Honeywell International Inc. patent applications on February 6th, 2025
Patent Applications by Honeywell International Inc. on February 6th, 2025
Honeywell International Inc.: 21 patent applications
Honeywell International Inc. has applied for patents in the areas of H04L9/32 (4), B01J6/00 (2), G06F21/75 (2), G06F7/58 (2), A62B9/02 (1) H04L9/3278 (3), A62B9/022 (1), G06F21/75 (1), H04L9/3263 (1), H03K19/01806 (1)
With keywords such as: configured, output, puf, mems, fluid, device, circuit, transistor, input, and circuitry in patent application abstracts.
Patent Applications by Honeywell International Inc.
20250041633. BREATHING REGULATOR BOOST TUBE_simplified_abstract_(honeywell international inc.)
Inventor(s): David Alan Plummer of Marnhull (GB) for honeywell international inc.
IPC Code(s): A62B9/02, A62B7/00
CPC Code(s): A62B9/022
Abstract: a breathing system includes a pressurized fluid supply, a downstream breathing device, and a fluid regulator comprising. the fluid regulator includes an inlet in fluid connection with the fluid supply, and an outlet in fluid connection with a downstream breathing device. the fluid supply supplies fluid at a first pressure to the inlet, and the fluid is at a second pressure at the outlet that is lower than the first pressure. the fluid regulator also includes a boost tube disposed within an outlet portion of the fluid regulator. the boost tube includes a body defining a length and a plurality of apertures extending through the length of the body and configured to reduce the turbulence of the fluid flowing from the outlet to the downstream breathing device.
Inventor(s): Stephen Yates of South Barrington IL (US) for honeywell international inc., Amanda Childers of Arlington Heights IL (US) for honeywell international inc.
IPC Code(s): B01J8/26, B01J6/00, B01J8/02, B01J8/18, C25B1/04, C25B15/08
CPC Code(s): B01J8/26
Abstract: a system for generating a gas may include a pyrolysis reactor configured to pyrolyze a hydrocarbon to generate hydrogen and carbon. the pyrolysis reactor is further configured to contact the carbon with an agitated bed comprising metal oxide substrate particles to generate carbon-coated metal oxide particles. a technique for generating a gas may include agitating metal oxide substrate particles to form an agitated bed in a pyrolysis reactor. the technique may further include pyrolyzing, in the pyrolysis reactor, a hydrocarbon to generate hydrogen and carbon. the technique may further include contacting, in the pyrolysis reactor, the carbon with the agitated bed to generate carbon-coated metal oxide particles.
Inventor(s): JAYASENTHILNATHAN BALASUBRAMANIAN of Phoenix AZ (US) for honeywell international inc., EMMANUEL LETSU-DAKE of Phoenix AZ (US) for honeywell international inc., ROBERTO GUDINO of Phoenix AZ (US) for honeywell international inc.
IPC Code(s): B60L58/14, B60L15/20, B64D27/24, G01C21/34
CPC Code(s): B60L58/14
Abstract: embodiments of the present disclosure are directed to a vehicle battery situational awareness (vbsa) platform configured to monitor one or more vehicles. an onboard vbsa system associated with a vehicle is communicably coupled to a vehicle operations center associated with the vbsa platform and can monitor a current energy expenditure of the vehicle as the vehicle executes a trip plan. the onboard vbsa system can also determine that the current energy expenditure of the vehicle does not match a predicted energy expenditure. the onboard vbsa system can generate, based on output from a vehicle performance prediction model, a predicted energy overlay representing the predicted energy expenditure. the onboard vbsa system can also determine a safety boundary characterized by a maximum safe travel time. the onboard vbsa system can also cause display of the predicted energy overlay and the safety boundary on one or more computing devices.
Inventor(s): Dariia Averkova of Phoenix AZ (US) for honeywell international inc., Nichola Lubold of Phoenix AZ (US) for honeywell international inc.
IPC Code(s): B64D45/00, G06F3/0482, G06F3/0483, G06F3/0485, G06F9/451
CPC Code(s): B64D45/00
Abstract: an electronic checklist (ecl) system is disclosed. the ecl is configured to: generate an ecl display window, the ecl display window including an checklist information display panel and a checklist item display panel, the checklist information display panel having an annotations area and a virtual pilot area; populate the checklist item display panel with a plurality of checklist items from the ecl, wherein the checklist item display panel is scrollable to display checklist items from the ecl that occur earlier or later than a checklist item that is in focus; automatically populate the annotations area with information relating to a checklist item that is active; and cause the ecl display window to be displayed on the display device.
Inventor(s): Mehrad Mehr of Morristown NJ (US) for honeywell international inc., Robert Mantz of Clifton NJ (US) for honeywell international inc., Bahram Jadidian of Watchung NJ (US) for honeywell international inc.
IPC Code(s): C01B3/24, B01J6/00
CPC Code(s): C01B3/24
Abstract: a pyrolysis system for generating hydrogen gas by hydrocarbon pyrolysis may include a pyrolysis furnace and a heating system. the pyrolysis furnace may include a chamber defining a furnace interior. the chamber may include a thermal barrier. the heating system may include a heating element coupled to an electrical lead at a lead junction. the lead junction may be within the furnace interior. the electrical lead may include a refractory material. a maximum cross-sectional area of the electrical lead may be less than a minimum cross-sectional joule area of the heating element. a technique for assembling a system configured to generate hydrogen gas by hydrocarbon pyrolysis may include positioning the heating element within the furnace interior of the pyrolysis furnace, and coupling the electrical lead to the heating element at the lead junction within the furnace interior.
Inventor(s): Somraj SURESH of Charlotte NC (US) for honeywell international inc., Manjesh Kumar B of Charlotte NC (US) for honeywell international inc., Ian BENTLEY of Charlotte NC (US) for honeywell international inc., Josh M. FRIBLEY of Charlotte NC (US) for honeywell international inc., Kelong YAN of Charlotte NC (US) for honeywell international inc.
IPC Code(s): G01L19/06
CPC Code(s): G01L19/0645
Abstract: an example coupling mechanism for a media-isolated pressure sensor, method for manufacturing the coupling mechanism, and media-isolated pressure sensor are provided. the coupling mechanism includes a fluid coupling medium disposed in an interior cavity of a pressure sensor housing, forming a barrier between pressure sensing circuitry and a fluid. disposing the fluid coupling medium includes dispensing within the interior cavity, a first portion of a fluid coupling substance having a volume less than a maximum substance volume, and removing dissolved gas from within the first portion. disposing the fluid coupling medium further includes dispensing a second portion of the fluid coupling substance within the interior cavity, the second portion also having a volume less than the maximum substance volume. the fluid coupling substance is cured, forming a coupling mechanism, such that pressure sensing circuitry generates electrical signals based on pressure imposed by the fluid through the coupling mechanism.
20250044355. SWITCH WITH SERVICE LIFE INDICATOR_simplified_abstract_(honeywell international inc.)
Inventor(s): Fu XIANG of Charlotte NC (US) for honeywell international inc., Yongbing ZHU of Charlotte NC (US) for honeywell international inc., Bo ZHANG of Charlotte NC (US) for honeywell international inc., Xiao Lin BAI of Charlotte NC (US) for honeywell international inc., Xiaoqiang ZHANG of Charlotte NC (US) for honeywell international inc.
IPC Code(s): G01R31/327, G01R27/20, H01H1/00, H01H1/20, H01H3/12
CPC Code(s): G01R31/3275
Abstract: a switch is provided. the switch includes, but not limited to: normally open (no) terminals; normally closed (nc) terminals; an actuator, configured to conduct at least one of the no terminals and the nc terminals; an indicator for a remaining service life of the switch; and a controller component, configured to: determine the remaining service life of the switch based on a conduct resistance between at least one of the no terminals and the nc terminals, and control the indicator to illuminate a corresponding color based on the determined remaining service life of the switch.
Inventor(s): James Alexander Nicholls of Glendale AZ (US) for honeywell international inc., Laurentiu Mihai Gheorghe of Phoenix AZ (US) for honeywell international inc.
IPC Code(s): G01S19/48, G01C21/16
CPC Code(s): G01S19/48
Abstract: a vehicle having a doppler based cellular navigation system is provided. the vehicle includes a radio frequency (rf) antenna, an rf receiver in communication with the rf antenna, a memory and a controller. the memory includes a ground-based rf emitter database with ground-based rf emitter location information. the controller is in communication with the rf receiver and the memory. the controller is configured to monitor a doppler shift in received rf signals from ground-based rf emitters. the controller is further configured to determine location information when the controller detects a doppler shift in a received rf signal of zero. the controller is further configured to implement the determined location information in navigating a vehicle.
Inventor(s): James L. Tucker of Clearwater FL (US) for honeywell international inc.
IPC Code(s): G06F7/58
CPC Code(s): G06F7/588
Abstract: systems and methods for an active transistor rng circuit with mems entropy are described herein. in one example, an rng circuit includes one or more mems structures configured to provide an output, wherein the output includes active oscillations, charge, resistance, capacitance, and/or inductance values. the rng circuit further includes active transistor rng circuitry communicatively coupled to the one or more mems structures. the active transistor rng circuitry is configured to generate a random number output based on the output by the one or more mems structures. the random number output generated by the active transistor rng circuitry is an output of the rng circuit.
Inventor(s): Ricardo Banffy of DUBLIN (IE) for honeywell international inc.
IPC Code(s): G06F9/30, G06F11/34
CPC Code(s): G06F9/30145
Abstract: various embodiments relate to optimizing central processing unit (cpu) instruction flows based on performance-efficiency classifications for cpu instructions. in an implementation, a performance-efficiency classification for a cpu instruction is determined based on an instruction dependency between the cpu instruction and one or more other cpu instructions. additionally, a particular execution unit from a set of execution units that comprises a defined performance-efficiency classification corresponding to the performance-efficiency classification associated with the cpu instruction is determined and/or execution of the cpu instruction via the particular execution unit is caused.
Inventor(s): James L. Tucker of Clearwater FL (US) for honeywell international inc., Kenneth H. Heffner of Largo FL (US) for honeywell international inc., Peter L. Cousseau of Seattle WA (US) for honeywell international inc., Lee R. Wienkes of Minneapolis MN (US) for honeywell international inc., Donald Patrick Horkheimer of Minneapolis MN (US) for honeywell international inc.
IPC Code(s): G06F21/75, G06F21/72
CPC Code(s): G06F21/75
Abstract: a system is provided. the system includes a physical unclonable function (puf) circuit having an input, an output and an embedded microelectromechanical system (mems) device; and an interface, coupled to the puf circuit, and being configured to be coupled to a mechanical structure; wherein the embedded mems device is configured to detect a parameter or characteristic associated with the mechanical structure and to provide an input to the puf circuit based on the detected parameter, whereby the puf circuit uses the input from the embedded mems device to extend trust to the mechanical structure.
Inventor(s): Anushka Srivastava of Bengaluru (IN) for honeywell international inc., Rajesh Babu Nalukurthy of Atlanta GA (US) for honeywell international inc., Jesse J. Otis of North Haven CT (US) for honeywell international inc., Poshith Udayashankar of Bangalore (IN) for honeywell international inc., Vipin Das E K of Bengaluru (IN) for honeywell international inc.
IPC Code(s): G08B29/18, G08B17/06
CPC Code(s): G08B29/185
Abstract: one method includes identifying a fire event by analyzing sensor data from at least one sensor of a fire sensing device of a fire alarm subsystem at a facility being monitored by the fire alarm subsystem, after identifying the fire event by analyzing the sensor data from the at least one sensor of the fire sensing device, accessing data from at least one secondary subsystem to determine if the secondary subsystem data indicates the fire event is occurring, and if the fire event has been identified by analyzing the sensor data from the at least one sensor of the fire sensing device and data from at least one secondary subsystem indicates the fire event is occurring, then initiating an alarm to an emergency response center.
Inventor(s): Keith Braho of Murrysville PA (US) for honeywell international inc.
IPC Code(s): G10L15/14, G10L15/18
CPC Code(s): G10L15/14
Abstract: embodiments of the disclosure provide for adapting speech recognition confidence scores to one or more users based on expect response(s). some embodiments, receive input speech and generate, based on the input speech and using a recognition algorithm, a recognition hypothesis. the recognition hypothesis may comprise at least one pairing comprising a word and an initial confidence score associated with the word. some embodiments, determine whether the recognition hypothesis matches an expected response based at least in part on comparing the word to a corresponding word in an expected response. some embodiments, in response to determining that the recognition hypothesis matches the expected response, updates statistical data associated with the word.
20250047019. COMPLIANT PIN_simplified_abstract_(honeywell international inc.)
Inventor(s): Gangaraju R of Charlotte NC (US) for honeywell international inc., Thomas OLSON of Charlotte NC (US) for honeywell international inc., Jithun M of Charlotte NC (US) for honeywell international inc.
IPC Code(s): H01R12/58, H01R12/52, H05K1/14
CPC Code(s): H01R12/585
Abstract: a compliant pin including, but not limited to: a main section; and a first insertion section on a first end of the main section and configured to be inserted into a through-hole of a printed circuit board (pcb) to provide an electrical connection between the compliant pin and the pcb. the first insertion section includes, but not limited to: a contact portion; a first spring positioned, where the first spring is configured to be compressed during an insertion process and recover elasticity in an instance in which the first spring passes the through-hole of the pcb; and a second spring positioned, where in the instance in which the first spring passes the through-hole of the pcb, the second spring is configured to stop the first insertion section, and the first spring and the second spring constrain movement of the pcb.
Inventor(s): Sameer D. Manikfan of Hyderabad (IN) for honeywell international inc., Andrew J. Trenchard of Romsey (GB) for honeywell international inc.
IPC Code(s): H02J3/46, G06N3/08, H02J3/00
CPC Code(s): H02J3/466
Abstract: the method and system manages energy flows between an electrical grid and a plurality of microgrids that deploy at least one battery energy storage system, and which are controlled by a microgrid controller. a central controller receives electrical grid information from external sources and is arranged to generate an aggregate long-term schedule and an aggregate short-term schedule for energy flows and energy prices for the plurality microgrids connected to the central controller. a microgrid scheduler associated with each microgrid includes a long-term day(s) ahead scheduler that receives the aggregating long-term schedule and a short-term near real-time scheduler that receives the aggregate short-term schedule. the long-term day(s) ahead scheduler is arranged to generate a microgrid long-term schedule that controls energy flows between the electrical grid and each microgrid and its connected battery energy storage system that is corrected by a microgrid short-term near real-time schedule generated by the microgrid short-term near real-time scheduler.
Inventor(s): Ralf Heinrich Schröder genannt Berghegger of Glandorf (DE) for honeywell international inc.
IPC Code(s): H03K19/018, H03K17/30, H03K17/60, H03K19/084
CPC Code(s): H03K19/01806
Abstract: an electrical circuit and a method of operating the electrical circuit can include a group of transistors including one or more of a first transistor and a second transistor, wherein the first transistor is electronically connected to an input and an output of the electrical circuit, and the second transistor is electronically connected to the first transistor and the output. the electrical circuit can also include a group of resistors including a first base resistor and a second base resistor, wherein the first base resistor is electronically connected to a voltage supply, the first transistor, the second base resistor and one or more diodes. the electrical circuit may also include one or more capacitors electronically connected to the input, the first transistor, the second transistor, and the diode(s) and the output, such that an output voltage at the output is approximately double the supply voltage of the electrical circuit.
Inventor(s): Divya Swarup Giriyappa Srinivasan of Bangalore (IN) for honeywell international inc., John Azariah Rajadurai of Bangalore (IN) for honeywell international inc., Thomas D. Judd of Phoenix AZ (US) for honeywell international inc.
IPC Code(s): H04L9/32
CPC Code(s): H04L9/3263
Abstract: techniques are provided for facilitating less expensive and more rapid implement and modification of processes, e.g., communications processes, performed in a vehicle, e.g., a commercial aircraft, by implementing those functions on a non-certified computer. this is because the non-certified computer and the functions which it performs do not require certification by a government entity. optionally, the non-certified computer is communicatively coupled to a communications management unit which requires certification from the government entity. optionally, the non-certified computer may be an electronic flight bag for commercial aviation applications.
Inventor(s): Kenneth H. Heffner of Largo FL (US) for honeywell international inc., Peter L. Cousseau of Seattle WA (US) for honeywell international inc., James L. Tucker of Clearwater FL (US) for honeywell international inc., Donald Patrick Horkheimer of Minneapolis MN (US) for honeywell international inc.
IPC Code(s): H04L9/32, B81B3/00, H04L9/08
CPC Code(s): H04L9/3278
Abstract: a system that includes: a microelectromechanical system (mems) device for generating an output signal at an output of the mems device, the mems device receiving at least one input signal at an input of the mems device; a storage medium configured to store a signal injection function and an output generation function; and a processor, in communication with the mems device and the storage medium, the processor configured to run the signal injection function to selectively modify the at least one input signal to produce a modified input signal and to provide the modified input signal to the input of the mems device, and that is configured to run an output generation function to extract a random component and a unique component from the output signal, wherein the random component and the unique component are generated by the mems device based on the modified at least one input signal.
Inventor(s): James L. Tucker of Clearwater FL (US) for honeywell international inc., Kenneth H. Heffner of Largo FL (US) for honeywell international inc., Peter L. Cousseau of Seattle WA (US) for honeywell international inc., Donald Patrick Horkheimer of Minneapolis MN (US) for honeywell international inc.
IPC Code(s): H04L9/32, G06F7/58, G06F21/75
CPC Code(s): H04L9/3278
Abstract: systems and methods for codependent physical unclonable function (puf)/random number generator (rng) generator pairing for physical provenance are described herein. in one example a device includes physical unclonable function (puf) circuitry configured to produce a puf output in response to an input and random number generator (rng) circuitry configured to output one or more random numbers. the puf circuitry and the rng circuitry share one or more components such that an alteration of the rng circuitry alters the puf circuitry. the device is configured to determine whether the rng circuitry is an untainted source of random numbers based on an output of the puf circuitry.
Inventor(s): James L. Tucker of Clearwater FL (US) for honeywell international inc.
IPC Code(s): H04L9/32, B81B7/02, H03K3/03
CPC Code(s): H04L9/3278
Abstract: systems and methods for an active transistor puf circuit with mems uniqueness are described herein. in one example, a puf circuit includes one or more mems structures configured to provide an output, wherein the output includes active oscillations, charge, resistance, inductance, and/or capacitance values. the puf circuit further includes active transistor puf circuitry communicatively coupled to the one or more mems structures. the active transistor puf circuitry is configured to receive a challenge input and generate a puf response in response to the challenge input. the puf response is generated based on the output provided by the one or more mems structures and manufacturing variation in components of the active transistor puf circuitry. the puf response generated by the active transistor puf circuitry is an output of the puf circuit.
Inventor(s): Ved Gund of Plymouth MN (US) for honeywell international inc.
IPC Code(s): H10B99/00
CPC Code(s): H10B99/14
Abstract: a computational device includes a phase-change material (pcm) variable microelectromechanical systems (mems) capacitor and a power source. the pcm variable mems capacitor includes a substrate, a first electrode, a second electrode, a pcm, and a heater. the first electrode is spaced apart from the substrate to define a pcm cavity. the second electrode is spaced apart from the first electrode to define a capacitance gap. the pcm is disposed within the pcm cavity. the heater element is coupled to receive a voltage pulse, whereby a temperature of the pcm varies to thereby vary the capacitance gap. the power source is coupled to the pcm variable mems capacitor and is operable to (i) supply the voltage pulse to the heater and (ii) a time-dependent voltage between the first electrode and the second electrode, to thereby implement a single multiply operation.
Honeywell International Inc. patent applications on February 6th, 2025
- Honeywell International Inc.
- A62B9/02
- A62B7/00
- CPC A62B9/022
- Honeywell international inc.
- B01J8/26
- B01J6/00
- B01J8/02
- B01J8/18
- C25B1/04
- C25B15/08
- CPC B01J8/26
- B60L58/14
- B60L15/20
- B64D27/24
- G01C21/34
- CPC B60L58/14
- B64D45/00
- G06F3/0482
- G06F3/0483
- G06F3/0485
- G06F9/451
- CPC B64D45/00
- C01B3/24
- CPC C01B3/24
- G01L19/06
- CPC G01L19/0645
- G01R31/327
- G01R27/20
- H01H1/00
- H01H1/20
- H01H3/12
- CPC G01R31/3275
- G01S19/48
- G01C21/16
- CPC G01S19/48
- G06F7/58
- CPC G06F7/588
- G06F9/30
- G06F11/34
- CPC G06F9/30145
- G06F21/75
- G06F21/72
- CPC G06F21/75
- G08B29/18
- G08B17/06
- CPC G08B29/185
- G10L15/14
- G10L15/18
- CPC G10L15/14
- H01R12/58
- H01R12/52
- H05K1/14
- CPC H01R12/585
- H02J3/46
- G06N3/08
- H02J3/00
- CPC H02J3/466
- H03K19/018
- H03K17/30
- H03K17/60
- H03K19/084
- CPC H03K19/01806
- H04L9/32
- CPC H04L9/3263
- B81B3/00
- H04L9/08
- CPC H04L9/3278
- B81B7/02
- H03K3/03
- H10B99/00
- CPC H10B99/14