Patents by Inventor Andrew Phelps Day
Andrew Phelps Day has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
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Patent number: 10964426Abstract: Certain examples provide systems and methods to monitor and control hospital operational systems based on occupancy data and medical orders. An example healthcare workflow management and reasoning system includes a workflow engine including a first particularly programmed processor to monitor one or more medical orders from one or more hospital information systems to identify a condition indicating that a first patient in a first room is ready for a clinical activity such as discharge. The example healthcare workflow management and reasoning system includes a sensing component including a second processor to gather occupancy data regarding the first patient in the first room and transmit the occupancy data to the workflow engine. The example workflow engine controls one or more hospital operational systems to trigger cleaning of the first room, lighting settings for the first room, and transportation of a second patient to the first room based on occupancy data from the sensing component.Type: GrantFiled: October 16, 2015Date of Patent: March 30, 2021Assignee: General Electric CompanyInventors: Christopher Donald Johnson, Brandon Stephen Good, Andrew Phelps Day, David S. Toledano, Yang Zhao, Jeffrey Richardson Terry
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Publication number: 20200337628Abstract: The present disclosure relates to the reduction of pressure ulcers and falls with respect to patients with physical or cognitive impairments who are in bed. A control system assures that the bed and ancillary apparatus are physically set and that patient behaviors are responded to by care providers. Motion is monitored with a non-mutually exclusive portfolio of sensors, and this information is used by one or more reasoning engines. An integrated clinical workflow is informed by the patterns of movement and then the physical environment, patient interaction, and care provider workflow are controlled to reduce the incidence of falls and pressure ulcers in bed ridden patients.Type: ApplicationFiled: June 15, 2020Publication date: October 29, 2020Inventors: Christopher Donald Johnson, Peter Henry Tu, Andrew Phelps Day, Ting Yu
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Patent number: 10682090Abstract: The present disclosure relates to the reduction of pressure ulcers and falls with respect to patients with physical or cognitive impairments who are in bed. A control system assures that the bed and ancillary apparatus are physically set and that patient behaviors are responded to by care providers. Motion is monitored with a non-mutually exclusive portfolio of sensors, and this information is used by one or more reasoning engines. An integrated clinical workflow is informed by the patterns of movement and then the physical environment, patient interaction, and care provider workflow are controlled to reduce the incidence of falls and pressure ulcers in bed ridden patients.Type: GrantFiled: June 29, 2016Date of Patent: June 16, 2020Assignee: General Electric CompanyInventors: Christopher Donald Johnson, Peter Henry Tu, Andrew Phelps Day, Ting Yu
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Patent number: 10679754Abstract: An example method includes: classifying lung function risk based on patient attributes and a clinical protocol; generating alarms and incentives for compliance with the clinical protocol based on patient attributes, clinical protocol, and patient lung function risk; determining an orientation and position of a clinical device based on tagged feature(s) of the clinical device compared to identified patient feature(s); monitoring patient interaction with the clinical device; identifying a deviation from the clinical protocol based on the monitored patient interaction, a patient biometric indicator, and a desired setpoint state in the protocol; when a deviation is identified, providing feedback proportional to the deviation, the feedback including an adjustment with respect to the clinical protocol and/or the clinical device; and triggering at least one alarm and/or incentive based on deviation and feedback, wherein the alarm/incentives differs based on whether and to what extent deviation is identified and feedType: GrantFiled: July 25, 2018Date of Patent: June 9, 2020Assignee: General Electric CompanyInventors: Christopher Donald Johnson, Peter Henry Tu, Andrew Phelps Day, Ting Yu, Jeffrey Richardson Terry
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Publication number: 20180330827Abstract: An example method includes: classifying lung function risk based on patient attributes and a clinical protocol; generating alarms and incentives for compliance with the clinical protocol based on patient attributes, clinical protocol, and patient lung function risk; determining an orientation and position of a clinical device based on tagged feature(s) of the clinical device compared to identified patient feature(s); monitoring patient interaction with the clinical device; identifying a deviation from the clinical protocol based on the monitored patient interaction, a patient biometric indicator, and a desired setpoint state in the protocol; when a deviation is identified, providing feedback proportional to the deviation, the feedback including an adjustment with respect to the clinical protocol and/or the clinical device; and triggering at least one alarm and/or incentive based on deviation and feedback, wherein the alarm/incentives differs based on whether and to what extent deviation is identified and feedType: ApplicationFiled: July 25, 2018Publication date: November 15, 2018Inventors: Christopher Donald Johnson, Peter Henry Tu, Andrew Phelps Day, Ting Yu, Jeffrey Richardson Terry
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Patent number: 10061897Abstract: An example method includes: classifying lung function risk based on patient attributes and a clinical protocol; generating alarms and incentives for compliance with the clinical protocol based on patient attributes, clinical protocol, and patient lung function risk; determining an orientation and position of a clinical device based on tagged feature(s) of the clinical device compared to identified patient feature(s); monitoring patient interaction with the clinical device; identifying a deviation from the clinical protocol based on the monitored patient interaction, a patient biometric indicator, and a desired setpoint state in the protocol; when a deviation is identified, providing feedback proportional to the deviation, the feedback including an adjustment with respect to the clinical protocol and/or the clinical device; and triggering at least one alarm and/or incentive based on deviation and feedback, wherein the alarm/incentives differs based on whether and to what extent deviation is identified and feedType: GrantFiled: June 11, 2015Date of Patent: August 28, 2018Assignee: General Electric CompanyInventors: Christopher Donald Johnson, Peter Henry Tu, Andrew Phelps Day, Ting Yu, Jeffrey Richardson Terry
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Publication number: 20180000407Abstract: The present disclosure relates to the reduction of pressure ulcers and falls with respect to patients with physical or cognitive impairments who are in bed. A control system assures that the bed and ancillary apparatus are physically set and that patient behaviors are responded to by care providers. Motion is monitored with a non-mutually exclusive portfolio of sensors, and this information is used by one or more reasoning engines. An integrated clinical workflow is informed by the patterns of movement and then the physical environment, patient interaction, and care provider workflow are controlled to reduce the incidence of falls and pressure ulcers in bed ridden patients.Type: ApplicationFiled: June 29, 2016Publication date: January 4, 2018Inventors: Christopher Donald Johnson, Peter Henry Tu, Andrew Phelps Day, Ting Yu
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Publication number: 20170109481Abstract: Certain examples provide systems and methods to monitor and control hospital operational systems based on occupancy data and medical orders. An example healthcare workflow management and reasoning system includes a workflow engine including a first particularly programmed processor to monitor one or more medical orders from one or more hospital information systems to identify a condition indicating that a first patient in a first room is ready for a clinical activity such as discharge. The example healthcare workflow management and reasoning system includes a sensing component including a second processor to gather occupancy data regarding the first patient in the first room and transmit the occupancy data to the workflow engine. The example workflow engine controls one or more hospital operational systems to trigger cleaning of the first room, lighting settings for the first room, and transportation of a second patient to the first room based on occupancy data from the sensing component.Type: ApplicationFiled: October 16, 2015Publication date: April 20, 2017Inventors: Christopher Donald Johnson, Brandon Stephen Good, Andrew Phelps Day, David S. Toledano, Yang Zhao, Jeffrey Richardson Terry
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Publication number: 20150363566Abstract: An example method includes: classifying lung function risk based on patient attributes and a clinical protocol; generating alarms and incentives for compliance with the clinical protocol based on patient attributes, clinical protocol, and patient lung function risk; determining an orientation and position of a clinical device based on tagged feature(s) of the clinical device compared to identified patient feature(s); monitoring patient interaction with the clinical device; identifying a deviation from the clinical protocol based on the monitored patient interaction, a patient biometric indicator, and a desired setpoint state in the protocol; when a deviation is identified, providing feedback proportional to the deviation, the feedback including an adjustment with respect to the clinical protocol and/or the clinical device; and triggering at least one alarm and/or incentive based on deviation and feedback, wherein the alarm/incentives differs based on whether and to what extent deviation is identified and feedType: ApplicationFiled: June 11, 2015Publication date: December 17, 2015Inventors: Christopher Donald Johnson, Peter Henry Tu, Andrew Phelps Day, Ting Yu, Jeffrey Richardson Terry
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Publication number: 20140108033Abstract: Snapshot data may be received indicative of a current state of resources that deliver healthcare to a plurality of patients associated with a healthcare enterprise. The received snapshot data may be automatically used to initialize a healthcare enterprise simulation model. The healthcare enterprise simulation model may then be executed to automatically generate a predicted future state of the resources at a predetermined point in time. Some embodiments may automatically suggest mitigation strategies based on simulated scenarios reflecting potential bottlenecks and appropriate actions that may be taken by the enterprise. The system may continuously and automatically monitor forecast accuracy to detect potential anomalies.Type: ApplicationFiled: September 17, 2013Publication date: April 17, 2014Inventors: Kunter Seref Akbay, Christopher Donald Johnson, Angela Neff Patterson, Andrew Phelps Day, Ilkin Onur Dulgeroglu, David S. Toledano, Bex George Thomas, Dan Yang, Peter Leigh Katlic, Marcia Peterson
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Publication number: 20140108034Abstract: Current resource data may be continuously and automatically received indicative of a current state of resources that are used to deliver healthcare to a plurality of patients associated with a healthcare enterprise. The current resource data may be automatically used to update a healthcare enterprise simulation model. The healthcare enterprise simulation model may be executed to automatically generate a predicted future state of the resources. A resource request may then be received, and a resource assignment engine may automatically assign a particular resource to the resource request based at least in part on the predicted future state of the resources.Type: ApplicationFiled: October 2, 2013Publication date: April 17, 2014Inventors: Kunter Seref Akbay, Srinivas Bollapragada, Andrew Phelps Day, Ilkin Onur Dulgeroglu, David S. Toledano, Bex George Thomas, Marcia Peterson, Dan Yang
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Publication number: 20140108035Abstract: According to some embodiments, first current resource data indicative of a current state of first resources that are used to deliver healthcare to a plurality of patients associated with a first healthcare enterprise is continuously and automatically received. The first current resource data may be automatically used to update a healthcare enterprise simulation model. The healthcare enterprise simulation model may automatically generate a predicted future state of the first resources, wherein the predicted future state of the first resources is based at least in part on second resource data indicative of a state of second resources that are used to deliver healthcare to a plurality of patients associated with a second healthcare enterprise remote from and networked with the first healthcare enterprise.Type: ApplicationFiled: October 2, 2013Publication date: April 17, 2014Inventors: Kunter Seref Akbay, Srinivas Bollapragada, Andrew Phelps Day, Ilkin Onur Dulgeroglu, David S. Toledano, Bex George Thomas, Peter Leigh Katlic, Manmeet Singh, Marcia Peterson