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  The latest release of ThingWorx, version 9.7, brings powerful updates across performance, scalability, security, and developer productivity. Designed to meet the evolving demands of IoT and AR solutions, this version equips businesses with the tools to build smarter applications, improve operational efficiency, and stay ahead of the curve.   Performance & Scalability ThingWorx 9.7 introduces key updates that enhance performance and scalability for large-scale operations. The addition of partitioned value streams enables faster queries and purging of massive data sets, streamlining data management. Lazy loading for grid components optimizes application responsiveness, ensuring a seamless user experience, even in data-intensive environments. Additionally, the new Data Ordering feature ensures that ingested data is processed in the exact order it is received, even across asynchronous systems. This capability guarantees accurate execution of application logic and precise end calculations, addressing critical needs in industries requiring serialized data processing.   Reliability Enhancements Reliability is critical in enterprise applications, and ThingWorx 9.7 delivers with automated disaster recovery, providing quick failover mechanisms for deployments on the PTC Cloud. Enhanced diagnostics and tools for high-availability environments address challenges such as large cache collections, helping maintain stability and preventing bottlenecks in mission-critical systems.   Developer Productivity ThingWorx 9.7 offers developers a range of productivity-boosting features. The Mashup Builder enhancements include binding filtering, container zooming, and intuitive design tools that make application development faster and more efficient. Grid customizations, like inline editing and bulk selection, further streamline workflows. Developers also benefit from the latest Eclipse plugin, ensuring compatibility with modern tools and technologies.   Security & Compliance Security continues to be our highest priority in this release. ThingWorx 9.7 fully supports Java 21, delivering enhanced memory management and access to the latest security patches. TLS 1.3 Phase-2 integration brings advanced encryption protocols to secure communication across platforms. Additional security measures, such as granular file permissions, give administrators more control over sensitive data and operations.   Industry-Specific Solutions ThingWorx 9.7 introduces several innovative features tailored for specific industries: Route Versioning in Connected Work Cells: Manufacturers can now revise and track work cell routes with precision, creating complete traceability for serial numbers, routes, and associated work instructions. This feature streamlines workflows, enhances traceability, and boosts operational efficiency. Enhanced Operational Insights: The release includes new key performance indicators (KPIs) and reporting tools to deliver actionable insights at the factory line, site, and enterprise levels. These updates help organizations measure efficiency, reduce downtime, and improve overall productivity. Asset Muting for Chatty Devices: In scenarios where connected devices become overly chatty—sending excessive or unnecessary data—administrators can now mute these assets. This prevents data overload and mitigates risks such as distributed denial-of-service (DDoS) attacks, optimizing platform performance and ensuring uninterrupted operations. Improved Deployment Reliability: Enhancements in software content management ensure reliable and scalable management of large-scale deployments, reducing downtime and improving device performance.   Third-Party Library Upgrades ThingWorx 9.7 includes key updates to its underlying technology stack, ensuring compatibility with modern enterprise systems, improved performance, and robust security. To stay future-ready, we have updated its core technology stack, including Tomcat 9.0.95, Ignite 2.16 and RabbitMQ 3.13.7 to highlight few.   Why Upgrade to ThingWorx 9.7? ThingWorx 9.7 sets a new benchmark for IoT platforms, offering enhanced scalability, state-of-the-art security, and intuitive tools for developers. The updates cater to both enterprise-scale deployments and industry-specific challenges, ensuring that businesses can innovate and operate with confidence in an increasingly complex digital landscape.   Upgrade to ThingWorx 9.7 today and unlock new possibilities for innovation and success! View release notes here for more details on exact updates and be sure to upgrade to 9.7! Vineet Khokhar Principal Product Manager- IOT Security  
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Hello everyone,   Following a recent  experience, I felt it was important to share my insights with you. The core of this article is to demonstrate how you can format a Flux request in ThingWorx and post it to InfluxDB, with the aim of reporting the need for performance in calculations to InfluxDB. The following context is renewable energy. This article is not about Kepware neither about connecting to InfluxDB. As a prerequisite, you may like to read this article: Using Influx to store Value Stream properties from... - PTC Community     Introduction   The following InfluxDB usage has been developed for an electricity energy provider.   Technical Context Kepware is used as a source of data. A simulation for Wind assets based on excel file is configured, delivering data in realtime. SQL Database also gather the same data than the simulation in Kepware. It is used to load historical data into InfluxDB, addressing cases of temporary data loss. Once back online, SQL help to records the lost data in InfluxDB and computes the KPIs. InfluxDB is used to store data overtime as well as calculated KPIs. Invoicing third party system is simulated to get electricity price according time of the day.   Orchestration of InfluxDB operations with ThingWorx ThingWorx v9.4.4 Set the numeric property to log Maintain control over execution logic Format Flux request with dynamic inputs to send to Influx DB  InfluxDB Cloud v2 Store logged property Enable quick data read Execute calculation Note: Free InfluxDB version is slower in write and read, and only 30 days data retention max.     ThingWorx model and services   ThingWorx context Due to the fact relevant numeric properties are logged overtime, new KPIs are calculated based on the logged data. In the following example, each Wind asset triggered each minute a calculation to get the monetary gain based on current power produced and current electricity price. The request is formated in ThingWorx, pushed and executed in InfluxDB. Thus, ThingWorx server memory is not used for this calculation.   Services breakdown CalculateMonetaryKPIs Entry point service to calculate monetary KPIs. Use the two following services: Trigger the FormatFlux service then inject it in Post service. Inputs: No input Output: NOTHING FormatFlux _CalculateMonetaryKPI Format the request in Flux format for monetary KPI calculation. Respect the Flux synthax used by InfluxDB. Inputs: bucketName (STRING) thingName (STRING) Output: TEXT PostTextToInflux Generic service to post the request to InfluxDB, whatever the request is Inputs: FluxQuery (TEXT) influxToken (STRING) influxUrl (STRING) influxOrgName (STRING) influxBucket (STRING) thingName (STRING) Output: INFOTABLE   Highlights - CalculateMonetaryKPIs Find in attachments the full script in "CalculateMonetaryKPIs script.docx". Url, token, organization and bucket are configured in the Persitence Provider used by the ValueStream. We dynamically get it from the ValueStream attached to this thing. From here, we can reuse it to set the inputs of two other services using “MyConfig”.   Highlights - FormatFlux_CalculateMonetaryKPI Find in attachments the full script in "FormatFlux_CalculateMonetaryKPI script.docx". The major part of this script is a text, in Flux synthax, where we inject dynamic values. The service get the last values of ElectricityPrice, Power and Capacity to calculate ImmediateMonetaryGain, PotentialMaxMonetaryGain and PotentialMonetaryLoss.   Flux logic might not be easy for beginners, so let's break down the intermediate variables created on the fly in the Flux request. Let’s take the example of the existing data in the bucket (with only two minutes of values): _time _measurement _field _value 2024-07-03T14:00:00Z WindAsset1 ElectricityPrice 0.12 2024-07-03T14:00:00Z WindAsset1 Power 100 2024-07-03T14:00:00Z WindAsset1 Capacity 150 2024-07-03T15:00:00Z WindAsset1 ElectricityPrice 0.15 2024-07-03T15:00:00Z WindAsset1 Power 120 2024-07-03T15:00:00Z WindAsset1 Capacity 160   The request articulates with the following steps: Get source value Get last price, store it in priceData _time ElectricityPrice 2024-07-03T15:00:00Z 0,15 Get last power, store it in powerData _time Power 2024-07-03T15:00:00Z 120 Get last capacity, store it in capacityData _time Capacity 2024-07-03T15:00:00Z 160 Join the three tables *Data on the same time. Last values of price, power and capacity maybe not set at the same time, so final joinedData may be empty. _time ElectricityPrice Power Capacity 2024-07-03T14:00:00Z 0,15 120 160 Perform calculations gainData store the result: ElectricityPrice * Power _time _measurement _field _value 2024-07-03T15:00:00Z WindAsset1 ImmediateMonetaryGain 18 maxGainData store the result: ElectricityPrice * Capacity lossData store the result: ElectricityPrice * (Capacity – Power) Add the result to original bucket   Highlights - PostTextToInflux Find in attachments the full script in "PostTextToInflux script.docx". Pretty straightforward script, the idea is to have a generic script to post a request. The header is quite original with the vnd.flux content type Url needs to be formatted according InfluxDB API     Well done!   Thanks to these steps, calculated values are stored in InfluxDB. Other services can be created to retrieve relevant InfluxDB data and visualize it in a mashup.     Last comment It was the first time I was in touch with Flux script, so I wasn't comfortable, and I am still far to be proficient. After spending more than a week browsing through InfluxDB documentation and running multiple tests, I achieved limited success but nothing substantial for a final outcome. As a last resort, I turned to ChatGPT. Through a few interactions, I quickly obtained convincing results. Within a day, I had a satisfactory outcome, which I fine-tuned for relevant use.   Here is two examples of two consecutive ChatGPT prompts and answers. It might need to be fine-tuned after first answer.   Right after, I asked to convert it to a ThingWorx script format:   In this last picture, the script won’t work. The fluxQuery is not well formatted for TWX. Please, refer to the provided script "FormatFlux_CalculateMonetaryKPI script.docx" to see how to format the Flux query and insert variables inside. Despite mistakes, ChatGPT still mainly provides relevant code structure for beginners in Flux and is an undeniable boost for writing code.  
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  Guidelines for selecting the optimal method for connecting to ThingWorx   GUIDE CONCEPT   In the world of IoT application development, connectivity refers to the infrastructure and protocols which connect devices to the cloud or network. Edge devices handle the interface between the physical world and the cloud.   ThingWorx provides you with several different tools for connecting to the Thingworx platform.   This guide is designed as an introduction to these tools, and will help you determine which to choose based on your specific requirements.   YOU'LL LEARN HOW TO   Pros and cons of different connection methods The connection method best suited for some typical applications Where to find detailed information about any connection method   NOTE: This guide's content aligns with ThingWorx 9.3. The estimated time to complete this guide is 30 minutes   Step 1: Connectivity Method Options   There are many factors that will influence your decision about the ideal mechanism to connect to ThingWorx. On this page we compare and contrast different methods and give examples for where each one is a natural fit.   Connectivity Method Developer Benefit REST API Integrate seamlessly using dynamically-generated API calls Azure IoT Hub Connector Connect devices that use Azure IoT Hub Edge SDKs Build full-featured integrations for any platform ThingWorx Kepware Server Connect out-of-the-box with over 150 protocol drivers for industrial equipment Edge MicroServer Establish bi-directional connectivity with this complete, ready-to-run agent   REST API   Pros Cons Typical use case Skills Required Connection Type  Web developer can easily create integration ThingWorx cannot trigger action on the edge Push data from small devices to ThingWorx REST API development Request/Response   Using the ThingWorx REST API is an easy way for low-capability devices to connect with a ThingWorx platform. Any edge device that can make an HTTP POST can read and update properties or execute services on a ThingWorx platform. The disadvantage of this method is that it is one way from edge to platform. There is no way for the platform to initiate a service on the remote device and properties are only updated when the edge device initiates a connection with ThingWorx.   Learn more about the ThingWorx REST API:   Use REST API to Access ThingWorx Using the Connect an Arduino Developer Board tutorial REST API Documentation   Azure IoT Hub Connector   Pros Cons Typical use Case Skills Required Connection Type  Easily connect devices that use Azure IoT Hub Adds dependency and cost to application Add ThingWorx for devices connected with the Azure cloud Azure edge development AlwaysOn™   The diagram illustrates device-to-cloud integration with the Azure IoT Hub.   The ThingWorx Azure IoT Hub Connector establishes network connections to both ThingWorx Foundation and the Azure IoT Hub. Data flows in from devices, through the Azure IoT Hub hosted in the cloud, to the ThingWorx Azure IoT Hub Connector configured for a specific ThingWorx instance. The ThingWorx Azure IoT Hub Connector translates messages from the Azure IoT Hub format, to the native ThingWorx format and uses an established AlwaysOn connection to forward the information to ThingWorx Foundation.   Azure IoT Hub   Connect Azure IoT Devices   Edge SDKs   Pros Cons Typical Use case Skill Required Connection Type  Fully integrate device or remote system with ThingWorx platform Most developer flexibility All functionality must be developed by programmer Full customization or tight integration required Application development in Java, C, or .Net AlwaysOn™   These SDKs are developer tools that wrap the protocol used to connect to the ThingWorx Platform. There are SDK's available for Java, C, and .Net languages. The Edge MicroServer uses the C SDK internally. All SDKs use the ThingWorx AlwaysOn binary protocol together with the HTTP WebSocket protocol for transport. WebSocket connections can operate through a firewall allowing two-way, low latency communication between the device and server. The SDKs support the following key concepts that allow a Thing developed with an SDK to be a full-fledged entity in the ThingWorx environment:   Remote properties — Entities that define the types, identities, and values from a device or remote system Services — Actions that can be performed on demand by a device or remote system Events — Data that is sent to a subscribed device or remote system whenever the Event is triggered   You can choose from any of the SDK's to create a custom application that meets their exact requirements.   C SDK   The C SDK is the most lightweight of all the SDKs and will result in an application that uses the least amount of RAM, frequently requiring less than 200kB. It is the only SDK that is distributed as source code, allowing compilation of C SDK applications on any platform even those without an operating system.   Learn more about the C SDK:   C SDK Tutorial C SDK Documentation   Java SDK   The Java SDK is designed for portability and simplicity to ease connecting any Java-enabled device or system to ThingWorx. The Java SDK is provided as .jar files and sample Java source code. Any system that can run Java 1.7.51 or later should be able to build and run the example applications.   Learn more about the Java SDK:   Java SDK Tutorial Java SDK Documentation   .Net SDK   The .Net SDK is provided as .dll files with sample Visual C# project files and source code. Any system that can run Microsoft NET 3.5 SP1 Framework development environment should be able to build and run the example applications.   Learn more about the .Net SDK:   .Net SDK Documentation   ThingWorx Kepware Server   Pros Cons Typical Use case Skill Required Connection Type  Easily connect to hundreds of different types of industrial equipment Requires computer running Windows physically connected to device Adding ThingWorx to an industrial setting Configure settings AlwaysOn™   The ThingWorx Kepware Server Windows client lets users quickly and easily connect real-time, bi-directional industrial controls data to the ThingWorx IoT Platform via the ThingWorx AlwaysOn protocol. ThingWorx services enable users to browse, read, write, and interact with ThingWorx Kepware Server, and includes intuitive tools that simplify the modeling of industrial things.   Learn more about the ThingWorx Kepware Server:   Connect Industrial Devices and Systems ThingWorx Kepware Server Documentation ThingWorx Kepware Server Manual   Edge MicroServer   Pros Cons Typical Use case Skill Required Connection Type  Easily connect with simple scripting Requires a device running Windows or Linux Customization with Lua scripting Connecting gateway router to ThingWorx Configure settings AlwaysOn™   The ThingWorx Edge MicroServer is a binary executable available for Windows and Linux running on either ARM or x86 processors. The EMS establishes an AlwaysOn, bi-directional connection to a destination ThingWorx platform when it is started. The EMS is configured by editing a json text file to specify the target platform and credentials. The EMS uses the always on connection to provide a local HTTP server that is a reflection of the platform REST API. This local copy of the platform API allows devices that are not capable of making encrypted connections across the open internet to securely interact with the platform. The EMS package also includes the Lua Script Resource application. This application extends the ThingWorx Foundation server by connecting through the EMS HTTP server and provides a Lua interpreter that can be used to connect local resources to the ThingWorx server.   Learn more about the ThingWorx Edge MicroServer:   Connect a Raspberry Pi to ThingWorx using the Edge MicroServer Edge MicroServer Documentation   Step 2: Next Steps   Congratulations! You've successfully completed the Choose a Connectivity Method guide.   At this point, you can make an educated decision regarding which connection methods are best suited for your application and infrastructure.   The next guide in the Connect and Configure Industrial Devices and Systems learning path is Use REST API to Access ThingWorx   Learn More   We recommend the following resources to continue your learning experience:   Capability Guide Connect ThingWorx Application Development Reference Build Get Started with ThingWorx for IoT Experience Create Your Application UI   Additional Resources   If you have questions, issues, or need additional information, refer to:   Resource Link Community Developer Community Forum Support ThingWorx Connectors Help Center
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In the evolving landscape of software development, ensuring support for the latest, most secure versions of programming languages is essential. At PTC, we continuously evaluate our technology stack, and Java is no exception. As part of our ongoing commitment to providing secure and high-performing products, we’re announcing some important updates to the Java support plans for ThingWorx.   Current Java Support in ThingWorx (Through Version v9.1.X - v9.6.X)   As of ThingWorx v9.6, Java 11 is the only supported version. This version has been a mainstay of our IoT platform, ensuring stability and performance across various use cases. However, Java 11 entered Extended Support in September 2023, meaning its standard support phase has ended. While this version will continue to receive security updates for a while, its lifecycle is winding down.   Introducing Java 21 Support in ThingWorx v9.7 (Planned Release: December 2024)   With ThingWorx 9.7, releasing in December 2024, we will introduce support for Java 21, the next Long-Term Support (LTS) version of Java. This upgrade brings key benefits, including improved performance, enhanced garbage collection, and increased security, ensuring that ThingWorx remains optimized for enterprise-scale IoT deployments. (More details: The Arrival Of JAVA 21) Given the diversity of our customer base, we know that some are still using Java 11, while others are ready to move to Java 21. ThingWorx 9.7 will support both versions, allowing customers the flexibility to upgrade to the latest ThingWorx version while preparing their environments for Java 21.   The Road to Java 21-Only: What to Expect in ThingWorx v10.0 (Planned Release: June 2025)   As we assess the adoption of Java 21 following the ThingWorx 9.7 release, our goal is to phase out support for Java 11 with ThingWorx 10.0, scheduled for release in June 2025. Starting with ThingWorx 10, Java 21 will be the only supported version, marking the end of Java 11 support for the core platform.   This is driven by the need to stay aligned with modern standards and best practices, including support for third-party technologies such as Tomcat v10 and Spring Framework v6, which require latest Java versions. These updates will ensure that ThingWorx continues to benefit from the latest advancements in the Java ecosystem. Next steps for ThingWorx users   As we approach the release of ThingWorx 9.7, we encourage customers to begin planning for the move to Java 21. While ThingWorx 9.7 will support both Java 11 and Java 21, we recommend upgrading to Java 21 to take full advantage of the enhancements it offers. For more detailed information on overall third party support, do check Release Advisor Vineet Khokhar Principal Product Manager, IoT Security   Stay tuned for more updates as we approach the release of ThingWorx v9.7, and as always, in case of issues, feel free to reach out to <support.ptc.com>  This post on ThingWorxTM status & roadmap is a preliminary version and not subject to your license agreement or any other agreement with ThingWorx. This post contains intended strategies, developments, and functionalities of the ThingWorxTM product. The information is furnished for information use only and is not intended to be binding upon ThingWorx to any particular course of business, product strategy, and/or development. Please note that this document is subject to change and may be changed by ThingWorx at any time without notice; accordingly, you should not rely on this data for production or purchasing decisions. ThingWorx assumes no responsibility for errors or omissions in this document.
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Greetings, Community Members! PTC has launched ThingWorx 9.6.0 as of June, and it's now ready for your upgrade! Let's explore the key enhancements in this latest version of ThingWorx.   What are the top three areas of updates in ThingWorx 9.6?   Performance, Scalability, Reliability, and Security: There's a significant boost in file transfer performance between connected devices and the ThingWorx platform. A notable enhancement in server startup performance, with some instances showing an 84% reduction in startup time. Numerous logging improvements, including limitations on log verbosity, log filtration, and configurable log storage capabilities, contribute to the stabilization of the ThingWorx system. Additionally, ThingWorx now supports log extraction to third-party software like Sumologic, Datadog, Splunk, Grafana, etc., utilizing the industry-standard OpenTelemetry framework starting from TWX 9.6. Content Security Policy has been implemented, fortifying ThingWorx against script and data injection attacks, man-in-the-middle (MITM) attacks, and clickjacking. Several tech stack updates in 9.6; support now available for Azure B2C and TLS 1.3 (limited)   Developer Productivity: Introducing a new Collection widget with improved performance, enabling a transition away from the legacy Collection and Repeater widgets. Several other new widgets such as KPI dial widget, Tree selector widget, Progress Tracker widget and other critical enhancements for ThingWorx WebComponents are now available Support for viewing mashup configurations such as layouts, bindings, and widget properties in a read-only mode, helping improve user experience by allowing multiple users to review mashup designs simultaneously without making edits.   Solutions updates: Streamlined continuous improvement with the ability to View and Create Actions in One-Click from performance analysis screens for the Digital Performance Management (DPM) solution. Enhanced performance for the Asset Monitoring & Utilization (AMU) solution, with alarm events creation now handled asynchronously. Several fixes and improvements for Connected Work Cell (CWC), Real-Time Production Performance Monitoring (RTPPM), and DPM such as limits evaluation, messages not displayed, incorrectly calculated KPIs and issues with Running Time on the operator display and more, helping customers achieve continuous improvements in their manufacturing operations   View release notes here and be sure to upgrade to 9.6!   Dilanur Bayraktar ThingWorx Product Management
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The natively exposed ThingWorx Platform performance metrics can be extremely valuable to understanding overall platform performance and certain of the core subsystem operations, however as a development platform this doesn't give any visibility into what your built solution is or is not doing.   Here is an amazing little trick that you can use to embed custom performance metrics into your application so that they show up automatically in your Prometheus monitoring system. What you do with these metrics is up to your creativity (with some constraints of course). Imaging a request counter for specific services which may be incredibly important or costly to run, or an exception metric that is incremented each time you catch an exception, or a query result size metric that informs you of how much data is being queried from the database.   Refer to Resources > MetricsServices: GetCounterMetric GetGaugeMetric IncrementCounterMetric DecrementCounterMetric SetGaugeMetric You'll need to give your metric a name - identified by key - and this is meant to be dotted notation* which will then be converted to underscores when the metric is exposed on the OpenMetrics endpoint.  Use sections/domains in the dotted notation to structure your metrics in-line with your application design.   COUNTER type metrics are the most commonly used and relate to things happening through time.  They are an index which will get timestamped as they're collected by Prometheus so that you will be able to look back in time and analyse and investigate what happened when and what the scale or impact was.  After the fact functions and queries will need to be applied to make these metrics most useful (delta over time, increase, rate per second).   Common examples of counter type metrics are: requests, executions, bytes transferred, rows queried, seconds elapsed, execution time.     Resources["MetricServices"].IncrementCounterMetric({ basetype: "LONG", value: 1, key: "__PTC_Reported.integration.mes.requests", aggregate: false });     GAUGE type metrics are point-in-time status of some thing being measured.   Common gauge type metrics are: CPU load/utilization, memory utilization, free disk space, used disk space, busy/active threads.     Resources["MetricServices"].SetGaugeMetric({ basetype: "NUMBER", value: 12, key: "__PTC_Reported.Users.ConnectedOperatorCount", aggregate: true });     Be aware of the aggregate flag, as it will make this custom metric cluster level which can have some unintended consequences.  Normally you always want performance metrics for the specific node as you then see what work is happening where and can confirm that it is being properly distributed within the cluster.  There are some situations however where you might want the cluster aggregation however, like with this concurrently connected operators.   Happy Monitoring!  
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Check out this new framework to achieving digital manufacturing success. Learn about the top 3 areas teams need to consider!    Identify a unified end goal Align it with the most impactful use cases Formulate a lasting strategy that resonates their long-term vision Discover More! 
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Tune in to The Lean Manufacturer podcast where expert guests bring their outside view of the IIoT and discuss various aspects of manufacturing. Over the course of the series, we’ll cover some of the most important ways the IIoT can maximize manufacturing efficiency and bring value to your organization, including the need for reducing planned and unplanned downtime, enabling operational efficiency, ensuring digital continuous improvement, and so much more.      
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Are you ready for #WorldIoTDay?
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Only logged in customers with a PTC active maintenance contract can view this content. Learn More

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PTC was recognized an outright leader in the global IoT market.
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Note: The following tutorial are based on a Thingworx/CWC 9.5. Steps and names may differ in another version. Context As a human reaction, the tracked time displayed may be misperceived by the Operator. It can lead to a reject of the solution. CWC doesn’t have (yet?) the capability to configure the visibility to hide the timer. The purpose of this tutorial is to create a quick and straight to the point customization to hide the timer in the execution screen. All other features, services and interfaces are left untouched.   As a big picture, here are the 6 modifications you will need to do: Modify the 4 mashups Modify 2 values in 2 tables of the MSSQL database   Status The mashup containing the timer is PTC.FSU.CWC.Execution.Overview_MU. It is easy to duplicate it and hide the timer widget (switch the visible property to false). But now, how to set it in the standard interface? In order to do it, you need to duplicate the mashups linked to the Execution.Overview_MU mashup. PTC.FSU.CWC.Execution.Overview_MU is directly referenced by the following entities: PTC.FSU.CWC.Authoring.Preview_MU PTC.FSU.CWC.Execution.WorkInstructionStart_MU PTC.FSU.CWC.GIobalUI.ApplicationSpecificHeader_HD PTC.FSU.CWC.WorkDefinitionExecution.StationSelectionContainer_EP   Customization Duplicate all those mashups except Authoring.Preview_MU because we will focus only on the authoring side of CWC. Hereafter it will be called the same as the original + _DUPLICATE. Perform the following modifications.   Open PTC.FSU.CWC.GlobalUI.ApplicationSpecificHeader_HD_DUPLICATE, then in Functions: open the expression named NavigateToStationSelection. Change the name of the mashup to the relevant one, example: PTC.FSU.CWC.WorkDefinitionExecution.StationSelectionContainer_EP_DUPLICATE open the validator named ShowRaiseHand. Change the name of the 2 mashups to the relevant ones, example: PTC.FSU.CWC.Execution.WorkInstructionStart_MU_DUPLICATE and PTC.FSU.CWC.Execution.Overview_MU_DUPLICATE open the validator named ShowStationSelection. Change the name of the 2 mashups to the relevant ones, example: PTC.FSU.CWC.Execution.WorkInstructionStart_MU_DUPLICATE   Open PTC.FSU.CWC.Execution.Overview_DUPLICATE, then in Functions: open the expression named SetMashupToWorkInstructionStart. Change the name of the mashup to the relevant one, example: PTC.FSU.CWC.Execution.WorkInstructionStart_MU_DUPLICATE open the expression named SetMashupToStationSelection. Change the name of the mashup to the relevant one, example: PTC.FSU.CWC.WorkDefinitionExecution.StationSelectionContainer_EP_DUPLICATE   Open PTC.FSU.CWC.Execution.WorkInstructionStart_MU_DUPLICATE, then in Functions: open the expression named NavigateToStart. Change the name of the mashup to the relevant one, example: PTC.FSU.CWC.Execution.Overview_MU_DUPLICATE open the expression named NavigateToStationSelection. Change the name of the mashup to the relevant one, example: PTC.FSU.CWC.WorkDefinitionExecution.StationSelectionContainer_EP_DUPLICATE   Open PTC.FSU.CWC.WorkDefinitionExecution.StationSelectionContainer_EP_DUPLICATE, in functions: open the expression named NavigateToStart. Change the name of the mashup to the relevant one, example: PTC.FSU.CWC.Execution.Overview_MU_DUPLICATE open the expression named NavigateToWorkInstructionStart. Change the name of the mashup to the relevant one, example: PTC.FSU.CWC.Execution.WorkInstructionStart_MU_DUPLICATE   Now, let’s change the database value. In MSSQL, navigate to the thingworxapps database, and edit the dbo.menu table. Look the line for AssemblyExecution (by default line 22) and look the value in column targetmashuplink. Switch the original value PTC.FSU.CWC.WorkDefinitionExecution.StationSelectionContainer_EP to the name of the duplication of this mashup. Lastly, edit the dbo.menucontext table. Look the line related to CWC (application UID = 5) and look the value in column targetmashuplink. Switch the original value PTC.FSU.CWC.GlobalUI.ApplicationSpecificHeader_HD to the name of the duplication of this mashup.   Result After this modification, you can start and check an operation. You should see the following result:
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There have been a number of questions from customers and partners on when they should use different tools for calculation of descriptive analytics within ThingWorx applications. The platform includes two different approaches for the implementation of many common statistical calculations on data for a property: descriptive services and property transforms. Both of these tools are easy to implement and orchestrate as part of a ThingWorx application. However, these tools are targeted for handling different scenarios and also differ in utilization of compute resources. When choosing between these two approaches it is important to consider the specific use case being implemented along with how the implemented approach will fit into the overall design and architecture of the ThingWorx environment. This article will provide some guidance on scenarios to use each of these approaches in ThingWorx applications and things to consider with each approach.   Let's look at the two different approaches and some guidelines for when they should be used.   Descriptive services (click for more details) provide a set of ThingWorx services to analyze a data set and perform many common data transformations.  These services are targeted for performing calculations and transformations on recent operating history of a single property.  Descriptive services are called on demand to perform batch calculations. Scenarios to use descriptive services: On demand calculations performed within a mashup, a service call or an event to determine action and calculation results are not (always) stored Regular occurring calculations on logged property values or generated datasets (batch calculations) Calculations are done regularly in minutes, hours or days on a discrete set of data.  Examples: average value in last hour, median value in last day, or max value in last half hour.  Time between data creation and analysis is minutes or hours.  Some latency in the calculation result is acceptable for the use case. Input data set has 10s to 100s to 1000s of values.  Keep the size of the input data at 10,800 values or less.  If larger data sizes are required, then break them into micro batches if possible or use other tools to handle the processing. Multiple calculations need to be done from the same set of input data.  Examples: average value in last hour, max value in the last hour and standard deviation value in the last hour are all required to be calculated. Things to consider when using descriptive services Requires input dataset to be in the specific datashape format that is used by descriptive services.  If property values are logged in a value stream, there is a service to query the values and prepare the dataset for processing.  If scenarios where the data is not for a logged property, then another service or sql query can be used to prepare the dataset for processing. Requires javascript development work to implement.   This includes creation of a service to execute the descriptive services and usage of subscriptions and events to orchestrate calculations. An example of the javascript to execute descriptive services is available in the help center (here) Typically retrieval of the input data from value stream (QueryTimedValuesForProperty) is slowest part of the process. The input data is sent to an out of process platform analytics service for all calculations. Broader set of calculation services available (see table at the end of this article) Remember that these services are not meant to be used for big data calculations or big data preparation.  Look for other approaches if the input data sets grow larger than 10,800 values Property Transforms (click for more details) provide a set of transformation services for streaming data as it enters ThingWorx.   Property transforms are targeted for performing continuous calculations on recent values in the stream of a single property and delivering results in (near) real-time.  Since property transforms are continuous calculations, they are always running and using compute resources. Before implementing property transforms review the information in the property transform sizing guide to better understand factors that impact the scaling of property transforms. Scenarios to use: Continuous calculations on a stream for a single property as new data comes into ThingWorx New values enter the stream faster than one value per minute (as a general guideline) Calculations required to be done in seconds or minutes.  Examples: average electrical current in last 10 seconds, median pressure in the last 10 readings,  or max torque in last minute Time between data creation and analysis is small (in seconds).  Results of property transform is required for rapid decisions and action so reducing latency is critical Data sets used for calculation are small and contain 10s to 100s of values.  Calculated results are stored in a new property in the ThingModel Things to consider when using property transforms Codeless process to create new property transforms on a single property in the ThingModel Does not require input property values to be logged as calculations are performed on streaming data as it enters ThingWorx Unlike descriptive services which only execute when called, each property transform creates a continuously running job that will always be using compute resources.  Resource allocations for property transforms must be included in the overall system architecture.  Before selecting the property transform approach, refer to the Property Transform Sizing Guide for more information about how different parameters affect the performance of Property Transforms and results of performance load test scenarios. Let’s apply these guidelines to a few different use cases to determine which approach to select. 1. Mashup application that allows users to calculate and view median temperature over a selected time window In this scenario, the calculation will be executed on-demand with a user defined time window. Descriptive services are the only option here since there is not a pre-defined schedule and the user can select which data to use for the calculation.   2. Calculate the max torque (readings arriving one per second) on a press over each minute without storing all of the individual readings. In this scenario, the calculation will be executed without storing the individual readings coming from the machine. The transformation is made to the data on its way into ThingWorx and continuously calculating based on new values. Property transforms are the only option here since the individual values are not being stored.   3. Calculation of average pressure value (readings arriving one per second) over a five minute window to monitor conditions and raise an alert when the median value is more than two standard deviations from expected. In this scenario, both descriptive services and property transforms can perform the calculation required. The calculation is going to occur every 5 minutes and each data set will have about 300 values. The selection of batch (descriptive services) or streaming (property transforms) will likely be determined by the usage of the result. In this case, the calculation result will be used to raise an alert for a specific five minute window which likely will require immediate action. Since the alert needs to be raised as soon as possible, property transforms are the best option (although descriptive services will handle this case also with less compute resource requirements).   4, Calculation of median temperature (readings each 20 seconds) over 48 hour period to use as input to predict error conditions in the next week. In this scenario, the calculation will be performed relatively infrequently (once every 48 hours) over a larger data set (about 8,640 values). Descriptive services are the best option in this case due to the data size and calculation frequency. If property transforms were used, then compute resources would be tied up holding all of the incoming values in memory for an extended period before performing a calculation. With descriptive services, the calculation will only consume resource when needed, or once every 48 hours.   Hopefully this information above provides some more insight and guidelines to help choose between property transforms and descriptive services. The table below provides some additional comparisons between the two approaches.     Descriptive Services Property Transforms Purpose Provide a set of ThingWorx services to analyze a data set and perform many common data transformations. Provide a set of prescribed transformation services for streaming data as it enters ThingWorx. Processing Mode Batch Streaming / Continuous Delivery API / Service Composer interface API / Service Input Data Discrete data set Must be logged Single property Configurable by time or lookback Rolling data set on property X Persistence is optional Single property Configurable by time or lookback Output Data Return object handled programmatically Single output for discrete data set New property f_X in the input model Continuous output at configurable frequency Output time aligned with input data Available Services Statistics (min, max, mean, median, mode, std deviation) SPC calculations (# continuous data points: above threshold, in / out of range, increasing / decreasing, alternating) Data distribution: count by bins (histogram) Five numbers (min, lower quartile, median, upper quartile, max) Confidence interval Sampling frequency Frequency transform (FFT) Statistics (min, max, mean, median, mode, std deviation) SPC calculations (# continuous data points: above threshold, in / out of range, increasing / decreasing, alternating)
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    Step 3: Monitor SPC Properties   Once the properties have been configured, you are ready to progress on to SPC monitoring.   This is done by viewing the PTC.SPC.Monitoring_MU Mashup.   NOTE: Once a property has been configured for SPC monitoring, 2-5 minutes must pass before the accelerator has collected enough streaming values to perform SPC calculations. During this time, you may see an item that has 2 OOC rules violated; “Collecting Enough Data to Begin Monitoring” and “… to Compute Capability”.     Within Property SPC Status, click an item from the grid that has 0 in the OOC column. See that the Out of Control Rules area is blank, since there are no currently-violated SCP rules for that selected property. Both CP and CPK are above 1.0, showing that the process is capable. All the points in the charts are blue, as they do not violate any OOC rules. Within Property SPC Status, click an item from the grid that has a nonzero number in the OOC column.   See that the Out of Control Rules area has one or more rules listed that are currently being violated. Here, the rule being violated is Range Out of Control. One or more of the charts may have point(s) that are red. Here, you can see one of the points in the R chart is red, as it is above the Upper Control Limit. In the bottom-left, click Refresh Now.   Note that the datetime value of the date picker in the lower-left indicates the period to which the Mashup has updated. It is possible that Properties that were previously not in violation are now violating OOC rules; the opposite is also possible. Note that not all points that violate an OOC rule will display in red. Here, you can see that the rule 8 Consecutive Points Above Center Line is violated, but the corresponding points in the X-Bar Chart are not red. View the SPC status at a time from the recent past. In the lower-left, click date picker. Choose a datetime of 2-3 minutes in the past. You will see that the date picker reflects the datetime value you selected. All the Widgets in the Mashup are updated to reflect their status at that point in time. Enter continuous monitoring mode. Select any of the eight (8) items from the Property SPC Status area. To the left of the Refresh Now button, click the toggle. This will enable the Mashup to auto-refresh every 30 seconds. In the upper-right corner of the Property SPC Status area, click the gray arrow to expand the monitoring display.   Every 30 seconds, the monitoring display will update to show the most recent status for the item you selected.       Step 4: Next Steps   Congratulations! You’ve successfully completed the Deploy Statistical Process Control guide, and learned how to:   Configure multiple properties for SPC monitoring Identify abnormalities in streaming property values   Learn More   We recommend the following resources to continue your learning experience:    Site              Link Wikipedia Western Electric Rules Wikipedia Process Capability   Additional Resources If you have questions, issues, or need additional information, refer to:    Resource       Link Community Developer Community Forum Support ThingWorx Help Center  
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    Configure streaming asset properties for SPC monitoring.   Guide Concept   Note: This guide is intended only as a starting point and is not a fully developed or supported solution. This accelerator has been developed using ThingWorx 8.5 and should not be used with any previous versions of the software.   This project introduces you to configuring Properties from your connected streaming assets for Statistical Process Control (SPC) monitoring.   Following the steps in this guide, you will learn how multiple connected assets and their Properties can be displayed in a hierarchy tree.   You will then configure these Properties using predetermined set points, and upper and lower control points for the assets.   Finally, you will learn to navigate the monitoring of the Properties.   We introduce some of the basic building blocks of an SPC accelerator, including important Things and Mashups. You will also use ThingWorx Timers to simulate streaming data.     You'll learn how to   Configure multiple properties for SPC monitoring Identify abnormalities in streaming property values   NOTE: The estimated time to complete this guide is 30 minutes     Step 1: Import SPC Accelerator   Before exploring Statistical Process Control (SCP) within ThingWorx Foundation, you must first import some Entities via the top-right Import / Export button.   Download and unzip PTC_StatisticalCalculations_PJ.zip and PTC_SPC_PJ.zip. These two files each contain a ThingWorx project of a similar name. Import PTC_StatisticalCalculations_PJ.twx first. Import PTC_SPC_PJ.twx once the other import has completed. Explore the imported entities.   Each of the projects contain multiple entities of various types. The most important entities you will use in this guide are as follows:    Entity Name                                   Description Motor_Pump1 Timer to simulate streaming data Motor_Blower1 Timer to simulate streaming data PTC.SPC.ConfigurationHelper Thing that manages the accelerator PTC.SPC.Configuration_MU Mashup for configuring SPC properties PTC.SPC.Monitoring_MU Mashup for monitoring SPC properties   Step 2: Configure Properties for SPC monitoring   You may configure SPC monitoring for multiple production lines, connected assets on those lines, and time-series Properties on those assets using the SPC accelerator.   This is done by viewing the PTC.SPC.Configuration_MU Mashup.   Follow these steps to configure an SPC Property.   Create a new production line   In the Enter New Production Line Name text field, type Line100. Click Add New Line.   Now you will see the new production line added to the Asset Hierarchy tree along the left. All production lines you’ve created (as well as their assets and the assets’ Properties) will be shown here.   In the lower-right, the SPC Property Configuration area has disappeared because the item selected in the Asset Hierarchy tree is the new line; only assets within lines can have streaming Properties.   Add a streaming asset to Line100   Within the Select Asset Thing entity picker, type Motor_Blower1. Click Add Asset for Line.   This asset has Properties that are streaming into ThingWorx. Multiple assets can be added to the same production line by selecting the line from the Asset Hierarchy tree and following the steps above.   If you select the new asset from the Asset Hierarchy tree, you will see that the list of Properties Eligible for SPC Monitor is shown in the SPC Property Configuration area. All Properties have the same default configuration associated with them.   Configure a property for SPC Monitoring   Below is a brief description of each of the configuration parameters:    Parameter           Description Sample Size Number of consecutive property values to average together. For example, a Sample Size of 5 will tell the accelerator to group every 5 property values together and calculate their average value. XBar Points Number of the most recent sample aggregations to display in the SPC Monitoring Mashup. This also affects SPC calculations. Capability Points Number of the most recent sample aggregations to use when populating the Capability Histogram in the SPC Monitoring Mashup. Set Point Value determined to be the set point for that particular property on the asset. Lower Design Spec Value determined to be the lower design spec for that particular property on the asset. This is used for capability calculations. Upper Design Spec Value determined to be the upper design spec for that particular property on the asset. This is used for capability calculations.   Select Pressure1 from the list of eligible properties. Enter the following values:  Properties                      Values Sample Size 5 Xbar Points 30 Capability Points 60 Set Point 73 Lower Design Spec 68 Uppder Design Spec 78   3, Select Xbar-R Chart. 4. Click Add or Update SPC Monitoring. 5. Pressure1 is added to the Asset Hierarchy tree underneath the Motor_Blower1 asset. 6. If you select this Property, you can modify the configuration and save it by clicking Add or Update SPC Monitoring.   Configure assets and Properties   Follow these steps using the following parameters:                                     Line Asset  Property  Sample Size Xbar Point Capability Points Set Points Lower Design Spec Upper Design Spec Chart Type 100 Motor_Blower1 Pressure1 5 30 60 73 68 78 Xbar-R 100 Motor_Blower1 Pressure2 5 30 60 78 68 89 Xbar-R 100 Motor_Blower1 Temperature1 5 30 60 50 44 56 Xbar-s 100 Motor_Blower1 Temperature2 5 30 60 85 73 97 Xbar-s 100 Motor_Pump1 Vibration10 5 30 60 150 108 190 Xbar-s 100 Motor_Pump1 Vibration11 8 60 100 200 168 220 Xbar-s 100 Motor_Pump1 Pressure100 5 30 60 100 84 118 Xbar-R 100 Motor_Pump1 Pressure200 5 30 60 90 84 97 Xbar-R   As you add assets to Line100 and configure their Properties, you will see the Asset Hierarchy tree grow. If you need to remove an asset or its associated Properties from the Asset Hierarchy tree, you may select that item, and click Remove Selected. For any item you remove, its child-items will also be removed.   Click here to view Part 2 of this guide.
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  PLEASE NOTE DataConnect has now been deprecated and no longer in use and supported.   We are regularly asked in the community how to send data from ThingWorx platform to ThingWorx Analytics in order to perform some analytics computation. There are different ways to achieve this and it will depend on the business needs. If the analytics need is about anomaly detection, the best way forward is to use ThingWatcher without the use of ThingWorx Analytics server. The ThingWatcher Help Center is an excellent place to start, and a quick start up program can be found in this blog. If the requirement is to perform a full blown analytics computation, then sending data to ThingWorx Analytics is required. This can be achieved by Using ThingWorx DataConnect, and this is what this blog will cover Using custom implementation. I will be very pleased to get your feedback on your experience in implementing custom solution as this could give some good ideas to others too. In this blog we will use the example of a smart Tractor in ThingWorx where we collect data points on: Speed Distance covered since last tyre change Tyre pressure Amount of gum left on the tyre Tyre size. From an Analytics perspective the gum left on the tyre would be the goal we want to analyse in order to know when the tyre needs changing.   We are going to cover the following: Background Workflow DataConnect configuration ThingWorx Configuration Data Analysis Definition Configuration Data Analysis Definition Execution Demo files   Background For people not familiar with ThingWorx Analytics, it is important to know that ThingWorx Analytics only accepts a single datafile in a .csv format. Each columns of the .csv file represents a feature that may have an impact on the goal to analyse. For example, in the case of the tyre wear, the distance covered, the speed, the pressure and tyre size will be our features. The goal is also included as a column in this .csv file. So any solution sending data to ThingWorx Analytics will need to prepare such a .csv file. DataConnect will perform this activity, in addition to some transformation too.   Workflow   Decide on the properties of the Thing to be collected, that are relevant to the analysis. Create service(s) that collect those properties. Define a Data Analysis Definition (DAD) object in ThingWorx. The DAD uses a Data Shape to define each feature that is to be collected and sends them to ThingWorx Analytics. Part of the collection process requires the use of the services created in point 2. Upon execution, the DAD will create one skinny csv file per feature and send those skinny .csv files to DataConnect. In the case of our example the DAD will create a speed.csv, distance.csv, pressure.csv, gumleft.csv, tyresize.csv and id.csv. DataConnect processes those skinny csv files to create a final single .csv file that contains all these features. During the processing, DataConnect will perform some transformation and synchronisation of the different skinny .csv files. The resulting dataset csv file is sent to ThingWorx Analytics Server where it can then be used as any other dataset file.     DataConnect configuration   As seen in this workflow a ThingWorx server, DataConnect server and a ThingWorx Analytics server will need to be installed and configured. Thankfully, the installation of DataConnect is rather simple and well described in the ThingWorx DataConnect User’s guide. Below I have provided a sample of a working dataconnect.conf file for reference, as this is one place where syntax can cause a problem:   ThingWorx Configuration The platform Subsystem needs to be configured to point to the DataConnect server . This is done under SYSTEM > Subsystems > PlatformSubsystem:     DAD Configuration The most critical part of the process is to properly configure the DAD as this is what will dictate the format and values filled in the skinny csv files for the specific features. The first step is to create a data shape with as many fields as feature(s)/properties collected.   Note that one field must be defined as the primary key. This field is the one that uniquely identifies the Thing (more on this later). We can then create the DAD using this data shape as shown below   For each feature, a datasource needs to be defined to tell the DAD how to collect the values for the skinny csv files. This is where custom services are usually needed. Indeed, the Out Of The Box (OOTB) services, such as QueryNumberPropertyHistory, help to collect logged values but the id returned by those services is continuously incremented. This does not work for the DAD. The id returned by each services needs to be what uniquely identifies the Thing. It needs to be the same for all records for this Thing amongst the different skinny csv files. It is indeed this field that is then used by DataConnect to merge all the skinny files into one master dataset csv file. A custom service can make use of the OOTB services, however it will need to override the id value. For example the below service uses QueryNumberPropertyHistory to retrieve the logged values and timestamp but then overrides the id with the Thing’s name.     The returned values of the service then needs to be mapped in the DAD to indicate which output corresponds to the actual property’s value, the Thing id and the timestamp (if needed). This is done through the Edit Datasource window (by clicking on Add Datasource link or the Datasource itself if already defined in the Define Feature window).   On the left hand side, we define the origin of the datasource. Here we have selected the service GetHistory from the Thing Template smartTractor. On the right hand side, we define the mapping between the service’s output and the skinny .csv file columns. Circled in grey are the output from the service. Circled in green are what define the columns in the .csv file. A skinny csv file will have 1 to 3 columns, as follow: One column for the ID. Simply tick the radio button corresponding to the service output that represents the ID One column representing the value of the Thing property. This is indicated by selecting the link icon on the left hand side in front of the returned data which represent the value (in our example the output data from the service is named value) One column representing the Timestamp. This is only needed when a property is time dependant (for example, time series dataset). On the example the property is Distance, the distance covered by the tyre does depend on the time, however we would not have a timestamp for the TyreSize property as the wheel size will remain the same. How many columns should we have (and therefore how many output should our service has)? The .csv file representing the ID will have one column, and therefore the service collecting the ID returns only one output (Thing name in our smartTractor example – not shown here but is available in the download) Properties that are not time bound will have a csv file with 2 columns, one for the ID and one for the value of the property. Properties that are time bound will have 3 columns: 1 for the ID, one for the value and one for the timestamp. Therefore the service will have 3 outputs.   Additionally the input for the service may need to be configured, by clicking on the icon.   Once the datasources are configured, you should configure the Time Sampling Interval in the General Information tab. This sampling interval will be used by DataConnect to synchronize all the skinny csv files. See the Help Center for a good explanation on this.   DAD Execution Once the above configuration is done, the DAD can be executed to collect properties’ value already logged on the ThingWorx platform. Select Execution Settings in the DAD and enter the time range for property collection:   A dataset with the same name as the DAD is then created in DataConnect as well as in ThingWorx Analytics Server Dataconnect:     ThingWorx Analytics:   The dataset can then be processed as any other dataset inside ThingWorx Analytics.   Demo files   For convenience I have also attached a ThingWorx entities export that can be imported into a ThingWorx platform for you to take a closer look at the setup discussed in this blog. Attached is also a small simulator to populate the properties of the Tractor_1 Thing. The usage is : java -jar TWXTyreSimulatorClient.jar  hostname_or_IP port AppKey For example: java -jar TWXTyreSimulatorClient.jar 192.168.56.106 8080 d82510b7-5538-449c-af13-0bb60e01a129   Again feel free to share your experience in the comments below as they will be very interesting for all of us. Thank you
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Overview REST stands for representational state transfer and is a software architectural style common in the World Wide Web. Anything with a RESTful interface can be communicated with using standard REST syntax. ThingWorx has such an interface built-in to make viewing and updating Thing properties as well as executing services easy to do independently of the Web UI.   How to Use REST API The ThingWorx REST API is entirely accessible via URL using the following syntax:    (Precision LMS. Getting Started With ThingWorx 5.4 (Part 1 of Introduction to ThingWorx 5.4). PTC University. https://precisionlms.ptc.com/viewer/course/en/21332822/page/21332905.)   The above example shows how to access a service called “GetBlogEntriesWithComments” found on the “ThingWorxTrainingMaintenanceBlog” Thing. Notice that even though this service gets XML formatted data, the method is type “POST” and “GET” will not work in this scenario (Further reading: https://support.ptc.com/appserver/cs/view/solution.jsp?n=CS214689&lang=en_US).   In order to be able to run REST API calls from the browser, one must allow request method switching. This can be enabled by checking the box “Allow Request Method Switch” in PlatformSubsystem (Further reading: https://support.ptc.com/appserver/cs/view/solution.jsp?n=CS224211&lang=en_US).   Access REST API from Postman Postman is a commonly used REST client which can ping servers via REST API in a manner which mimics third party software. It is free and easy-to-use, with a full tutorial located here: https://www.getpostman.com/docs/   In order to make a request, populate the URL field with a properly formatted REST API call (see previous section). Parameters will not automatically be URL-encoded, but right-clicking on a highlighted portion of the URL and selecting EncodeURIComponent encodes the section.   Next click the headers tab. Here is where the content-type, accept, and authorization are set for the REST call. Accept refers to which response format the REST call is expecting while content-type refers to the format of the request being sent to the server. Authhorization is required for accessing ThingWorx, even via REST API (see previous section for examples authenticating using an app key, but in Postman you can also use Basic Auth using a username and password)   In Postman, there is also ample opportunity to modify the request body under the Body tab. There are several options here for setting parameters. Form-data and x-www-form-urlencoded both allow for setting key value pairs easily and cleanly, and in the latter case, encoding occurs automatically (e.g. “Hello World” becomes %22Hello%20World%22). Raw request types can contain anything and Postman will not touch anything entered except to replace environment variables. Whatever is placed in the text area under raw will get sent with the request (normally XML or JSON, as specified by content-type). Finally, binary allows for sending things which cannot normally be entered into Postman, e.g. image, text, or audio files.     REST API Examples For introductory level examples, see the previous Blog document found here: https://community.thingworx.com/docs/DOC-3315   Retrieving property values from “MyThing” using GET, the default method type (notice how no “method=GET” is required here, though it would still work with that as well): http://localhost/Thingworx/Things/MyThing/Properties/   Updating “MyProperty “with the value “hello” on “MyThing” using PUT: http://localhost/Thingworx/Things/MyThing/Properties/MyProperty?method=PUT&value=hello In Postman, you can send multiple property updates at once via query body (in this case updating all of the properties, the string “Prop1” and the number “Prop2” on MyThing) § Query: http://localhost/Thingworx/Things/MyThing/Properties/* § Query Type: PUT § Query Headers: Content-Type: application/json Authorization: Basic Auth (input username and password on Authorization tab and this will auto-populate) § Body JSON: {"Prop1":"hello world","Prop2":10} Note: you can also specify multiple properties as shown, but only update one at a time in Postman by utilizing the browser syntax given above   Calling “MyService” (a service on “TestThing)” with a String input parameter (“InputString”): http://localhost/Thingworx/Things/TestThing/Services/MyService?method=post&InputString=input   It is easier to pass things like XML and JSON into services using Postman. This query calls “MyJSONService” on “MyThing” with a JSON input parameter § Query: http://localhost/Thingworx/Things/MyThing/Services/MyJSONService § Query Type: § Queries Headers: Accept should match service output (text/html for String) Content-Type: application/json or Authorization: Basic Auth (input username and password on Authorization tab and this will auto-populate) Body JSON: {"InputJSON":"{\"JSONInput\":{\"PropertyName\":\"TestingProp\",\"PropertyValue\":\"Test\"}}"} Body XML:{"xmlInput": "<xml><name>User1</name></xml"}   Viewing “BasicMashup” using AppKey authentication (so no login is required because this Application Key is set-up to login as a user who has permissions to view the Mashup): http://localhost/Thingworx/Mashups/BasicMashup?appKey=b101903d-af6f-43ae-9ad8-0e8c604141af&x-thingworx-session=true Read more here: https://support.ptc.com/appserver/cs/view/solution.jsp?n=CS227935   Downloading Log Information from “ApplicationLog” (or other log types): http://localhost/Thingworx/Logs/ApplicationLog/Services/QueryLogEntries?method=POST   In Postman, more information can be passed into some queries via query body § Query: http://localhost/Thingworx/Logs/ApplicationLog/Services/QueryLogEntries Query Type: POST Query Headers: Accept: application/octet-stream or Content-Type: application/json Authorization: Basic Auth (input username and password on Authorization tab and this will auto-populate) Body: {\"searchExpression\":\"\",\"origin\":\"\",\"instance\":\"\",\"thread\":\"\", \"startDate\":1462457344702,\"endDate\":1462543744702,\"maxItems\":100}   Downloading “MyFile.txt” from “MyRepo” FileRepository (here, “/” refers to the home folder of this FileRepository and the full path would be something like “C:\ThingworxStorage\repository\MyRepo\MyFolder\MyFile.txt”): http://localhost/Thingworx/FileRepositoryDownloader?download-repository=MyRepo&download-path=/MyFolder/MyFile.txt   Uploading files to FileRepository type Things is a bit tricky as anything uploaded must be Base64 encoded prior to making the service call. In Postman, this is the configuration to used to send a file called “HelloWorld.txt”, containing the string “Hello World!”, to a folder called “FolderInRepo” on a FileRepository named “MyRepo”:   Query: http://localhost/Thingworx/Things/MyRepo/Services/SaveBinary Query Type: POST Query Headers: Accept: application/json Content-Type: application/json Authorization: Basic Auth (input username and password on Authorization tab and this will auto-populate) Body: {"path" : "/FolderInRepo/HelloWorld.txt", "content" : "SGVsbG8gV29ybGQh"} Notice here that the content has been encoded to Base64 using a free online service. In most cases, this step can be handled by programming language code more easily and for more challenging file content   Resources and other built-in Things can be accessed in similar fashion to user-created Things. This query searches for Things with the “GenericThing” ThingTemplate implemented: http://localhost/Thingworx/Resources/SearchFunctions/Services/SearchThingsByTemplate?method=POST&thingTemplate=GenericThing   Deleting “MyThing” (try using services for this instead when possible since they are likely safer): http://localhost/Thingworx/Things/MyThing1?method=DELETE&content-type=application/JSON   Exporting all data within ThingWorx using the DataExporter functionality: http://localhost/Thingworx/DataExporter?Accept=application/octet-stream   Exporting all entities which have the Model Tag “Application.TestTerm” within ThingWorx using the Exporter functionality: http://localhost/Thingworx/Exporter?Accept=text/xml&searchTags=Applications:TestTerm
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  Connect an ESP8266 WiFi module using the Arduino programming environment and the ThingWorx REST API.   This information was created for a previous version of ThingWorx and may not be fully accurate. Report any issues with this article here.   Guide Concept   This project will introduce the utilities ThingWorx provides for connections to an Adafruit Feather.   Following the steps in this guide, you will have a fully configured setup between your Adafruit Feather and the ThingWorx platform to begin your IoT development.   We will teach you how to utilize the ThingWorx REST API and the Arduino programming language to connect your Adafruit Feather for IoT application development.   You'll learn how to   Connect an ESP8266 WiFi module to a ThingWorx server Use the Arduino programming environment with the ThingWorx REST API   NOTE:  The estimated time to complete this guide is 30 minutes.      Step 1: Install Software   Arduino   There are three pieces of software to install before getting started with the ThingWorx-specfic code: Install FTDI USB driver. If you have connected development boards to your PC in the past you probably already have this installed. The latest Arduino IDE full install will also install the driver. NOTE: SparkFun has an excellent FTDI Driver Installation guide.   3. Arduino IDE - version 1.6.4 or later recommended. 4. Install ESP8266 addon into Arduino IDE. 5. The SparkFun Setting Up the Arduino IDE Tutorial is a great guide to getting started with their board. 6. Adafruit also has a great with their board Testing a Wifi Connection Tutorial.   When everything is set-up correctly and you are able to upload and see the Blink demo flashing the LED on the board you are ready to move to the next step.   ThingWorx Foundation Server   Start, and Launch your ThingWorx Foundation server. Log into Composer.  You will need a ThingWorx appKey to authorize the board.  Follow these instructions in Create an Application Key to create an appKey that you will copy into the source code in the next step.       Step 2: Set up Arduino IDE, Developer Board, and ThingWorx Server   Once you are able to run the blink test sketch, your IDE and board are set-up correctly. To learn how to run the blink test, read the SparkFun Board Instructions and the Adafruit board instructions.   Arduino IDE   Before you will be able to run the code below that connects a developement board to a ThingWorx Foundation server, you will need to modify the code with four pieces of information specific to your environment. You will need:   A WiFi access point SSID The correct password for the WiFi access point The IP address or URL of a ThingWorx Foundation Server A valid appKey created by your ThingWorx Foundation Server. To create an appKey, follow these instructions to Create An Application Key   Create a new sketch in the Arduino IDE then copy and paste the code below into the IDE.   Modify the WiFi Definitions and the ThingWorx server definitions shown in the code with your specficic information then save the sketch with a new name. The next step will describe what you should see when you upload and run the code on your developer board.   /** * * ESP8266_ThingWorx_REST_Demo.ino * * * (c) PTC, Inc. 2016-2020 * */ #include <Arduino.h> #include <ESP8266WiFi.h> #include <ESP8266HTTPClient.h> #include <WiFiClientSecureBearSSL.h> ////////////////////// // WiFi Definitions // ////////////////////// const char WiFiSSID[] = "Liberty454"; // WiFi access point SSID const char WiFiPSK[] = "Flutie22"; // WiFi password - empty string for open access points ////////////////////////////////////////////// // ThingWorx server definitions // // modify for a specific platform instance // ////////////////////////////////////////////// const char TWPlatformBaseURL[] = "https://pp-2007011431nt.devportal.ptc.io"; const char appKey[] = "2d4e9440-3e51-452f-a057-b55d45289264"; //////////////////////////////////////////////////////// // Pin Definitions - board specific for Adafruit board// //////////////////////////////////////////////////////// const int RED_LED = 0; // Thing's onboard, red LED - const int BLUE_LED = 2; // Thing's onboard, blue LED const int ANALOG_PIN = A0; // The only analog pin on the Thing const int OFF = HIGH; const int ON = LOW; // this will set as the Accept header for all the HTTP requests to the ThingWorx server // valid values are: application/json, text/xml, text/csv, text/html (default) #define ACCEPT_TYPE "text/csv" ///////////////////// //Attempt to make a WiFi connection. Checks if connection has been made once per second until timeout is reached //returns TRUE if successful or FALSE if timed out ///////////////////// boolean connectToWiFi(int timeout){ Serial.println("Connecting to: " + String(WiFiSSID)); WiFi.begin(WiFiSSID, WiFiPSK); // loop while WiFi is not connected waiting one second between checks uint8_t tries = 0; // counter for how many times we have checked while ((WiFi.status() != WL_CONNECTED) && (tries < timeout) ){ // stop checking if connection has been made OR we have timed out tries++; Serial.printf(".");// print . for progress bar Serial.println(WiFi.status()); delay(2000); } Serial.println("*"); //visual indication that board is connected or timeout if (WiFi.status() == WL_CONNECTED){ //check that WiFi is connected, print status and device IP address before returning Serial.println("WiFi connected"); Serial.println("IP address: "); Serial.println(WiFi.localIP()); return true; } else { //if WiFi is not connected we must have exceeded WiFi connection timeout return false; } } ////////////////////////// //create a name for the board that is probably unique by appending last two bytes of MAC address //return name as a String /////////////////////////////// String getUniqueDeviceName(){ String uniqueName; uint8_t mac[WL_MAC_ADDR_LENGTH]; WiFi.macAddress(mac); // WiFi does NOT need to be connected for this call String macID = String(mac[WL_MAC_ADDR_LENGTH - 2], HEX) + String(mac[WL_MAC_ADDR_LENGTH - 1], HEX); macID.toUpperCase(); uniqueName = "ESP8266Board-" + macID; Serial.println("DeviceID>" + uniqueName); return uniqueName; } /////////////////////////////// // make HTTP GET to a specific Thing and Propertry on a ThingWorx server // thingName - Name of Thing on server to make GET from // property - Property of thingName to make GET from // returns HTTP response code from server and prints full response /////////////////////////////// int httpGetPropertry(String thingName, String property){ std::unique_ptr<BearSSL::WiFiClientSecure>client(new BearSSL::WiFiClientSecure); client->setInsecure(); HTTPClient https; int httpCode = -1; String response = ""; Serial.print("[httpsGetPropertry] begin..."); String fullRequestURL = String(TWPlatformBaseURL) + "/Thingworx/Things/"+ thingName +"/Properties/"+ property +"?appKey=" + String(appKey); https.begin(*client,fullRequestURL); https.addHeader("Accept",ACCEPT_TYPE,false,false); Serial.println("GET URL>" + fullRequestURL +"<"); // start connection and send HTTP header httpCode = https.GET(); // httpCode will be negative on error if(httpCode > 0) { response = https.getString(); Serial.printf("[httpGetPropertry] response code:%d body>",httpCode); Serial.println(response + "<\n"); } else { Serial.printf("[httpGetPropertry] failed, error: %s\n\n", https.errorToString(httpCode).c_str()); } https.end(); return httpCode; } /////////////////////////////// // makes HTTP POST to platform to CreateThing service using input string as the new Things's name. // Returns server response code /////////////////////////////// int createThing(String nameOfThing){ std::unique_ptr<BearSSL::WiFiClientSecure>client(new BearSSL::WiFiClientSecure); client->setInsecure(); HTTPClient https; int httpCode = -1; String response = ""; Serial.print("[createThing] begin..."); String fullRequestURL = String(TWPlatformBaseURL) + "/Thingworx/Resources/EntityServices/Services/CreateThing?appKey=" + String(appKey); https.begin(*client,fullRequestURL); https.addHeader("Accept",ACCEPT_TYPE,false,false); https.addHeader("Content-Type","application/json",false,false); Serial.println("POST URL>" + fullRequestURL + "<"); // start connection and send HTTP header httpCode = https.POST("{\"name\": \""+ nameOfThing +"\",\"thingTemplateName\": \"GenericThing\"}"); // httpCode will be negative on error if(httpCode > 0) { response = https.getString(); Serial.printf("[createThing] response code:%d body>",httpCode); Serial.println(response + "<\n"); } else { Serial.printf("[createThing] POST... failed, error: %s\n\n", https.errorToString(httpCode).c_str()); } https.end(); return httpCode; } /////////////////////////////// // make HTTP POST to ThingWorx server Thing service // nameOfThing - Name of Thing to POST to // endPoint - Services URL to invoke // postBody - Body of POST to send to ThingWorx platform // returns HTTP response code from server /////////////////////////////// int postToThing(String nameOfThing, String endPoint, String postBody){ std::unique_ptr<BearSSL::WiFiClientSecure>client(new BearSSL::WiFiClientSecure); client->setInsecure(); HTTPClient https; int httpCode = -1; String response = ""; Serial.print("[postToThing] begin..."); String fullRequestURL = String(TWPlatformBaseURL) + "/Thingworx/Things/"+ nameOfThing +"/Services/"+ endPoint +"?appKey=" + String(appKey); Serial.println("URL>" + fullRequestURL + "<"); https.begin(*client,fullRequestURL); https.addHeader("Accept",ACCEPT_TYPE,false,false); https.addHeader("Content-Type","application/json",false,false); Serial.println("[postToThing] POST body>" + postBody + "<"); // start connection and send HTTP header httpCode = https.POST(postBody); // httpCode will be negative on error if(httpCode > 0) { response = https.getString(); Serial.printf("[postToThing] response code:%d body>",httpCode); Serial.println(response + "<\n"); } else { Serial.printf("[postToThing] POST... failed, error: %s\n\n", https.errorToString(httpCode).c_str()); } https.end(); return httpCode; } void setup() { pinMode(RED_LED, OUTPUT); pinMode(BLUE_LED, OUTPUT); Serial.begin(115200); Serial.setDebugOutput(true); Serial.println(); Serial.println(); Serial.println(); Serial.printf("Starting...\n"); for(uint8_t t = 4; t > 0; t--) { Serial.printf(" WAIT %d...\n", t); Serial.flush(); delay(1000); } connectToWiFi(10); } void loop() { String thingName = getUniqueDeviceName(); //unique name for this Thing so many work on one ThingWorx server while (WiFi.status() == WL_CONNECTED) { //confirm WiFi is connected before looping as long as WiFi is connected int getResponseCode = httpGetPropertry(thingName, "SomeNumber"); if (getResponseCode == 404){ // a 404 means connected, but either no Thing or no property // first we will try to create a new Thing on the platform int postResp = createThing(thingName); // saving the response code for retry logic in the future // the newly crated Thing has to be enabled postResp = postToThing(thingName,"EnableThing",""); //POST to EnableThing endpoint with no body // after the new Thing is enabled it must be restarted postResp = postToThing(thingName,"RestartThing",""); //POST to RestartThing endpoint with no body // add a property to the Thing 3rd parameter is ugly because required quotes are escaped with backslashes postResp = postToThing(thingName,"AddPropertyDefinition", "{\"name\":\"SomeNumber\",\"type\":\"NUMBER\"}"); //POST body contains JSON object with property name and property type // after changes to a Thing's structure it must be restarted postResp = postToThing(thingName,"RestartThing",""); //POST to RestartThing endpoint with no body } delay(2000); }// end WiFi connected while loop Serial.printf("****Wifi connection dropped****\n"); WiFi.disconnect(true); delay(10000); connectToWiFi(10); }     Step 3: Run Arduino Demo   Click on the right arrow in the Arduino IDE toolbar to upload and start the sketch. Note:The compile and upload process will take almost a minute and will show [ 100% ] when it is completed successfully. 2. After the upload is complete, click on Tools > Serial Monitor and select 115200 baud from the drop down in the lower right.            Check Connection on ThingWorx Server   Open the Composer window of your ThingWorx Foundation server and click on the browse folder icon, then Things.   You will see a Thing named "ESP8266Board-XXXX" with XXXX replaced by the last 4 digits of your boards WiFi MAC address. Click on the Thing then click the Properties and Alerts tab in the left column. Click the pencil "Set value" icon in the value column and enter a number in the text box. Click the "Check" button to set the value.   Open the Arduino Serial monitor window, and you will see the value you just entered on the platform shown in the serial output.   Step 4: Next Steps   Congratulations! You've successfully completed the Connect an Arduino Developer Board Quickstart.   This guide has given you the basic tools to:   Set up Arduino IDE Run Arduino demo Check connection on ThingWorx Server   Learn More   We recommend the following resources to continue your learning experience:    Capability Guide Connect Use REST API to Access ThingWorx Build Data Model Introduction   Additional Resources   If you have questions, issues, or need additional information, refer to:    Resource Link Community Developer Community Forum Support REST API Help Center
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This video is Module 11: ThingWorx Analytics Mashup Exercise of the ThingWorx Analytics Training videos. It shows you how to create a ThingWorx project and populate it with entities that collectively comprise a functioning application. 
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As of May 24, 2023, ThingWorx 9.4.0 is available for download!  Here are some of the highlights from the recent ThingWorx release.   What’s new in ThingWorx 9.4? Composer and Mashup Builder  New Combo chart and Pie chart based on modern Web Components architecture along with several other widget enhancements such as Grid toolbar improvements for custom actions, highlighting newly added rows for Grid widget and others Ability to style the focus on each widget when they are selected to get specific styling for different components Absolute positioning option with a beta flag to use by default is available now Several other Mashup improvements, such as Export function support is made available; improved migration dialogue (backported to 9.3 as well) to allow customers to move to new widgets; and legacy widgets language changes   Foundation  Heavily subscribed events could now be distributed across the ThingWorx HA cluster nodes to be scaled horizontally for better performance and processing of ThingWorx subscriptions. Azure Database for PostgreSQL Flex Server GA support with ThingWorx 9.4.1 for customers deploying ThingWorx Foundation on their own Azure Cloud infrastructure Improved ThingWorx APIs for InfluxDB to avoid Data loss at a high scale with additional monitoring metrics in place for guardrails Several security fixes and key third-party stack updates   Remote Access and Control (RAC) Remote Service Edge Extension (RSEE) for C-SDK, currently under Preview and planned to be Generally Available (GA) by Sept 2023, would allow ThingWorx admins to use Remote Access and Control with the C-SDK based connected devices to use Global Access Server (GAS) for a stable, secure, and large number of remote sessions With 9.4, a self-signed certificate or certificate generated by the trusted certificate authority can be used for RAC with the ThingWorx platform Ability to use parameter substitution to update Auto Launch commands dynamically based on data from the ThingWorx platform is now available   Software Content Management  Support for 100k+ assets with redesigned and improved performance on Asset Search Better control over package deployment with redesigned package tracking, filtering, and management Improved overall SCM stability, performance, and scalability and a more user-friendly and intuitive experience   Analytics  Improvements to the scalability of property transforms to enable stream processing of the larger number of properties within a ThingWorx installation Refactoring of Analytics Builder UI to use updated widgets and align with the PTC design system Updates to underlying libraries to enable the creation and scoring of predictive models in the latest version of PMML (v4.4) End of Support for Analytics Manager .NET Agent SDK     View release notes here and be sure to upgrade to 9.4!     Cheers, Ayush Tiwari Director, Product Management, ThingWorx      
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