Detailed information about the 100 most recent patent applications.
| Application Number | Title | Filing Date | Disposal Date | Disposition | Time (months) | Office Actions | Restrictions | Interview | Appeal |
|---|---|---|---|---|---|---|---|---|---|
| 19267136 | METHOD OF HYDROGEN GENERATION THROUGH SODIUM BOROHYDRIDE HYDROLYSIS USING CaV2O6@CaSiO3@g-C3N4 NANOCOMPOSITE | July 2025 | September 2025 | Allow | 2 | 0 | 0 | No | No |
| 19256128 | HYDROGEN GENERATION METHOD FROM SODIUM BOROHYDRIDE USING CoO/CaSiO3@g-C3N4 NANOCOMPOSITE MATERIAL | June 2025 | September 2025 | Allow | 2 | 0 | 0 | No | No |
| 19217982 | METHOD OF PRODUCING HYDROGEN GAS USING NANOCOMPOSITE CATALYST | May 2025 | August 2025 | Allow | 3 | 1 | 0 | No | No |
| 19045111 | Voltage-Assisted Annealing to Alter Tunnel Junction Properties | February 2025 | August 2025 | Allow | 7 | 1 | 1 | No | No |
| 18872628 | DRIVEN KERR NONLINEAR OSCILLATOR AND RELATED SYSTEMS AND METHODS | December 2024 | March 2025 | Allow | 4 | 0 | 0 | No | No |
| 18955851 | HEAT SHIELD AND JOSEPHSON JUNCTION ARRAY CHIP SYSTEM | November 2024 | May 2025 | Allow | 6 | 1 | 0 | No | No |
| 18780582 | SUPERCONDUCTOR SYNTHESIS METHOD | July 2024 | September 2024 | Allow | 2 | 1 | 0 | No | No |
| 18730393 | PROCESS TO CONDUCT AN AMMONIA CRACKING REACTION IN A FLUIDIZED BED REACTOR | July 2024 | June 2025 | Allow | 11 | 1 | 0 | No | No |
| 18774551 | FIBROUS SILICA ZINC OXIDE- SUPPORTED NICKEL CATALYST FOR DRY REFORMING OF METHANE AND METHODS OF PREPARATION THEREOF | July 2024 | December 2024 | Allow | 5 | 0 | 1 | No | No |
| 18673248 | SYSTEMS AND METHODS FOR GENERATING HYDROGEN AND MAGNETITE FROM ROCK | May 2024 | October 2025 | Allow | 17 | 2 | 1 | No | No |
| 18664126 | METHODS FOR PHOTOCATALYTIC WATER SPLITTING OF PRODUCED WATERS | May 2024 | December 2025 | Allow | 19 | 4 | 0 | Yes | No |
| 18654071 | LOW-COST AND HIGH-STRENGTH Bi-BASED SUPERCONDUCTING WIRE/TAPE AND PREPARATION METHOD THEREOF | May 2024 | March 2025 | Allow | 11 | 1 | 1 | Yes | No |
| 18647210 | HIGH TEMPERATURE SUPERCONDUCTING MATERIALS | April 2024 | May 2025 | Allow | 12 | 1 | 0 | No | No |
| 18622878 | Josephson Junction using Molecular Beam Epitaxy | March 2024 | May 2025 | Allow | 13 | 1 | 0 | No | No |
| 18600835 | SYNTHESIS METHOD FOR A YBCO SUPERCONDUCTING MATERIAL | March 2024 | July 2024 | Allow | 4 | 1 | 0 | No | No |
| 18589455 | EXPERIMENTAL SIMULATION DEVICE FOR HYDROGEN PRODUCTION BY IN-SITU CONVERSION OF GAS RESERVOIR AND USE METHOD THEREOF | February 2024 | July 2024 | Allow | 5 | 1 | 1 | No | No |
| 18586369 | METHODS FOR PREPARING HYDROGEN AND SOLID CARBON FROM A GASEOUS HYDROCARBON SOURCE USING MICROWAVES AND/OR RADIO WAVES | February 2024 | September 2024 | Allow | 7 | 1 | 0 | Yes | No |
| 18581633 | PROCESSES, SYSTEMS AND DEVICES FOR METAL FILLING OF HIGH TEMPERATURE SUPERCONDUCTOR CABLES | February 2024 | March 2026 | Allow | 24 | 2 | 1 | No | No |
| 18435070 | SYSTEMS AND METHODS FOR FABRICATION OF SUPERCONDUCTING INTEGRATED CIRCUITS | February 2024 | April 2025 | Allow | 14 | 1 | 0 | No | No |
| 18411951 | ULTRA-THIN FILM SUPERCONDUCTING TAPES | January 2024 | February 2025 | Allow | 13 | 1 | 0 | No | No |
| 18520624 | METHOD FOR MAKING SUPERCONDUCTING COIL FOR MAGNETIC RESONANCE IMAGING | November 2023 | October 2024 | Allow | 11 | 1 | 0 | No | No |
| 18509125 | Quality Control of High Performance Superconductor Tapes | November 2023 | November 2024 | Allow | 12 | 1 | 0 | No | No |
| 18378116 | Thermal Measurements Using Superconducting Materials | October 2023 | November 2025 | Allow | 25 | 2 | 0 | Yes | No |
| 18233116 | METHOD AND APPARATUS FOR PROCESSING OF MATERIALS USING HIGH-TEMPERATURE TORCH | August 2023 | August 2024 | Allow | 13 | 1 | 0 | No | No |
| 18364497 | Solid State Synthetic Method for Superconductor Material | August 2023 | February 2024 | Allow | 6 | 1 | 0 | No | No |
| 18363817 | METHOD FOR MAKING A SUPERCONDUCTING YBCO WIRE OR TAPE | August 2023 | November 2023 | Allow | 3 | 1 | 0 | No | No |
| 18225005 | CONTINUOUS, LONG FIBER SILCON CARBIDE FIBER REINFORCEMENT FOR HIGH TEMPERATURE SUPERCONDUCTORS, PRE-STRESSING THE FIBER FOR INCREASED STRENGTH, AND USING A FIBER NETWORK FOR 4D CONTROL OF MICRO-MAGENTIC AND MICRO-ELECTRIC FIELDS | July 2023 | February 2025 | Allow | 19 | 1 | 0 | No | No |
| 18344946 | INTEGRATED SYSTEM AND METHOD FOR HYDROGEN PURIFICATION, STORAGE AND PRESSURIZATION | June 2023 | November 2023 | Allow | 4 | 0 | 0 | No | No |
| 18032806 | VARIABLE-STRUCTURE STACKED CABLE TOPOLOGY AND PACKAGING METHOD THEREFOR | April 2023 | November 2024 | Allow | 19 | 1 | 0 | No | No |
| 18302702 | SYSTEMS AND METHODS FOR GENERATING HYDROGEN AND MAGNETITE FROM ROCK | April 2023 | February 2024 | Allow | 10 | 1 | 1 | Yes | No |
| 18115112 | METHOD FOR MAKING YBCO SUPERCONDUCTOR | February 2023 | June 2023 | Allow | 4 | 1 | 0 | No | No |
| 18162817 | HIGH TEMPERATURE SUPERCONDUCTING MATERIALS | February 2023 | January 2024 | Allow | 12 | 1 | 0 | No | No |
| 17922517 | AN ELECTROMAGNET COIL ASSEMBLY | October 2022 | March 2026 | Allow | 40 | 1 | 0 | No | No |
| 17975465 | High-Temperature Superconducting Striated Tape Combinations | October 2022 | May 2023 | Allow | 7 | 0 | 0 | No | No |
| 17966513 | METHODS FOR PREPARING HYDROGEN AND SOLID CARBON FROM A GASEOUS HYDROCARBON SOURCE USING MICROWAVES AND/OR RADIO WAVES | October 2022 | August 2024 | Allow | 22 | 4 | 0 | Yes | No |
| 17936183 | DEVICE, SYSTEM, AND METHOD FOR QUBIT CALIBRATION, MEASUREMENT AND CONTROL | September 2022 | March 2026 | Abandon | 41 | 1 | 0 | No | No |
| 17914411 | JUNCTION, DEVICE AND METHODS OF FABRICATION | September 2022 | January 2026 | Allow | 40 | 1 | 0 | No | No |
| 17945351 | Extremely Low Resistance Films and Methods for Modifying or Creating Same | September 2022 | July 2024 | Allow | 22 | 2 | 0 | No | No |
| 17902765 | REDUCING DISSIPATION AND FREQUENCY NOISE IN QUANTUM DEVICES USING A LOCAL VACUUM CAVITY | September 2022 | August 2023 | Allow | 11 | 0 | 0 | No | No |
| 17929049 | SUPERCONDUCTING COIL, SUPERCONDUCTING DEVICE, AND LIQUID EPOXY RESIN COMPOSITION | September 2022 | January 2026 | Allow | 41 | 1 | 0 | No | No |
| 17898065 | METHODS AND SYSTEMS FOR TREATMENT OF SUPERCONDUCTING MATERIALS TO IMPROVE LOW FIELD PERFORMANCE | August 2022 | December 2023 | Allow | 16 | 2 | 0 | No | No |
| 17887844 | Methods and Systems for Fabricating High Quality Superconducting Tapes | August 2022 | October 2023 | Allow | 14 | 1 | 0 | No | No |
| 17882466 | STABILIZATION AND TUNING OF PERSISTENT CURRENTS USING VARIABLE INDUCTANCE | August 2022 | February 2026 | Allow | 42 | 1 | 0 | No | No |
| 17882139 | SUPERCONDUCTING MATERIAL AND METHOD OF PREPARATION THEREOF | August 2022 | November 2025 | Allow | 40 | 1 | 0 | No | No |
| 17878877 | HYBRID KINETIC INDUCTANCE DEVICES FOR SUPERCONDUCTING QUANTUM COMPUTING | August 2022 | January 2026 | Allow | 42 | 1 | 0 | No | No |
| 17865860 | Quality Control of High Performance Superconductor Tapes | July 2022 | December 2023 | Abandon | 17 | 1 | 0 | No | No |
| 17789064 | PHONONIC MATERIAL AND METHOD FOR PRODUCING SAME | June 2022 | November 2025 | Abandon | 41 | 4 | 0 | Yes | Yes |
| 17786497 | HTS LINKED PARTIAL INSULATION FOR HTS FIELD COILS | June 2022 | January 2026 | Allow | 43 | 1 | 0 | No | No |
| 17785142 | SUPERCONDUCTING WIRE, METHOD FOR MANUFACTURING SUPERCONDUCTING WIRE, AND MRI DEVICE | June 2022 | September 2025 | Allow | 39 | 1 | 0 | No | No |
| 17782189 | SUPERCONDUCTING COIL | June 2022 | December 2025 | Allow | 42 | 1 | 0 | No | No |
| 17779679 | METHOD OF PREPARING BSCCO-BASED MATERIALS | May 2022 | December 2025 | Abandon | 43 | 1 | 0 | No | No |
| 17731236 | SECOND-GENERATION HTS STRIP AND PREPARATION METHOD THEREOF | April 2022 | December 2022 | Allow | 7 | 0 | 1 | No | No |
| 17727784 | HIGH TEMPERATURE SUPERCONDUCTING FILMS AND METHODS FOR MODIFYING AND CREATING SAME | April 2022 | November 2023 | Allow | 18 | 1 | 0 | No | No |
| 17771087 | A Superconducting Switch | April 2022 | June 2025 | Allow | 37 | 0 | 0 | No | No |
| 17660301 | Superconducting Power Cable System | April 2022 | September 2025 | Allow | 41 | 1 | 0 | No | No |
| 17723281 | ULTRA-THIN FILM SUPERCONDUCTING TAPES | April 2022 | October 2023 | Allow | 18 | 1 | 0 | No | No |
| 17722292 | HIGH DENSITY INTERCONNECTS FOR ARRAYS OF JOSEPHSON TRAVELING WAVE PARAMETRIC DEVICES | April 2022 | September 2025 | Allow | 41 | 1 | 0 | Yes | No |
| 17719317 | Superconductor Article with Directional Flux Pinning | April 2022 | September 2023 | Allow | 17 | 1 | 0 | No | No |
| 17658594 | PROCESS AND APPARATUS FOR PROVIDING A FEEDSTOCK | April 2022 | March 2025 | Allow | 35 | 2 | 1 | No | No |
| 17642804 | PERSISTENT CURRENT SWITCH AND SUPERCONDUCTING DEVICE | March 2022 | July 2025 | Abandon | 40 | 1 | 0 | No | No |
| 17653952 | CONNECTION STRUCTURE OF CONDUCTIVE LAYERS, CONDUCTIVE WIRE, COIL AND APPARATUS | March 2022 | February 2025 | Allow | 35 | 0 | 0 | No | No |
| 17689861 | CONNECTION STRUCTURE FOR SUPERCONDUCTING LAYER, SUPERCONDUCTING WIRE, SUPERCONDUCTING COIL, SUPERCONDUCTING DEVICE, AND CONNECTION METHOD FOR SUPERCONDUCTING LAYER | March 2022 | May 2025 | Allow | 38 | 1 | 0 | Yes | No |
| 17753581 | FABRICATION METHOD | March 2022 | February 2026 | Allow | 47 | 2 | 0 | Yes | No |
| 17687111 | A METHOD FOR CHARGING A SUPERCONDUCTOR BULK MAGNET BY FIELD-COOLING, WITH AT LEAST ONE NON-HOMOGENEOUS MAGNETIC FIELD COMPONENT OF THE APPLIED CHARGER MAGNETIC FIELD | March 2022 | October 2025 | Allow | 43 | 0 | 0 | No | No |
| 17639377 | POLYCRYSTALLINE BULK BODY AND METHOD FOR PRODUCING SAME | March 2022 | January 2026 | Allow | 47 | 2 | 0 | No | No |
| 17683219 | SUPERCONDUCTING DEVICES WITH FERROMAGNETIC BARRIER JUNCTIONS | February 2022 | July 2023 | Allow | 17 | 0 | 0 | No | No |
| 17670545 | Method and means for electric vehicle battery charging | February 2022 | December 2025 | Abandon | 46 | 1 | 0 | No | No |
| 17632689 | OXIDE SUPERCONDUCTING WIRE | February 2022 | June 2023 | Allow | 17 | 2 | 0 | Yes | No |
| 17577155 | BIMETALLIC CATALYST FOR CATALYTIC PARTIAL OXIDATION OF HYDROCARBONS | January 2022 | October 2023 | Abandon | 20 | 1 | 0 | No | No |
| 17627368 | MAGNESIUMDIBORIDE POWDER-IN-TUBE WIRE | January 2022 | October 2025 | Allow | 45 | 1 | 0 | No | No |
| 17626971 | SUPERCONDUCTING CIRCUIT AND QUANTUM COMPUTER | January 2022 | November 2025 | Allow | 46 | 1 | 0 | No | No |
| 17626588 | RESONATOR, OSCILLATOR, AND QUANTUM COMPUTER | January 2022 | March 2026 | Allow | 50 | 2 | 0 | No | No |
| 17564789 | TUNABLE CAPACITOR FOR SUPERCONDUCTING QUBITS | December 2021 | July 2025 | Allow | 42 | 0 | 0 | No | No |
| 17559394 | SUBELEMENT BASED ON NB-CONTAINING ROD ELEMENTS WITH POWDER-FILLED CORE TUBE FOR AN NB3SN-CONTAINING SUPERCONDUCTOR WIRE, AND ASSOCIATED PRODUCTION METHOD | December 2021 | January 2023 | Allow | 13 | 0 | 0 | No | No |
| 17620318 | QUENCH PROTECTION FOR HIGH TEMPERATURE SUPERCONDUCTING (HTS) LEADS | December 2021 | November 2025 | Abandon | 47 | 1 | 0 | No | No |
| 17547810 | Josephson Junction using Molecular Beam Epitaxy | December 2021 | January 2024 | Allow | 25 | 2 | 0 | No | No |
| 17545985 | VERTICAL TRANSMON STRUCTURE AND ITS FABRICATION PROCESS | December 2021 | October 2025 | Allow | 46 | 1 | 1 | No | No |
| 17532811 | SEMICONDUCTOR-SUPERCONDUCTOR HYBRID DEVICES WITH A HORIZONTALLY-CONFINED CHANNEL AND METHODS OF FORMING THE SAME | November 2021 | July 2025 | Allow | 43 | 1 | 0 | Yes | No |
| 17508810 | ON-CHIP TUNABLE DISSIPATIONLESS INDUCTOR | October 2021 | March 2026 | Abandon | 53 | 1 | 1 | No | No |
| 17601941 | FERROELECTRIC SUPERCONDUCTOR FROM BELOW TO ABOVE ROOM TEMPERATURE | October 2021 | October 2025 | Abandon | 48 | 1 | 0 | No | No |
| 17492920 | FINISHED CONDUCTOR ARRANGEMENT FOR AN NB3SN SUPERCONDUCTOR WIRE AND METHOD FOR PRODUCING A SUBELEMENT FOR AN NB3SN SUPERCONDUCTOR WIRE | October 2021 | September 2022 | Allow | 12 | 1 | 0 | No | No |
| 17600693 | HIGH TEMPERATURE SUPCONDUCTOR CABLE | October 2021 | April 2025 | Allow | 43 | 2 | 1 | Yes | No |
| 17488203 | Qubit Detection Using Superconductor Devices | September 2021 | October 2025 | Allow | 49 | 1 | 1 | No | No |
| 17598927 | METHOD FOR HYDROGEN PRODUCTION VIA METAL-WATER REACTION | September 2021 | February 2024 | Allow | 29 | 1 | 0 | No | No |
| 17479025 | Open Midplane, High Magnetic Field Solenoid System and Method for Neutron or X-Ray Scattering Analysis | September 2021 | June 2024 | Allow | 33 | 1 | 0 | No | No |
| 17465195 | DEVICES, SYSTEMS, FACILITIES, AND PROCESSES FOR LIQUEFIED NATURAL GAS PRODUCTION | September 2021 | February 2022 | Allow | 6 | 1 | 0 | No | No |
| 17463548 | MAJORANA-BASED QUBITS IN 3D TOPOLOGICAL INSULATOR FLAKES | September 2021 | August 2025 | Allow | 47 | 1 | 0 | Yes | No |
| 17408970 | SUPERCONDUCTING COIL MODULE | August 2021 | October 2025 | Abandon | 50 | 1 | 0 | No | No |
| 17428655 | SUPERCONDUCTING WIRE AND PERMANENT CURRENT SWITCH | August 2021 | June 2025 | Abandon | 46 | 1 | 0 | No | No |
| 17390752 | PARTIALLY-INSULATED HTS COILS | July 2021 | December 2023 | Abandon | 29 | 1 | 0 | No | No |
| 17443063 | Method and device for cooling of a superconducting cable and corresponding system | July 2021 | June 2025 | Allow | 47 | 1 | 0 | No | No |
| 17365870 | SUPERCONDUCTING RESERVOIR COMPUTER WITH JOSEPHSON TRANSMISSION LINES | July 2021 | October 2025 | Allow | 51 | 1 | 1 | No | No |
| 17353022 | SOLID STATE DELIVERY SYSTEM | June 2021 | June 2025 | Allow | 48 | 3 | 1 | No | No |
| 17352995 | METHOD FOR MAKING YTTRIUM-BARIUM-COPPER-OXIDE HAVING HIGH OFFSET SUPERCONDUCTING TRANSITION TEMPERATURE | June 2021 | January 2023 | Allow | 19 | 1 | 0 | No | No |
| 17348716 | HTS BEARING AND FLYWHEEL SYSTEMS AND METHODS | June 2021 | November 2025 | Allow | 53 | 2 | 0 | No | No |
| 17339990 | A-axis Josephson Junctions with Improved Smoothness | June 2021 | September 2025 | Allow | 52 | 2 | 0 | No | No |
| 17333183 | INTEGRATION SCHEME FOR SHUNTED JOSEPHSON JUNCTIONS | May 2021 | June 2025 | Abandon | 49 | 0 | 1 | No | No |
| 17333725 | LONGITUDINALLY JOINED SUPERCONDUCTING RESONATING CAVITIES | May 2021 | March 2023 | Allow | 22 | 1 | 0 | No | No |
| 17327230 | SUPERCONDUCTING TUNABLE INDUCTANCE | May 2021 | March 2026 | Abandon | 58 | 2 | 1 | No | No |
| 17295577 | NONLINEAR MICROWAVE FILTER | May 2021 | November 2024 | Allow | 42 | 1 | 0 | No | No |
This analysis examines appeal outcomes and the strategic value of filing appeals for examiner WARTALOWICZ, PAUL A.
With a 13.8% reversal rate, the PTAB affirms the examiner's rejections in the vast majority of cases. This reversal rate is below the USPTO average, indicating that appeals face more challenges here than typical.
Filing a Notice of Appeal can sometimes lead to allowance even before the appeal is fully briefed or decided by the PTAB. This occurs when the examiner or their supervisor reconsiders the rejection during the mandatory appeal conference (MPEP § 1207.01) after the appeal is filed.
In this dataset, 26.0% of applications that filed an appeal were subsequently allowed. This appeal filing benefit rate is below the USPTO average, suggesting that filing an appeal has limited effectiveness in prompting favorable reconsideration.
⚠ Appeals to PTAB face challenges. Ensure your case has strong merit before committing to full Board review.
⚠ Filing a Notice of Appeal shows limited benefit. Consider other strategies like interviews or amendments before appealing.
Examiner WARTALOWICZ, PAUL A works in Art Unit 1735 and has examined 731 patent applications in our dataset. With an allowance rate of 63.6%, this examiner allows applications at a lower rate than most examiners at the USPTO. Applications typically reach final disposition in approximately 37 months.
Examiner WARTALOWICZ, PAUL A's allowance rate of 63.6% places them in the 24% percentile among all USPTO examiners. This examiner is less likely to allow applications than most examiners at the USPTO.
On average, applications examined by WARTALOWICZ, PAUL A receive 2.18 office actions before reaching final disposition. This places the examiner in the 59% percentile for office actions issued. This examiner issues a slightly above-average number of office actions.
The median time to disposition (half-life) for applications examined by WARTALOWICZ, PAUL A is 37 months. This places the examiner in the 32% percentile for prosecution speed. Prosecution timelines are slightly slower than average with this examiner.
Conducting an examiner interview provides a +16.5% benefit to allowance rate for applications examined by WARTALOWICZ, PAUL A. This interview benefit is in the 57% percentile among all examiners. Recommendation: Interviews provide an above-average benefit with this examiner and are worth considering.
When applicants file an RCE with this examiner, 21.7% of applications are subsequently allowed. This success rate is in the 26% percentile among all examiners. Strategic Insight: RCEs show below-average effectiveness with this examiner. Carefully evaluate whether an RCE or continuation is the better strategy.
This examiner enters after-final amendments leading to allowance in 32.6% of cases where such amendments are filed. This entry rate is in the 48% percentile among all examiners. Strategic Recommendation: This examiner shows below-average receptiveness to after-final amendments. You may need to file an RCE or appeal rather than relying on after-final amendment entry.
When applicants request a pre-appeal conference (PAC) with this examiner, 28.6% result in withdrawal of the rejection or reopening of prosecution. This success rate is in the 30% percentile among all examiners. Note: Pre-appeal conferences show below-average success with this examiner. Consider whether your arguments are strong enough to warrant a PAC request.
This examiner withdraws rejections or reopens prosecution in 42.0% of appeals filed. This is in the 9% percentile among all examiners. Of these withdrawals, 38.1% occur early in the appeal process (after Notice of Appeal but before Appeal Brief). Strategic Insight: This examiner rarely withdraws rejections during the appeal process compared to other examiners. If you file an appeal, be prepared to fully prosecute it to a PTAB decision. Per MPEP § 1207, the examiner will prepare an Examiner's Answer maintaining the rejections.
When applicants file petitions regarding this examiner's actions, 51.1% are granted (fully or in part). This grant rate is in the 50% percentile among all examiners. Strategic Note: Petitions show below-average success regarding this examiner's actions. Ensure you have a strong procedural basis before filing.
Examiner's Amendments: This examiner makes examiner's amendments in 2.6% of allowed cases (in the 78% percentile). Per MPEP § 1302.04, examiner's amendments are used to place applications in condition for allowance when only minor changes are needed. This examiner frequently uses this tool compared to other examiners, indicating a cooperative approach to getting applications allowed. Strategic Insight: If you are close to allowance but minor claim amendments are needed, this examiner may be willing to make an examiner's amendment rather than requiring another round of prosecution.
Quayle Actions: This examiner issues Ex Parte Quayle actions in 6.9% of allowed cases (in the 85% percentile). Per MPEP § 714.14, a Quayle action indicates that all claims are allowable but formal matters remain. This examiner frequently uses Quayle actions compared to other examiners, which is a positive indicator that once substantive issues are resolved, allowance follows quickly.
Based on the statistical analysis of this examiner's prosecution patterns, here are tailored strategic recommendations:
Not Legal Advice: The information provided in this report is for informational purposes only and does not constitute legal advice. You should consult with a qualified patent attorney or agent for advice specific to your situation.
No Guarantees: We do not provide any guarantees as to the accuracy, completeness, or timeliness of the statistics presented above. Patent prosecution statistics are derived from publicly available USPTO data and are subject to data quality limitations, processing errors, and changes in USPTO practices over time.
Limitation of Liability: Under no circumstances will IronCrow AI be liable for any outcome, decision, or action resulting from your reliance on the statistics, analysis, or recommendations presented in this report. Past prosecution patterns do not guarantee future results.
Use at Your Own Risk: While we strive to provide accurate and useful prosecution statistics, you should independently verify any information that is material to your prosecution strategy and use your professional judgment in all patent prosecution matters.