | + | |
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| - | The //Window// menu allows you to change which WaveForms tab or window you have open. The Help tab contains information on all of the tools, menu options, and buttons. If you ever question how something works or functions, visit the Help tab. Below that, you will see whatever windows or tabs are currently open. | + | |
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| - | If you ever want to change a window to a tab, or tab to a window, you can click on the button displayed below. | + | |
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| - | The Protocol Analyzer currently supports three protocols: UART, SPI, and I2C. The settings and controls for these analyzers are located in the three tabs below the menu bar we just talked about. The first tab is the UART tab. | + | |
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| - | The //UART// tab allows you to send, receive, and save data over UART. | + | |
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| - | The first section on the UART tab which you can toggle open and closed is the settings section. | + | |
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| - | //TX// allows you to set which data line the data will be transmitted along. You can set this to any of the 16 digital I/O pins for the Analog Discovery and Digital Discovery. | + | |
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| - | //RX// allows you to set which data line the data will be received along. You can set this to any of the 16 digital I/O pins for the Analog Discovery and Digital Discovery, as well as any of the 24 High Speed Inputs on the Digital Discovery. | + | |
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| - | // | + | |
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| - | //Bits// selects the number of data bits and can be set to a value between 0 and 32 bits. | + | |
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| - | //Parity// allows you to select the parity mode. You can choose between odd, even, mark and high, and space or low parity modes. | + | |
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| - | //Stop// specifies the number of stop bits. You can choose a value between 0 and 3 bits. | + | |
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| - | //Rate// specifies the baud rate in bits per second. You can choose between 110 and 50,000,000 bits per second in standard baud rate values. | + | |
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| - | //Ending// selects how you'd like to end the line. You can choose between nothing, carriage return, line feed, RC LF, and LF CR. | + | |
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| - | In the //TX// section, you can type in the data you want to send and click send to transmit it over UART. If you check the auto box, the text is automatically sent. Alternatively, | + | |
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| - | In the //RX// section, you can receive and save data. If you have TX Echo checked, the data that you transmit will also be received. Received data is printed in blue, sent data is printed in green, and errors will be printed in red. If there are any unprintable characters, they will appear between braces. You can also save the data using the save or append buttons. The clear button will clear all data from the RX box. | + | |
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| - | The next tab is the //SPI// tab, which is set up similarly to the UART tab, bit with a few more options. For now, we'll continue with the walk around. In later steps, we'll demonstrate an example using the SPI tab. | + | |
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| - | At the top of the //SPI// tab is the // | + | |
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| - | The //Select// box allows you to enter which data line you are going to use as chip select. You can choose any pin that can be configured as an output. | + | |
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| - | The //Clock// box allows you to enter which data line you are going to use as the SPI clock. You can choose any pin that can be configured as an output. | + | |
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| - | The //Active// drop-down allows you to select how the chip select signal is active, choosing between active high or active low. | + | |
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| - | The // | + | |
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| - | The // | + | |
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| - | The //Phase// box allows you to set the phase of the signal as either 0 or 1. | + | |
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| - | The next four boxes, //DQ0//, //DQ1//, //DQ2//, and //DQ3// define the data lines. Depending on the mode that you use, these data boxes will hold different values. For example, DQ0 is used as MOSI if you are in write mode, DQ1 is MISO if you are reading. We'll get more into that later when I talk about mode. | + | |
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| - | The //First Bit// drop down selects the bit transmission order as Most or Least Significant word first. | + | |
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| - | The //First Word// drop down selects word transmission order as most or least significant word first. | + | |
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| - | The //gear// opens additional settings that allows you to set the initial drive of the signals. | + | |
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| - | The first way to use the SPI tab is with the //Simple// tab. This is the tab that will likely most commonly be used. | + | |
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| - | //Mode// allows you to select what type of SPI operation you are doing. You can do a Read Write to DQ0 and from DQ1, Read from DQ1 as MISO, Write to DQ1 as MOSI, Read0 from DQ0 in 3-wire SPI mode, dual Read, dual Write, quad read, or quad write. More information about the modes is available in the help tab from within WaveForms. | + | |
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| - | //Command Bits// defines how many command bits you want to send, allowing any value up to 32 bits. | + | |
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| - | //Command (DQ0)// is where you enter the command word to be sent tp DQ0 before the read or write operation. | + | |
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| - | //Word bits// specifies the word length, which will determine how the data is displayed. Any value up to 32 bits is allowed. | + | |
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| - | //Words// defines how many words the data will be comprised of, again affecting how the data is displayed. | + | |
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| - | //Write// specifies the words that are to be sent. You can input a value in binary, decimal or hexidecimal format, or import data using the open// button.// | + | |
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| - | //Read// shows the words being read. The data can be saved to a binary or text file using the //Save// or //Append// buttons. | + | |
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| - | The second way to use the SPI tab is to use the //Custo//m tab. This allows you to write custom scripts to combine operations into a custom SPI operation. | + | |
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| - | The following functions can be used in your custom SPI script: | + | |
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| - | * //Start()// activates the select signal. It will return true on success, otherwise will return false. | + | |
| - | * //Stop()// Deactivates the select signal. It will return true on success, otherwise will return false. | + | |
| - | * // | + | |
| - | * //Write( bits per work , { word1, word2... | [word1, word2...] } )// completes a 3 or 4-wire SPI data write. It returns true on success, otherwise returns false. | + | |
| - | * //Read( bits per work , number of words to read)// completes a 4-wire SPI data read. It returns the read array of words from DQ1. | + | |
| - | * //Read0( bits per work , number of words to read)// completes a 3-wire SPI data read. It returns the read array of words from DQ0. | + | |
| - | * // | + | |
| - | * //ReadDual( bits per work , number of words to read )// completes a dual SPI data read from DQ0,1. Returns the read array of words. | + | |
| - | * // | + | |
| - | * //ReadQuad( bits per work , number of words to read )// completes a dual SPI data read from DQ0,1,2,3. Returns the read array of words. | + | |
| - | * // | + | |
| - | * //DIO.// lets you set (the ones are not declared as SPI signal) and read the digital pins. | + | |
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| - | You can also access the SPI settings like: Select, Clock etc. | + | |
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| - | Several example scripts using Pmods are included in the Custom tab under // | + | |
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| - | The //Sensor// tab allows you to write custom communication scripts with precise timing using different functions than that of the custom tab. | + | |
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| - | The functions available are as follows: | + | |
| - | * // | + | |
| - | * //loop()// is called for specified number of Iterations and at specified Rate. It is useful to collect, decode and store sensor data. Use only static data transfer calls! | + | |
| - | * // | + | |
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| - | The sensor tab also provides several examples using Pmods and ICs under Example. | + | |
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| - | The final communication protocol that the Protocol Analyzer supports is I2C, which is available under the //I2C// tab. This tab is set up almost identical to the SPI tab. | + | |
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| - | At the top of the tab is the // | + | |
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| - | //SCL// allows you to select which pin you want to assign to the clock signal. | + | |
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| - | //SDA// allows you to select which pin you want to assign to the data signal. | + | |
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| - | The drop-down next to // | + | |
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| - | Below settings are the three tabs that allow different uses of the I2C Protocol Analyzer. | + | |
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| - | //Simple// is the first tab and allows you to complete basic communication with I2C. | + | |
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| - | //Address// allows you to specify the 7 bit I2C address. | + | |
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| - | // | + | |
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| - | Both //Bytes// specifies the number of data bytes to read or write. | + | |
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| - | The text box below //Write// allows you to specify the bytes to be written in binary decimal or hexadecimal format. You can also import data from a binary or text file using the //open// button. | + | |
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| - | //Write// executes the write function. | + | |
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| - | The text box below //Read// shows the read data bytes and can be saved to binary or text file using the //Save// or //Append// buttons. | + | |
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| - | //Read// executes the read function. | + | |
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| - | The //Custom// tab lets you write a custom communication script with the following functions: | + | |
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| - | * //Clear()// returns true when the bus is free. It will try to resolve SDA hold down issue. | + | |
| - | * //Read( address )// returns true when acknowledged otherwise false. | + | |
| - | * //Read( address, count of bytes )// returns the read bytes array from the specified address. | + | |
| - | * //Read( address, [sub address byte1, byte2...], count of bytes )// returns the read bytes array from the specified device address and subaddress using repeated start. | + | |
| - | * //Write( address )// returns true when acknowledged otherwise false. | + | |
| - | * //Write( address, [byte1, byte2... ] } )// returns zero on success or -1 on address NotAcKnowled or the NAK byte index. | + | |
| - | * //DIO//. lets you set (the ones are not declared as SPI signal) and read the digital pins. | + | |
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| - | You can access the I2C settings such as SCK, SDA, Frequency, etc. | + | |
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| - | Under //Example// you'll find several examples using Pmods and other ICs. | + | |
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| - | The //Sensor// tab allows you to write communications scripts to be executed at precise timing using the following functions: | + | |
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| - | * // | + | |
| - | * //loop()// is called for specified number of iterations and at specified Rate. It is useful to collect, decode and store sensor data. Use only static data transfer calls! | + | |
| - | * // | + | |
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| - | ---- | + | |
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| - | ====== Step 2: Select the Correct Settings for the Pmod ALS ====== | + | |
| - | Now it's time for an example. We'll be using the Pmod ALS to demonstrate the Protocol Analyzer reading data via SPI. | + | |
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| - | Open the Protocol Analyzer if it is not already open and enter the settings to match the image above. | + | |
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| - | //Select// should be set to DIO 0. | + | |
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| - | //Clock// should be set to DIO 2. | + | |
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| - | The clock frequency should be set to 2MHz. | + | |
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| - | //DQ1// should be set to DIO1. | + | |
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| - | //Mode// should be set to Read. | + | |
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| - | //Word bits// should be set to 11. | + | |
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| - | //Words// should be set to 1. | + | |
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| - | ====== Step 3: Connect the Pmod ALS to the Analog Discovery 2 ====== | + | |
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| - | Next, you'll need to connect the Pmod ALS to the Analog Discovery 2 or the Digital Discovery. | + | |
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| - | Connect the positive power supply to VCC, and set the power supply value to 3.3V. | + | |
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| - | Connect a ground wire to GND. | + | |
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| - | Connect DIO 0 to CS, DIO 1 to SDO, and DIO 2 to SCK. | + | |
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| - | ====== Step 4: Obtain Light Level Data ====== | + | |
| - | Back in WaveForms in the Protocol Analyzer, click Run in the Control menu and then click Execute. Each time you click Execute, you will receive a new data value. As you increase the light, you should see the values go up, and as you decrease the light, you should see the values go down to zero. | + | |
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| - | {{youtube> | + | |
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| - | {{tag>learn instrumentation tutorial analog-discovery-2 ad2 waveforms-2015 protocol-analyzer pmodals pmod-als digital-discovery electronics-explorer eeboard}} | + | |