DIAGNOSTIC CIRCUIT

Organization Name

The Boeing Company

Inventor(s)

Ian M. Dayton of Annapolis Junction MD (US)

Mark Edward Nowakowski of Huntington Beach CA (US)

DIAGNOSTIC CIRCUIT - A simplified explanation of the abstract

This abstract first appeared for US patent application 18045517 titled 'DIAGNOSTIC CIRCUIT

Simplified Explanation

The diagnostic circuit described in the abstract includes two superconducting quantum interference devices (SQUIDs) that are inductively coupled to an input port. The first SQUID generates a first output voltage based on the input current being above or below a certain threshold, while the second SQUID generates a second output voltage based on a different threshold.

• The diagnostic circuit includes an input port for receiving an input current.
• A first SQUID is inductively coupled to the input port and generates a first output voltage based on the input current crossing a first threshold.
• A second SQUID is also inductively coupled to the input port and generates a second output voltage based on the input current crossing a second threshold.

Potential Applications

The technology described in this patent application could be used in various medical devices for detecting and monitoring biological signals, such as brain activity or heart rhythms. It could also be applied in scientific instruments for precise measurements of small currents.

Problems Solved

This technology solves the problem of accurately detecting and measuring small currents in a reliable and efficient manner. It provides a way to differentiate between different levels of input current and generate corresponding output voltages.

Benefits

The benefits of this technology include high sensitivity, fast response times, and low noise levels in detecting and measuring input currents. It offers a compact and efficient solution for diagnostic circuits requiring precise current detection.

Potential Commercial Applications

• Medical devices for monitoring biological signals
• Scientific instruments for precise current measurements

Possible Prior Art

One possible prior art for this technology could be the use of SQUIDs in medical imaging devices for detecting magnetic fields in the body. Another could be the application of SQUIDs in sensitive magnetometers for geophysical exploration.

Unanswered Questions

How does the diagnostic circuit handle variations in input current over time?

The article does not provide information on how the diagnostic circuit compensates for fluctuations in input current that may occur during operation.

What is the power consumption of the diagnostic circuit?

The article does not mention the power requirements or consumption of the diagnostic circuit, which could be important for practical applications.

Original Abstract Submitted

A diagnostic circuit includes an input port configured to receive an input current and a first superconducting quantum interference device (SQUID) inductively coupled to the input port. The first SQUID is configured to generate a first output in the form of: a first voltage in response to the input current being less than a first threshold current and a second voltage in response to the input current being greater than the first threshold current. The diagnostic circuit also includes a second SQUID inductively coupled to the input port. The second SQUID is configured to generate a second output in the form of: a third voltage in response to the input current being less than a second threshold current and a fourth voltage in response to the input current being greater than the second threshold current.