Abstract: Automated development of an electronic data interchange (EDI) translator includes mapping, by a first machine learning model, source fields of documents formatted according to a first EDI format to destination fields of documents formatted according to a second EDI format. A mapping requirements specification is translated by a second machine learning model into code executable by a computer processor. A translation object is generated based on the mapping and translating. The translation object is used by an EDI translator that translates documents formatted according to the first EDI format into documents formatted according to the second EDI format is generated based on the mapping and translating.

Abstract: A system an input to receive a waveform signal, and one or more processors configured to execute code to cause the one or more processors to extract data bursts from the waveform signal, generate corresponding data vectors from the raw data for each data burst, and use machine learning to classify each data burst from the corresponding data vector. A method of classifying a data burst, comprising receiving an input waveform, extracting data bursts from the input waveform, deriving one or more spectral features of the data bursts, generating corresponding data vectors for each data burst from the one or more spectral features, and using machine learning to classify the data bursts from the corresponding data vectors.

Abstract: An integration flow segment is identified by receiving a start point and an end point in an integration flow in a web editor in a graphical user interface. The integration testing is simulated for the integration flow segment by providing a test payload in the web editor. A code segment corresponding to the integration flow segment is extracted. Based on the code segment, a runtime artifact is generated and deployed in a worker node hosting an integration runtime engine. The runtime artifact is loaded in a volatile memory corresponding to the worker node, and executed with the test payload in a worker node. The results of simulated integration testing are sent to the web editor. The runtime artifact is unloaded from the volatile memory. Results of the simulated integration testing are displayed at a visual proximity to sequence flows in the integration flow segment in the web editor.

Abstract: An integration flow segment is identified by receiving a start point and an end point in an integration flow in a web editor in a graphical user interface. The integration testing is simulated for the integration flow segment by providing a test payload in the web editor. A code segment corresponding to the integration flow segment is extracted. Based on the code segment, a runtime artifact is generated and deployed in a worker node hosting an integration runtime engine. The runtime artifact is loaded in a volatile memory corresponding to the worker node, and executed with the test payload in a worker node. The results of simulated integration testing are sent to the web editor. The runtime artifact is unloaded from the volatile memory. Results of the simulated integration testing are displayed at a visual proximity to sequence flows in the integration flow segment in the web editor.

Abstract: Various embodiments of systems and methods for distributed enterprise resource planning (ERP) are described herein. In one aspect, the method includes identifying one or more components of an enterprise resource planning system. A signal from one of the identified component is received. Based upon the received signal, a routine unit performs a task. The task includes at least one of updating a database table related to inventory of the ERP system, executing an application related to the ERP system to generate information to be sent to another identified component, and when the received signal includes data, transferring the data to another component of the identified one or more components.

Abstract: A method of securing a tire pressure-monitoring device to a vehicle wheel includes the steps of welding a bracket within a tire wheel well. The bracket assembly includes a weld surface that corresponds to a surface on the wheel rim. The weld surface includes a common curvature that matches the surface of the wheel and also includes a material compatible with welding to the wheel rim.

Abstract: A plastic air intake manifold is cleaned by a washer. The manifold is secured in a water tight chamber and immersed in water. Impellers in the chamber create turbulence in the water to remove oil and impurities located near the impellers. Air jets are activated to produce compressed air bubbles in the water which act abrasively to further clean the manifold. The water, impurities and oil are immediately removed from the chamber by a high power suction water outlet pump.

Abstract: A plurality of bosses on a lower manifold assembly are press fit into a plurality of holes in an active system body to form an air intake manifold assembly. Ultrasonic energy or heat is applied to the upper surface of the active system body proximate to each of the holes, slightly melting the outer surface of the bosses and the inner surface of the holes, creating a bond which secures the active system body to the lower manifold assembly. A compression seal can also be utilized to provide additional sealing.

Abstract: An improved method for forming cores to be utilized in a loss core plastic molding process includes the use of a flow meter. The flow meter ensures that sufficient molten metal is delivered into a cavity for the loss core elements. In this way, the present invention eliminates the occurrence of gaps, spaces or cavities in the molded loss core part. Most preferably a magnetic flow meter is utilized which can monitor the amount of molten metal having flown through the flow meter.

Abstract: A plastic air intake manifold is cleaned by a washer. The manifold is secured in a water tight chamber and immersed in water. Impellers in the chamber create turbulence in the water to remove oil and impurities located near the impellers. Air jets are activated to produce compressed air bubbles in the water which act abrasively to further clean the manifold. The water, impurities and oil are immediately removed from the chamber by a high power suction water outlet pump.