METHOD FOR PROCESSING INPUT VARIABLES BY MEANS OF A PROCESSING DEVICE HAVING AT LEAST ONE TRANSISTOR, DEVICE FOR EXECUTING THE METHOD, COMPUTING DEVICE AND USE

Organization Name

Robert Bosch GmbH

Inventor(s)

Taha Soliman of Renningen (DE)

Tobias Kirchner of Ludwigsburg (DE)

METHOD FOR PROCESSING INPUT VARIABLES BY MEANS OF A PROCESSING DEVICE HAVING AT LEAST ONE TRANSISTOR, DEVICE FOR EXECUTING THE METHOD, COMPUTING DEVICE AND USE - A simplified explanation of the abstract

This abstract first appeared for US patent application 18600281 titled 'METHOD FOR PROCESSING INPUT VARIABLES BY MEANS OF A PROCESSING DEVICE HAVING AT LEAST ONE TRANSISTOR, DEVICE FOR EXECUTING THE METHOD, COMPUTING DEVICE AND USE

The abstract describes a method for processing input variables using a processing device with at least a first transistor and a first memristive element. The method involves influencing the charging current of a capacitance associated with the control electrode of the first transistor using the first memristive element, applying a first output variable to the control electrode, and determining an output variable based on the product of the input variables.

• The method involves utilizing a first transistor and a first memristive element to process input variables.
• The first memristive element influences the charging current of a capacitance associated with the control electrode of the first transistor.
• A first output variable characterizing a second input variable is applied to the control electrode.
• The method determines an output variable based on the product of the first and second input variables.
• The method utilizes a variable characterizing the time profile of a current through a load path of the first transistor.

Potential Applications: - This method could be applied in electronic circuits for signal processing and data manipulation. - It could be used in sensor technologies for processing sensor data efficiently. - This method may find applications in artificial intelligence systems for optimizing data processing.

Problems Solved: - Efficient processing of input variables using a combination of a transistor and a memristive element. - Improved control over the charging current of a transistor's capacitance. - Enhanced capability to determine output variables based on the product of input variables.

Benefits: - Increased efficiency in processing input variables. - Enhanced control and manipulation of data in electronic systems. - Potential for improved performance in various applications requiring data processing.

Commercial Applications: Title: Advanced Data Processing Method for Electronic Systems This technology could be utilized in the development of advanced electronic devices for various industries such as telecommunications, computing, and automation. The method's ability to efficiently process input variables and determine output variables based on specific criteria could lead to improved performance and functionality in commercial electronic systems.

Questions about the technology: 1. How does the method optimize the processing of input variables in electronic systems? 2. What are the potential implications of using a memristive element in conjunction with a transistor for data processing efficiency?

Original Abstract Submitted

A method for processing input variables by means of a processing device having least a first transistor. The method including: providing the first transistor and a first memristive element, which characterizes a first input variable associated with the first transistor, wherein a charging current of a capacitance associated with a control electrode of the first transistor can be influenced using the first memristive element; applying to the control electrode of the first transistor a first output variable which characterizes a second input variable associated with the first transistor; ascertaining a first output variable which characterizes at least one product of the first input variable and of the second input variable, based on a first variable characterizing a time profile of a current through a load path of the first transistor.