Prosecution Insights
Last updated: July 05, 2026
Application No. 18/724,597

INFORMATION PROCESSING DEVICE, INFORMATION PROCESSING METHOD, AND PROGRAM

Final Rejection §103
Filed
Jun 26, 2024
Priority
Dec 27, 2021 — nonprovisional of PCTJP2021048558
Examiner
PALL, CHARLES J
Art Unit
3663
Tech Center
3600 — Transportation & Electronic Commerce
Assignee
Nabla Mobility Inc.
OA Round
2 (Final)
54%
Grant Probability
Moderate
3-4
OA Rounds
1y 2m
Est. Remaining
72%
With Interview

Examiner Intelligence

Grants 54% of resolved cases
54%
Career Allowance Rate
78 granted / 143 resolved
+2.5% vs TC avg
Strong +17% interview lift
Without
With
+17.2%
Interview Lift
resolved cases with interview
Typical timeline
3y 3m
Avg Prosecution
20 currently pending
Career history
181
Total Applications
across all art units

Statute-Specific Performance

§101
1.7%
-38.3% vs TC avg
§103
92.2%
+52.2% vs TC avg
§102
1.2%
-38.8% vs TC avg
§112
4.1%
-35.9% vs TC avg
Black line = Tech Center average estimate • Based on career data from 143 resolved cases

Office Action

§103
DETAILED ACTION Notice of Pre-AIA or AIA Status The present application, filed on or after March 16, 2013, is being examined under the first inventor to file provisions of the AIA . Status of Claims Claims 1, 6-13, 15-21, and 23-27 are pending in this application. Claims 1, 6-13 and 15-21 are presented as currently amended claims. No claims are presented as original claims. Claims 23-27 are newly presented. Claims 2-5, 14 and 22 are newly cancelled. Examiner's Note Examiner has cited particular paragraphs / columns and line numbers or figures in the references as applied to the claims below for the convenience of the applicant. Although the specified citations are representative of the teachings in the art and are applied to the specific limitations within the individual claim, other passages and figures may apply as well. It is respectfully requested from the applicant, in preparing the responses, to fully consider the references in entirety as potentially teaching all or part of the claimed invention, as well as the context of the passage as taught by the prior art or disclosed by the examiner. Applicant is reminded that the Examiner is entitled to give the broadest reasonable interpretation to the language of the claims. Furthermore, the Examiner is not limited to Applicants’ definition which is not specifically set forth in the claims. Claim Objections The numbering of claims is not in accordance with 37 CFR 1.126 which requires the original numbering of the claims to be preserved throughout the prosecution. When claims are canceled, the remaining claims must not be renumbered. When new claims are presented, they must be numbered consecutively beginning with the number next following the highest numbered claims previously presented (whether entered or not). The second of the two claims both misnumbered as claim 23 has renumbered as 27. Claim Rejections - 35 USC § 103 The text of those sections of Title 35, U.S. Code not included in this action can be found in a prior Office action. This application currently names joint inventors. In considering patentability of the claims the examiner presumes that the subject matter of the various claims was commonly owned as of the effective filing date of the claimed invention(s) absent any evidence to the contrary. Applicant is advised of the obligation under 37 CFR 1.56 to point out the inventor and effective filing dates of each claim that was not commonly owned as of the effective filing date of the later invention in order for the examiner to consider the applicability of 35 U.S.C. 102(b)(2)(C) for any potential 35 U.S.C. 102(a)(2) prior art against the later invention. Claims 1, 6, 8-13, 15-21, 23-27 are rejected under 35 U.S.C. 103 as being unpatentable over Gibbons et al. (US 20210383708 A1) in view of Tran et al. (US 20210089134 A1) in view of Nathan et al. (US 20210020049 A1) (the combination of which is referred to as “combination Gibbons” hereinafter) Regarding claim 1, Gibbons teaches an information processing device comprising: a processor; and a non-transitory memory storing a program, wherein: the program, when executed by the processor, causes the processor to perform operations including: (Gibbons: ¶ 012; instructions may be executed by an electronic processor) (i) acquiringa target aircraft; (Gibbons: ¶ 010; a measurement of a weather system or event may comprise a wind velocity or other characteristic of the event and be measured by a sensor on the other aircraft and automatically provided to aircraft expected to encounter the weather system or event.) (Gibbons: ¶¶ 135-137; in each of a plurality of aircraft to: Acquire current data, information, etc. regarding weather conditions along a flightpath and within a certain range around the flightpath (as suggested by module 406); this may include measurements from on-board sensors) (Gibbons: ¶ 138; application at the ground-based server to process the received weather-related data, information, etc. (if needed) and execute logic to determine which aircraft/pilots to communicate with regarding a specific weather system or event) (ii) acquiring, through a wireless network, other aircraft information regarding another aircraft different from the target aircraft, the other aircraft information comprising atmospheric information; (Gibbons: ¶ 115; collect weather-related data and information from a plurality of aircraft that have encountered or flown nearby weather systems and events while flying along their flight trajectory)(Gibbons: ¶ 077; information, etc. obtained from the other aircraft may be used to generate the overlay(s), where the overlay(s) may indicate one or more of: [0078] A general shape of a weather system or event in relation to the aircraft's current trajectory (where the trajectory is indicated by waypoints, altitudes, airspeed, etc.)) (iii) acquiring weather information regarding an atmospheric condition at different altitudes in an airspace regarding a flight path of the target aircraft, (Gibbons: ¶ 117; server receives data, information, etc. from a plurality of aircraft [which is] provided to and used by aircraft that are expected to encounter or be impacted by one of the weather systems)(Gibbons: ¶ 118-119; identify a location of a weather system or event for which it has received data, information . . . this information may be relevant to pilots in front of and behind a weather system) . . . (iv) acquiring one or more candidate fight paths based on the condition information, the other aircraft information and the weather information; (Gibbons: ¶¶ 119-120; determine one or more aircraft that may be expected to encounter or be impacted by a weather system or event for which data, information, etc., has been received (as suggested by step or stage 438); this may include accessing a database or other source of information regarding the planned flight trajectories of a plurality of aircraft expected to be airborne during a specified period and/or within a specific region) (Gibbons: ¶ 009; overlay or overlays may include indications of weather systems, weather events, observations or measurements provided by other aircraft, and in some embodiments, suggested route changes to avoid or minimize the impact of a weather system or event.) (Gibbons: ¶ 131; whether the reported or predicted weather system or event is present along the flightpath.) (Gibbons: ¶ 115; collect weather-related data and information from a plurality of aircraft that have encountered or flown nearby weather systems and events while flying along their flight trajectory) (Gibbons: ¶ 119; this information may be relevant to pilots in front of and behind a weather system or event due to considerations of turbulence, headwinds, tailwinds, etc;). . . (vii) transmitting, through the wireless network, the recommended flight path information (Gibbons: ¶ 019; if the crew member accepts the received data and information, then to generate one or more displays showing the trajectory of the selected aircraft and the weather system or event in relation to the trajectory.) to an electronic flight bay (EFB) of the target aircraft (Gibbons: ¶ 055; Electronic Flight Bag [operates] TAP [which] is a subset of the overall system and is where the route change recommendations are generated. A pilot interfaces with TAP through a user interface. TAP and the user interface can be co-resident)such that a pilot of the target aircraft determines whether to change the flight path (Gibbons: ¶ 101; a set of user interface elements to permit a user to change information regarding an aircraft's heading or altitude and in response to be able to examine the current weather system information and weather events based on those changes) To the extent Gibbon is silent about or does not Gibbons teach: the weather information being acquired by performing machine learning based on forecast information and the atmospheric information acquired by the another aircraft; Tran does teach: the weather information being acquired by performing machine learning based on forecast information and the atmospheric information acquired by the another aircraft; (Tran: ¶ 142; encoder learns from the flight plan and the decoder integrates the weather information and recursively “translates” the embedded flight plan information into a full 4D trajectory. Convolution layers can be used into the decoder network pipeline to extract representations from the high-dimension weather features) Before the effective filling date of the claimed invention, it would have been obvious to one of ordinary skill in the art to combine the teachings of Tran with the teachings of Gibbon because doing so would result in the predicable benefit of allowing better “route optimization while avoiding the negative impact of the weather event” (Tran: ¶ 075). To the extent Gibbon is silent about or does not Gibbons teach: (v) calculating a score for each of the one or more candidate paths based on an objective function relating to at least one of fuel consumption, operational cost, safety index or required time; Nathan does teach: (v) calculating a score for each of the one or more candidate paths based on an objective function relating to at least one of fuel consumption, operational cost, safety index or required time; (Nathan: ¶ 073; process of selecting the optimal alternate flight path may be performed by a cost-optimization process based on one or a plurality of factors, such as the (estimated) fuel expenditure and flight time required by each of the plurality of alternate flight paths. In certain embodiments, the cost-optimization process may consider either fuel expenditure or flight time as the main consideration) (vi) selecting a recommended flight path information for the target aircraft based on the score, (Nathan: ¶ 035; constructing a plurality of alternate flight paths around the zone of avoidance based on the safety envelope (operation 304); determining an optimal flight path from among the plurality of alternate flight paths) the recommended flight path information comprising altitude information; (Nathan: ¶ 074; Fuel expenditure and flight time may be estimated based on any or combination of suitable factors, such as the characteristics of the aircraft (e.g., weight), the altitude of the alternate flight path) Before the effective filling date of the claimed invention, it would have been obvious to one of ordinary skill in the art to combine the teachings of Nathan with the teachings of Gibbon because doing so would result in the predicable benefit of selecting the “economically optimal [flight path] among the candidate alternate flight paths. . ..” Nathan: ¶ 022). Regarding claim 6, as detailed above, combination Gibbons teaches the invention as detailed with respect to claim 1. Nathan teaches: wherein the recommended flight path information is selected to minimize fuel consumption of the target aircraft or(Nathan: ¶ 073; process of selecting the optimal alternate flight path may be performed by a cost-optimization process based on one or a plurality of factors, such as the (estimated) fuel expenditure and flight time required by each of the plurality of alternate flight paths. In certain embodiments, the cost-optimization process may consider either fuel expenditure or flight time as the main consideration) Regarding claim 8, as detailed above, combination Gibbons teaches the invention as detailed with respect to claim 1. Nathan further teaches: wherein: the operations further comprises acquiring allowed airspace where the target aircraft is allowed to fly, (Nathan: ¶ 002; Aircraft traveling on a flight path may encounter hazards or airspace restrictions, . . . no-fly zones . . . If a zone of avoidance is ahead on the aircraft's current flight path, then the aircraft may need to find an alternate path around the zone.) and the score is calculated using the allowed airspace information. (Nathan: ¶ 035; constructing a plurality of alternate flight paths around the zone of avoidance based on the safety envelope (operation 304); determining an optimal flight path from among the plurality of alternate flight paths) ((Nathan: ¶ 074; Fuel expenditure and flight time may be estimated) Regarding claim 9, as detailed above, combination Gibbons teaches the invention as detailed with respect to claim 1. Gibbons does not explicitly teach: the other aircraft information comprises information regarding positions of one or more other aircrafts after a specified time has elapsed, the operations comprises acquiring information regarding the positions of the other aircraft after a specified time has elapsed based on information regarding the positions of the one or more other aircrafts; however, Nathan does teach: A system in which information regarding the positions of the other aircraft wherein the aircraft information comprises information regarding positions of one or more other aircrafts is continuously acquired and used to update flight routing. (Nathan: ¶ 038; reflectivity data may be adjusted to account for movement of the aircraft 210. The computer system 211 may store the reflectivity data obtained in a memory of the computer system 211. The memory may be continuously updated with data from the radar so that the data is up-to-date whenever computation of an alternate flight path around a zone of avoidance is performed.) Therefore, before the effective filling date of the claimed invention, it would have been obvious to one of ordinary skill that Nathan teaches or suggests the other aircraft information comprises information regarding positions of one or more other aircrafts after a specified time has elapsed, the operations comprises acquiring information regarding the positions of the other aircraft after a specified time has elapsed based on information regarding the positions of the one or more other aircrafts because a person of ordinary skill in the art would recognize that radar data is provided regularly at specific time intervals based on the frequency of radar pulse transmission. And Tran teaches: and the score is calculated using the information regarding the positions(Nathan: ¶ 073; process of selecting the optimal alternate flight path may be performed by a cost-optimization process based on one or a plurality of factors, such as the (estimated) fuel expenditure and flight time required by each of the plurality of alternate flight paths. In certain embodiments, the cost-optimization process may consider either fuel expenditure or flight time as the main consideration) Regarding claim 10, as detailed above, combination Gibbons teaches the invention as detailed with respect to claim 1. Nathan teaches: whereinis acquired using at least one of scheduled information regarding the flight plan of the target aircraft, aircraft characteristics information indicating characteristics of equipment of the target aircraft, or operation history information regarding operation history of the target aircraft (Nathan: ¶ 042; safe distance may be determined based on (e.g., a mathematical function of) one or a combination of factors, which may include characteristics of the airplane and characteristics of the zone of avoidance. Characteristics of the airplane may include the size, weight, and payload of the airplane.) Regarding claim 11, as detailed above, combination Gibbons teaches the invention as detailed with respect to claim 1. Nathan teaches: wherein at least the operations (iii)-(vii) are repeatedly performed each time specified acquisition conditions are met (Nathan: ¶ 045; location, altitude, speed, and direction of each vehicle 10 can be continuously monitored and reported back to the servers to manage this data in real-time in an automated fashion) Regarding claim 12, as detailed above, combination Gibbons teaches the invention as detailed with respect to claim 1. Gibbons further teaches: wherein the recommended flight path information is output on the EFB (Gibbons: ¶ 055; Electronic Flight Bag [operates] TAP [which] is a subset of the overall system and is where the route change recommendations are generated. A pilot interfaces with TAP through a user interface. TAP and the user interface can be co-resident)each time specified output conditions are met during the flight of the target aircraft. (Gibbons: ¶¶ 124-125; generate one or more overlays or displays that present the weather-related data, information, etc. to the pilot or crew member (as suggested by step or stage 444), where the overlay(s) or displays may indicate one or more of: a general shape of a weather system or event in relation to the aircraft's current trajectory) Regarding claim 13, as detailed above, combination Gibbons teaches the invention as detailed with respect to claim 1. Gibbons further teaches: wherein the recommended flight path information is output on the EFB in a specified notification mode recommended flight path information the specified notification mode being different from an output mode when the specified notification conditions are not met. (Gibbons: ¶ 009; overlay or overlays may include indications of weather systems, weather events, observations or measurements provided by other aircraft, and in some embodiments, suggested route changes to avoid or minimize the impact of a weather system or event.) Regarding claim 15, as detailed above, combination Gibbons teaches the invention as detailed with respect to claim 51. Gibbons further teaches: wherein the recommended flight path information further includes information regarding heading or speed. (Gibbons: ¶¶ 129-130; generate and provide a recommended change to a trajectory or flight plan . . . by using the received data, information, etc. as an input to an existing or separate flight planning system (as suggested by step or stage 446).) (Gibbons: ¶ 053; flight plan consists of a sequence of waypoints, which are fixed location latitude/longitude points that typically have a three to five letter name. A flight plan will include specifics of anticipated wind strength, altitude, and airspeed.) Regarding claim 16, as detailed above, combination Gibbons teaches the invention as detailed with respect to claim 15. Gibbons teaches: the operations further comprises acquiring result information regarding an operation result of the target aircraft based on the recommended flight path information the recommended flight path information is updated using the result information; (Gibbons: ¶ 129-130; updated weather-related data, information, etc. may be used to generate and provide a recommended change to a trajectory or flight plan; [0130] this may be an optional capability and if desired, may be implemented by using the received data, information, etc. as an input to an existing or separate flight planning system (as suggested by step or stage 446).) Regarding claim 17, as detailed above, combination Gibbons teaches the invention as detailed with respect to claim 15. Gibbons further teaches: operations further comprises transmitting flight setting information used for the flight by the target aircraft in instrument flight mode based on the recommended flight path information (Gibbons: ¶¶ 129-130; generate and provide a recommended change to a trajectory or flight plan . . . by using the received data, information, etc. as an input to an existing or separate flight planning system (as suggested by step or stage 446).) Regarding claim 18, as detailed above, combination Gibbons teaches the invention as detailed with respect to claim 1. Nathan further teaches: wherein the recommended flight path information is further transmitted to a terminal device used by a ground user (Nathan: ¶ 034; alternate flight path is computed, the ground-based computer system may transmit the computed alternate flight path to the air traffic controller 123 for clearance (approval), before transmitting the computed alternate flight path to the aircraft 2) Regarding claim 19, as detailed above, combination Gibbons teaches the invention as detailed with respect to claim 1. Gibbons further teaches: wherein the recommended flight path information (Gibbons: ¶¶ 129-130; generate and provide a recommended change to a trajectory or flight plan . . . by using the received data, information, etc. as an input to an existing or separate flight planning system (as suggested by step or stage 446).) comprises at least one of an ascent profile and a descent profile that the target aircraft is recommended to pass through. (Gibbons: ¶ 053; flight plan consists of a sequence of waypoints, which are fixed location latitude/longitude points that typically have a three to five letter name. A flight plan will include specifics of anticipated wind strength, altitude, and airspeed) Regarding claim 20, as detailed above, combination Gibbons teaches the invention as detailed with respect to claim 19. Gibbons further teaches: wherein the altitude information in the recommended flight path information (Gibbons: ¶¶ 129-130; generate and provide a recommended change to a trajectory or flight plan . . . by using the received data, information, etc. as an input to an existing or separate flight planning system (as suggested by step or stage 446).) comprises altitudes of two or more points in the ascent profile or descent profile. (Gibbons: ¶ 053; flight plan consists of a sequence of waypoints, which are fixed location latitude/longitude points that typically have a three to five letter name. A flight plan will include specifics of anticipated wind strength, altitude, and airspeed) Regarding claim 21, Gibbons teaches an information processing method comprising: (i) acquiring, by a processor, (Gibbons: ¶ 012; instructions may be executed by an electronic processor)condition information regarding the condition of a target aircraft; (Gibbons: ¶ 010; a measurement of a weather system or event may comprise a wind velocity or other characteristic of the event and be measured by a sensor on the other aircraft and automatically provided to aircraft expected to encounter the weather system or event.) (Gibbons: ¶¶ 135-137; in each of a plurality of aircraft to: Acquire current data, information, etc. regarding weather conditions along a flightpath and within a certain range around the flightpath (as suggested by module 406); this may include measurements from on-board sensors) (Gibbons: ¶ 138; application at the ground-based server to process the received weather-related data, information, etc. (if needed) and execute logic to determine which aircraft/pilots to communicate with regarding a specific weather system or event) (ii) acquiring, by the processor, through a wireless network, other aircraft information regarding another aircraft different from the target aircraft, the other aircraft information comprising atmospheric information; (Gibbons: ¶ 115; collect weather-related data and information from a plurality of aircraft that have encountered or flown nearby weather systems and events while flying along their flight trajectory)(Gibbons: ¶ 077; information, etc. obtained from the other aircraft may be used to generate the overlay(s), where the overlay(s) may indicate one or more of: [0078] A general shape of a weather system or event in relation to the aircraft's current trajectory (where the trajectory is indicated by waypoints, altitudes, airspeed, etc.)) (iii) acquiring, by the processor, weather information regarding an atmospheric condition at different altitudes in an airspace regarding a flight path of the target aircraft, (Gibbons: ¶ 117; server receives data, information, etc. from a plurality of aircraft [which is] provided to and used by aircraft that are expected to encounter or be impacted by one of the weather systems)(Gibbons: ¶ 118-119; identify a location of a weather system or event for which it has received data, information . . . this information may be relevant to pilots in front of and behind a weather system) . . . (iv) acquiring, by the processor, one or more candidate fight paths based on the condition information, the other aircraft information and the weather information; (Gibbons: ¶¶ 119-120; determine one or more aircraft that may be expected to encounter or be impacted by a weather system or event for which data, information, etc., has been received (as suggested by step or stage 438); this may include accessing a database or other source of information regarding the planned flight trajectories of a plurality of aircraft expected to be airborne during a specified period and/or within a specific region) (Gibbons: ¶ 009; overlay or overlays may include indications of weather systems, weather events, observations or measurements provided by other aircraft, and in some embodiments, suggested route changes to avoid or minimize the impact of a weather system or event.) (Gibbons: ¶ 131; whether the reported or predicted weather system or event is present along the flightpath.) (Gibbons: ¶ 115; collect weather-related data and information from a plurality of aircraft that have encountered or flown nearby weather systems and events while flying along their flight trajectory) (Gibbons: ¶ 119; this information may be relevant to pilots in front of and behind a weather system or event due to considerations of turbulence, headwinds, tailwinds, etc;). . . (vii) transmitting, by the processor, through the wireless network, the recommended flight path information(Gibbons: ¶ 019; if the crew member accepts the received data and information, then to generate one or more displays showing the trajectory of the selected aircraft and the weather system or event in relation to the trajectory.) to an electronic flight bay (EFB) of the target aircraft (Gibbons: ¶ 055; Electronic Flight Bag [operates] TAP [which] is a subset of the overall system and is where the route change recommendations are generated. A pilot interfaces with TAP through a user interface. TAP and the user interface can be co-resident)such that a pilot of the target aircraft determines whether to change the flight path (Gibbons: ¶ 101; a set of user interface elements to permit a user to change information regarding an aircraft's heading or altitude and in response to be able to examine the current weather system information and weather events based on those changes) To the extent Gibbon is silent about or does not Gibbons teach: the weather information being acquired by performing machine learning based on forecast information and the atmospheric information acquired by the another aircraft; Tran does teach: the weather information being acquired by performing machine learning based on forecast information and the atmospheric information acquired by the another aircraft; (Tran: ¶ 142; encoder learns from the flight plan and the decoder integrates the weather information and recursively “translates” the embedded flight plan information into a full 4D trajectory. Convolution layers can be used into the decoder network pipeline to extract representations from the high-dimension weather features) Before the effective filling date of the claimed invention, it would have been obvious to one of ordinary skill in the art to combine the teachings of Tran with the teachings of Gibbon because doing so would result in the predicable benefit of allowing better “route optimization while avoiding the negative impact of the weather event” (Tran: ¶ 075). To the extent Gibbon is silent about or does not Gibbons teach: (v) calculating a score for each of the one or more candidate paths based on an objective function relating to at least one of fuel consumption, operational cost, safety index or required time; Nathan does teach: (v) calculating, by the processor, a score for each of the one or more candidate paths based on an objective function relating to at least one of fuel consumption, operational cost, safety index or required time; (Nathan: ¶ 073; process of selecting the optimal alternate flight path may be performed by a cost-optimization process based on one or a plurality of factors, such as the (estimated) fuel expenditure and flight time required by each of the plurality of alternate flight paths. In certain embodiments, the cost-optimization process may consider either fuel expenditure or flight time as the main consideration) (vi) selecting, by the processor, a recommended flight path information for the target aircraft based on the score, (Nathan: ¶ 035; constructing a plurality of alternate flight paths around the zone of avoidance based on the safety envelope (operation 304); determining an optimal flight path from among the plurality of alternate flight paths) the recommended flight path information comprising altitude information; and (Nathan: ¶ 074; Fuel expenditure and flight time may be estimated based on any or combination of suitable factors, such as the characteristics of the aircraft (e.g., weight), the altitude of the alternate flight path) Before the effective filling date of the claimed invention, it would have been obvious to one of ordinary skill in the art to combine the teachings of Nathan with the teachings of Gibbon because doing so would result in the predicable benefit of selecting the “economically optimal [flight path] among the candidate alternate flight paths. . ..” Nathan: ¶ 022). Regarding claim 23, as detailed above, combination Gibbons teaches the invention as detailed with respect to claim 1. Nathan further teaches: wherein the operations are performed in real time during the flight of the target aircraft to dynamically optimize fuel consumption and operational cost. (Nathan: ¶ 045; location, altitude, speed, and direction of each vehicle 10 can be continuously monitored and reported back to the servers to manage this data in real-time in an automated fashion) (Nathan: ¶ 073; process of selecting the optimal alternate flight path may be performed by a cost-optimization process based on one or a plurality of factors, such as the (estimated) fuel expenditure) Regarding claim 24, as detailed above, combination Gibbons teaches the invention as detailed with respect to claim 21. Nathan further teaches: wherein at least the operations (iii)-(vii) are repeatedly performed each time specified acquisition conditions are met. (Nathan: ¶ 045; location, altitude, speed, and direction of each vehicle 10 can be continuously monitored and reported back to the servers to manage this data in real-time in an automated fashion) Regarding claim 25, as detailed above, combination Gibbons teaches the invention as detailed with respect to claim 21. Nathan further teaches: wherein the methods performed in real time during the flight of the target aircraft to dynamically optimize fuel consumption and operational cost. (Nathan: ¶ 045; location, altitude, speed, and direction of each vehicle 10 can be continuously monitored and reported back to the servers to manage this data in real-time in an automated fashion) (Nathan: ¶ 073; process of selecting the optimal alternate flight path may be performed by a cost-optimization process based on one or a plurality of factors, such as the (estimated) fuel expenditure) Regarding claim 26, as detailed above, combination Gibbons teaches the invention as detailed with respect to claim 21. Tran further teaches: wherein the machine learning is performed using a neural network trained on historical flight data and atmospheric measurements to predict . . . and wind conditions at the different altitudes. (Tran: ¶ 154; a neural network is trained to generate flight plans from historical data) (Tran: ¶ 142; Convolution layers can be used into the decoder network pipeline to extract representations from the high-dimension weather features) (Tran: ¶ 150; self-configuration aspect could determine whether the operations should continue given the current and/or predicted wind/weather conditions.) and Gibbons teaches: turbulence (Gibbons: ¶ 119; this information may be relevant to pilots in front of and behind a weather system or event due to considerations of turbulence, headwinds, tailwinds) Regarding claim [[[23]]] 27, as detailed above, combination Gibbons teaches the invention as detailed with respect to claim 1. Tran further teaches: wherein the processor executes the machine learning using a neural network trained on historical flight data and atmospheric measurements to predict . . . and wind conditions at the different altitudes. (Tran: ¶ 154; a neural network is trained to generate flight plans from historical data) (Tran: ¶ 142; Convolution layers can be used into the decoder network pipeline to extract representations from the high-dimension weather features) (Tran: ¶ 150; self-configuration aspect could determine whether the operations should continue given the current and/or predicted wind/weather conditions.) and Gibbons teaches: turbulence (Gibbons: ¶ 119; this information may be relevant to pilots in front of and behind a weather system or event due to considerations of turbulence, headwinds, tailwinds) Claim 7 is rejected under 35 U.S.C. 103 as being unpatentable over combination Gibbons as applied to claim 1 above, and further in view of Lebbos (US 20210192961 A1). Regarding claim 7, as detailed above, combination Gibbons teaches the invention as detailed with respect to claim 1. Gibbons does not explicitly teach: wherein the recommended flight path information is selected to minimize fuel consumption or costs associated with one or more specified related aircraft different from the target aircraft; however, Lebbos does teach: wherein the recommended flight path information is selected to minimize fuel consumption or costs associated with one or more specified related aircraft different from the target aircraft (Lebbos: ¶ 056; In the fine filtering step 110 of the process 100, for each possible pair of flights 106, the process 100 analyzes whether a modification to one or both of the initial flight plans for the leader and follower aircraft to fly in formation over the common ground track section can generate net trip (i.e., entire flight) fuel burn savings for the pair (considered as a whole/in its entirety).) (Lebbos: ¶ 146; optimization of departure schedules could allow maximizing the fuel savings of a whole fleet Before the effective filling date of the claimed invention, it would have been obvious to one of ordinary skill in the art to combine the teachings of Lebbos with the teachings of Gibbons because doing so would result in the predicable benefit of "allow[ing] net trip fuel savings " (Lebbos: ¶ 010). Response to Arguments Applicant's remarks filed Dec. 29, 2025 have been fully considered. Applicant’s argument and amendments with respect to the previous applied specification is persuasive and the objection has been withdrawn. Applicant’s argument and amendments with respect to the previous applied claim interpretation under 35 U.S.C. 112(f) is persuasive and the interpretation has not been applied. Applicant’s argument and amendments with respect to the previous applied 35 U.S.C. § 112(b) rejection is persuasive and the rejection is hereby withdrawn. Applicant’s argument and amendments with respect to the previous applied 35 U.S.C. § 101 rejection is persuasive and the rejection is hereby withdrawn. Applicant’s arguments with respect to claims 1, 6-13, 15-21 and 23-27 have been considered but are moot because the new ground of rejection does not rely on any reference applied in the prior rejection of record for any teaching or matter specifically challenged in the argument. Newly prior art Tran et al. (US 20210089134 A1) and Nathan et al. (US 20210020049 A1) have been applied to the newly amended claims. Tran teaches a method of predicting weather based upon a machine learning model and Nathan teaches an integrated flight route planning method that considers other aircraft routes and weather when computing a value for predicted fuel use, which a person of ordinary skill in the art would recognize as a “score” for evaluating a preference in routes. Consequently the claims remain rejected under 35 U.S.C. § 103. Conclusion The prior art made of record and not relied upon is considered pertinent to applicant's disclosure Borgyos (US 20230008742 A1) which discloses a method which allows rerouting an aircraft during a flight of an aircraft system based on a potential conflict with another aircraft in which fuel consumption is considered. Applicant's amendment necessitated the new ground(s) of rejection presented in this Office action. Accordingly, THIS ACTION IS MADE FINAL. See MPEP § 706.07(a). Applicant is reminded of the extension of time policy as set forth in 37 CFR 1.136(a). A shortened statutory period for reply to this final action is set to expire THREE MONTHS from the mailing date of this action. In the event a first reply is filed within TWO MONTHS of the mailing date of this final action and the advisory action is not mailed until after the end of the THREE-MONTH shortened statutory period, then the shortened statutory period will expire on the date the advisory action is mailed, and any nonprovisional extension fee (37 CFR 1.17(a)) pursuant to 37 CFR 1.136(a) will be calculated from the mailing date of the advisory action. In no event, however, will the statutory period for reply expire later than SIX MONTHS from the mailing date of this final action. Any inquiry concerning this communication or earlier communications from the examiner should be directed to CHARLES PALL whose telephone number is (571)272-5280. The examiner can normally be reached M-F 9:30 - 18:30. Examiner interviews are available via telephone, in-person, and video conferencing using a USPTO supplied web-based collaboration tool. To schedule an interview, applicant is encouraged to use the USPTO Automated Interview Request (AIR) at http://www.uspto.gov/interviewpractice. If attempts to reach the examiner by telephone are unsuccessful, the examiner’s supervisor, Angela Ortiz can be reached at 571-272-1206. The fax phone number for the organization where this application or proceeding is assigned is 571-273-8300. Information regarding the status of published or unpublished applications may be obtained from Patent Center. Unpublished application information in Patent Center is available to registered users. To file and manage patent submissions in Patent Center, visit: https://patentcenter.uspto.gov. Visit https://www.uspto.gov/patents/apply/patent-center for more information about Patent Center and https://www.uspto.gov/patents/docx for information about filing in DOCX format. For additional questions, contact the Electronic Business Center (EBC) at 866-217-9197 (toll-free). If you would like assistance from a USPTO Customer Service Representative, call 800-786-9199 (IN USA OR CANADA) or 571-272-1000. /C.P./Examiner, Art Unit 3663 /ANGELA Y ORTIZ/Supervisory Patent Examiner, Art Unit 3663
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Prosecution Timeline

Jun 26, 2024
Application Filed
Oct 01, 2025
Non-Final Rejection mailed — §103
Dec 29, 2025
Response Filed
Apr 28, 2026
Final Rejection mailed — §103
May 21, 2026
Interview Requested
Jun 01, 2026
Applicant Interview (Telephonic)
Jun 01, 2026
Examiner Interview Summary

Precedent Cases

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Study what changed to get past this examiner. Based on 5 most recent grants.

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Prosecution Projections

3-4
Expected OA Rounds
54%
Grant Probability
72%
With Interview (+17.2%)
3y 3m (~1y 2m remaining)
Median Time to Grant
Moderate
PTA Risk
Based on 143 resolved cases by this examiner. Grant probability derived from career allowance rate.

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