Modern corporate illustration of "Agentic Engineering" concept - Colombian software developer as orchestrator or architect in central elevated position with commanding perspective, actively supervising multiple specialized AI agents working in parallel on different aspects of development project. Developer in confident professional stance with directing gesture, one hand raised coordinating workflow, expression of focused professional control and collaboration. Elevated or privileged viewpoint showing developer overseeing organized system. Five distinct specialized AI agents represented as elegant geometric holographic forms, each clearly differentiated and working in their specific area: Architecture Agent with blueprint diagrams and system design visualizations, Code Generator Agent actively writing and structuring code, Testing Agent executing automated tests with results panels, Documentation Agent creating technical docs and diagrams, CI/CD Agent managing deployment pipeline and infrastructure. Each agent positioned in its own clear workspace panel or station around the developer, visually organized like specialized team members. Bidirectional communication lines flowing between developer and each agent - glowing data streams, approval checkmarks, guidance arrows showing active supervision not passive observation. All panels simultaneously visible showing complete development lifecycle: architecture blueprints, code syntax windows, test execution terminals, documentation pages, CI/CD pipeline flow. Atmosphere of professional control, organized collaboration, disciplined engineering approach. Developer clearly engaged in review, guidance, and decision-making, not just watching. Visual sense of "professional team" with AI agents as specialized colleagues under expert direction. Corporate color palette: deep professional blues, slate grays, crisp whites, cyan technological accents, emerald green highlights. Modern semi-realistic corporate digital illustration, clean professional composition with organized complexity. Clean abstract tech background with refined digital networks suggesting enterprise infrastructure. Soft professional lighting with depth emphasizing central orchestrator role. High resolution, sharp details, premium professional quality. Horizontal format optimized for blog section with clear recognizable focal point showing developer in control. No text overlays, no logos, no watermarks, no cartoon style, professional sophisticated aesthetic conveying serious engineering discipline.
024
Hero
make a 3D infographic that illustrates software integration, with the writing: “architecture”, “components” and “data”, with a high-tech design. Show the software in the form of a HOLOGRAPHIC cube in the center with program codes. Around it, insert computers, screens, servers, server clouds and computer chips.
2120
FLUX
In a vibrant blue background, the text "STEP 2" stands out prominently in a bold, mint green font, followed by a clear directive: "Plant the workflow of your web application" rendered in a softer white. Above the text is an illustrated laptop that features a simplified design, facing slightly toward the viewer, enhancing the message about web application workflow. Thin green lines emanate from the laptop, suggesting a flow or connection, contributing to the tech-oriented theme. The overall layout is clean and modern, emphasizing clarity and guidance for users embarking on web application development.
029
Ideogram
make a 3D image illustrating software integration, with the writing: “architecture”, “components” and “data”, with a high-tech design. Show the software in the form of a HOLOGRAPHIC cube in the center with program codes. Around it, insert computers, screens, servers, server clouds and computer chips.
186
FLUX
make a 3D image illustrating software integration, with the writing: “architecture”, “components” and “data”, with a high-tech design. Show the software in the form of a HOLOGRAPHIC cube in the center with program codes. Around it, insert computers, screens, servers, server clouds and computer chips.
153
FLUX
Create a BioRender-style, publication-ready vector infographic titled “研究内容框架图” for a grant proposal. Use clean flat BioRender vectors, thick outlines, minimal shadows, consistent spacing, and a readable sans-serif font (Microsoft YaHei). Use a 16:10 landscape canvas (taller than 16:9). All text inside boxes must be Chinese exactly as specified. Do not include any mathematical letters, symbols, or formulas. Layout The figure has two main sections: Section A (left/center): Research Content Framework (main flowchart) A large framed panel with a top-down or left-to-right flow of four major blocks (Step 1 → Step 2 → Step 3 → Step 4). Each block is a rounded rectangle with a short title plus 2–4 bullet points. Add clear arrows between steps. Add a small triangle badge near Step 3 showing the trade-off. Section B (right side): Three embedded mini-schematics aligned vertically, each framed, with titles: “闭环控制框架(流程图)” “耦合误差示意(维恩图)” “深度递归神经网络示意(时间展开)” Use thin dashed connectors from the main Step 1–3 blocks to the corresponding mini-schematics to show correspondence. Icons (flat, minimal) Multi-agent network graph (nodes + edges), drones and mobile robots, wireless signal, clock/bell for event-triggering, sample-and-hold icon, neural network/RNN icon, Lyapunov/stability icon, and a balance scale icon (performance vs communication vs energy). Keep icons minimal and consistent. Chinese text to place in boxes (exact) Title (top center) “学习辨识—事件触发耦合下非线性多智能体系统分布式一致性控制与收敛性/有界性分析:研究内容框架图” Section A: Main research content framework (4 steps) Step 1 (Block 1) Title: “一致性误差机理刻画” Bullets: “建立统一闭环误差建模框架” “刻画学习误差、触发保持误差与拓扑耦合误差的交叉作用” “解释收敛退化、触发频繁与性能下降的成因” “覆盖无领导一致、领导跟随一致与协同跟踪场景” Step 2 (Block 2) Title: “低保守收敛性与有界性分析” Bullets: “显式利用触发区间信息构造分析工具” “建立收敛性与有界性判据并降低保守性” “推导误差上界、无有限时间无限触发条件与触发间隔下界” “刻画触发间隔与拓扑、触发参数、辨识精度的定量关系” Step 3 (Block 3) Title: “协同设计与权衡机制” Bullets: “协同设计学习辨识器、动态事件触发与分布式控制协议” “保证学习参数与内部递归状态有界” “揭示学习率、触发参数、拓扑特征与一致性性能的定量关系” “建立一致性性能—通信次数—能耗开销的可计算权衡” Add-on icon near Step 3: A small triangular trade-off badge with vertex labels (Chinese): “一致性性能 / 通信次数 / 能耗开销” Caption next to triangle: “可计算权衡” Step 4 (Block 4) Title: “仿真分析与实验验证” Bullets: “搭建含未知非线性、扰动与通信约束的仿真平台” “对比不同触发规则、拓扑与学习精度下的性能与通信开销” “在多无人机与多机器人平台开展验证” “形成可推广的低通信、高可靠、可验证方法” Section B: Three mini-schematics (right side) Mini-panel 1: “闭环控制框架(流程图)” Draw a left-to-right flowchart with rounded blocks and arrows: Blocks (in order, Chinese text exact): “非线性多智能体系统” → “局部/邻域信息获取” → “一致性误差计算” → “学习辨识器(深度递归神经网络)” → “分布式控制器” → “动态事件触发器” → “网络传输与采样保持” → Back arrow to “非线性多智能体系统” Add two dashed feedback arrows from “一致性误差计算” to: “学习辨识器(深度递归神经网络)” (label: “误差驱动更新”) “动态事件触发器” (label: “误差驱动更新”) Add small notes: Under “动态事件触发器”: “按需通信/按需更新” Near “网络传输与采样保持”: “触发保持误差” Add a small timeline icon with ticks labeled in Chinese: “触发时刻…下一次触发时刻” and label “触发间隔”. Mini-panel 2: “耦合误差示意(维恩图)” Draw a three-circle Venn diagram with semi-transparent circles: Circle labels (Chinese): “学习辨识误差” (with RNN icon) “触发保持误差” (with clock + sample-and-hold icon) “拓扑耦合误差” (with network graph icon) Pairwise overlap labels: “学习更新×非均匀更新” “异步通信×拓扑传播” “分布式辨识×邻域耦合” Center overlap (bold): “耦合项集合” Under it: “影响一致性误差演化” Arrow from center to a right-side box titled “结果表征” with bullets: “收敛退化(渐近→最终有界)” “触发频繁/触发间隔变小” “稳态误差界增大/性能下降” Mini-panel 3: “深度递归神经网络示意(时间展开)” Draw a time-unrolled recurrent network schematic along a horizontal timeline labeled in Chinese: “上一时刻 → 当前时刻 → 下一时刻” At each time slice, show stacked recurrent blocks: Input label: “本体状态与邻域信息” → Middle label: “递归记忆状态” → Output label: “未知非线性与不确定项的在线辨识输出” Connect time slices with arrows labeled: “共享参数” Add a side arrow from “一致性误差” into a small box: “参数更新(投影/正则化/学习率调度)” Then arrow into: “学习参数更新” Style constraints BioRender clean scientific infographic, no photorealism, no clutter, high readability. Strict rule: do not include any math symbols, letters, equations, or subscripts. Negative prompt: Avoid photorealistic style, avoid dense paragraphs, avoid handwritten fonts, avoid low resolution, avoid formulas, avoid math letters.
136
Nano Banana
Currently client is struggling with the current process where they need to manually manage the excel sheets, reporting process and tools not situated in one application. There is No clear visibility of resource allocation, reporting, budget, collaboration, reporting, project management, task management, time consuming. we came up with the proposed solution to improve productivity by eliminating manual work and bringing all project-related processes into one unified PPM tool which will Include key features such as project and task management, resource allocation, budget tracking, reporting and team collaboration- all within a single platform and the tool will replace manual excel-based processes and disconnected tools currently in use. please create the system architecture diagram for proposed system
0107
FLUX
Modern corporate illustration of "Agentic Engineering" concept - Colombian software developer as orchestrator or architect in central elevated position with commanding perspective, actively supervising multiple specialized AI agents working in parallel on different aspects of development project. Developer in confident professional stance with directing gesture, one hand raised coordinating workflow, expression of focused professional control and collaboration. Elevated or privileged viewpoint showing developer overseeing organized system. Five distinct specialized AI agents represented as elegant geometric holographic forms, each clearly differentiated and working in their specific area: Architecture Agent with blueprint diagrams and system design visualizations, Code Generator Agent actively writing and structuring code, Testing Agent executing automated tests with results panels, Documentation Agent creating technical docs and diagrams, CI/CD Agent managing deployment pipeline and infrastructure. Each agent positioned in its own clear workspace panel or station around the developer, visually organized like specialized team members. Bidirectional communication lines flowing between developer and each agent - glowing data streams, approval checkmarks, guidance arrows showing active supervision not passive observation. All panels simultaneously visible showing complete development lifecycle: architecture blueprints, code syntax windows, test execution terminals, documentation pages, CI/CD pipeline flow. Atmosphere of professional control, organized collaboration, disciplined engineering approach. Developer clearly engaged in review, guidance, and decision-making, not just watching. Visual sense of "professional team" with AI agents as specialized colleagues under expert direction. Corporate color palette: deep professional blues, slate grays, crisp whites, cyan technological accents, emerald green highlights. Modern semi-realistic corporate digital illustration, clean professional composition with organized complexity. Clean abstract tech background with refined digital networks suggesting enterprise infrastructure. Soft professional lighting with depth emphasizing central orchestrator role. High resolution, sharp details, premium professional quality. Horizontal format optimized for blog section with clear recognizable focal point showing developer in control. No text overlays, no logos, no watermarks, no cartoon style, professional sophisticated aesthetic conveying serious engineering discipline.
024
Hero
In a vibrant blue background, the text "STEP 2" stands out prominently in a bold, mint green font, followed by a clear directive: "Plant the workflow of your web application" rendered in a softer white. Above the text is an illustrated laptop that features a simplified design, facing slightly toward the viewer, enhancing the message about web application workflow. Thin green lines emanate from the laptop, suggesting a flow or connection, contributing to the tech-oriented theme. The overall layout is clean and modern, emphasizing clarity and guidance for users embarking on web application development.
029
Ideogram
Create a BioRender-style, publication-ready vector infographic titled “研究内容框架图” for a grant proposal. Use clean flat BioRender vectors, thick outlines, minimal shadows, consistent spacing, and a readable sans-serif font (Microsoft YaHei). Use a 16:10 landscape canvas (taller than 16:9). All text inside boxes must be Chinese exactly as specified. Do not include any mathematical letters, symbols, or formulas. Layout The figure has two main sections: Section A (left/center): Research Content Framework (main flowchart) A large framed panel with a top-down or left-to-right flow of four major blocks (Step 1 → Step 2 → Step 3 → Step 4). Each block is a rounded rectangle with a short title plus 2–4 bullet points. Add clear arrows between steps. Add a small triangle badge near Step 3 showing the trade-off. Section B (right side): Three embedded mini-schematics aligned vertically, each framed, with titles: “闭环控制框架(流程图)” “耦合误差示意(维恩图)” “深度递归神经网络示意(时间展开)” Use thin dashed connectors from the main Step 1–3 blocks to the corresponding mini-schematics to show correspondence. Icons (flat, minimal) Multi-agent network graph (nodes + edges), drones and mobile robots, wireless signal, clock/bell for event-triggering, sample-and-hold icon, neural network/RNN icon, Lyapunov/stability icon, and a balance scale icon (performance vs communication vs energy). Keep icons minimal and consistent. Chinese text to place in boxes (exact) Title (top center) “学习辨识—事件触发耦合下非线性多智能体系统分布式一致性控制与收敛性/有界性分析:研究内容框架图” Section A: Main research content framework (4 steps) Step 1 (Block 1) Title: “一致性误差机理刻画” Bullets: “建立统一闭环误差建模框架” “刻画学习误差、触发保持误差与拓扑耦合误差的交叉作用” “解释收敛退化、触发频繁与性能下降的成因” “覆盖无领导一致、领导跟随一致与协同跟踪场景” Step 2 (Block 2) Title: “低保守收敛性与有界性分析” Bullets: “显式利用触发区间信息构造分析工具” “建立收敛性与有界性判据并降低保守性” “推导误差上界、无有限时间无限触发条件与触发间隔下界” “刻画触发间隔与拓扑、触发参数、辨识精度的定量关系” Step 3 (Block 3) Title: “协同设计与权衡机制” Bullets: “协同设计学习辨识器、动态事件触发与分布式控制协议” “保证学习参数与内部递归状态有界” “揭示学习率、触发参数、拓扑特征与一致性性能的定量关系” “建立一致性性能—通信次数—能耗开销的可计算权衡” Add-on icon near Step 3: A small triangular trade-off badge with vertex labels (Chinese): “一致性性能 / 通信次数 / 能耗开销” Caption next to triangle: “可计算权衡” Step 4 (Block 4) Title: “仿真分析与实验验证” Bullets: “搭建含未知非线性、扰动与通信约束的仿真平台” “对比不同触发规则、拓扑与学习精度下的性能与通信开销” “在多无人机与多机器人平台开展验证” “形成可推广的低通信、高可靠、可验证方法” Section B: Three mini-schematics (right side) Mini-panel 1: “闭环控制框架(流程图)” Draw a left-to-right flowchart with rounded blocks and arrows: Blocks (in order, Chinese text exact): “非线性多智能体系统” → “局部/邻域信息获取” → “一致性误差计算” → “学习辨识器(深度递归神经网络)” → “分布式控制器” → “动态事件触发器” → “网络传输与采样保持” → Back arrow to “非线性多智能体系统” Add two dashed feedback arrows from “一致性误差计算” to: “学习辨识器(深度递归神经网络)” (label: “误差驱动更新”) “动态事件触发器” (label: “误差驱动更新”) Add small notes: Under “动态事件触发器”: “按需通信/按需更新” Near “网络传输与采样保持”: “触发保持误差” Add a small timeline icon with ticks labeled in Chinese: “触发时刻…下一次触发时刻” and label “触发间隔”. Mini-panel 2: “耦合误差示意(维恩图)” Draw a three-circle Venn diagram with semi-transparent circles: Circle labels (Chinese): “学习辨识误差” (with RNN icon) “触发保持误差” (with clock + sample-and-hold icon) “拓扑耦合误差” (with network graph icon) Pairwise overlap labels: “学习更新×非均匀更新” “异步通信×拓扑传播” “分布式辨识×邻域耦合” Center overlap (bold): “耦合项集合” Under it: “影响一致性误差演化” Arrow from center to a right-side box titled “结果表征” with bullets: “收敛退化(渐近→最终有界)” “触发频繁/触发间隔变小” “稳态误差界增大/性能下降” Mini-panel 3: “深度递归神经网络示意(时间展开)” Draw a time-unrolled recurrent network schematic along a horizontal timeline labeled in Chinese: “上一时刻 → 当前时刻 → 下一时刻” At each time slice, show stacked recurrent blocks: Input label: “本体状态与邻域信息” → Middle label: “递归记忆状态” → Output label: “未知非线性与不确定项的在线辨识输出” Connect time slices with arrows labeled: “共享参数” Add a side arrow from “一致性误差” into a small box: “参数更新(投影/正则化/学习率调度)” Then arrow into: “学习参数更新” Style constraints BioRender clean scientific infographic, no photorealism, no clutter, high readability. Strict rule: do not include any math symbols, letters, equations, or subscripts. Negative prompt: Avoid photorealistic style, avoid dense paragraphs, avoid handwritten fonts, avoid low resolution, avoid formulas, avoid math letters.
136
Nano Banana
make a 3D infographic that illustrates software integration, with the writing: “architecture”, “components” and “data”, with a high-tech design. Show the software in the form of a HOLOGRAPHIC cube in the center with program codes. Around it, insert computers, screens, servers, server clouds and computer chips.
2120
FLUX
make a 3D image illustrating software integration, with the writing: “architecture”, “components” and “data”, with a high-tech design. Show the software in the form of a HOLOGRAPHIC cube in the center with program codes. Around it, insert computers, screens, servers, server clouds and computer chips.
186
FLUX
make a 3D image illustrating software integration, with the writing: “architecture”, “components” and “data”, with a high-tech design. Show the software in the form of a HOLOGRAPHIC cube in the center with program codes. Around it, insert computers, screens, servers, server clouds and computer chips.
153
FLUX
Currently client is struggling with the current process where they need to manually manage the excel sheets, reporting process and tools not situated in one application. There is No clear visibility of resource allocation, reporting, budget, collaboration, reporting, project management, task management, time consuming. we came up with the proposed solution to improve productivity by eliminating manual work and bringing all project-related processes into one unified PPM tool which will Include key features such as project and task management, resource allocation, budget tracking, reporting and team collaboration- all within a single platform and the tool will replace manual excel-based processes and disconnected tools currently in use. please create the system architecture diagram for proposed system
0107
FLUX
Modern corporate illustration of "Agentic Engineering" concept - Colombian software developer as orchestrator or architect in central elevated position with commanding perspective, actively supervising multiple specialized AI agents working in parallel on different aspects of development project. Developer in confident professional stance with directing gesture, one hand raised coordinating workflow, expression of focused professional control and collaboration. Elevated or privileged viewpoint showing developer overseeing organized system. Five distinct specialized AI agents represented as elegant geometric holographic forms, each clearly differentiated and working in their specific area: Architecture Agent with blueprint diagrams and system design visualizations, Code Generator Agent actively writing and structuring code, Testing Agent executing automated tests with results panels, Documentation Agent creating technical docs and diagrams, CI/CD Agent managing deployment pipeline and infrastructure. Each agent positioned in its own clear workspace panel or station around the developer, visually organized like specialized team members. Bidirectional communication lines flowing between developer and each agent - glowing data streams, approval checkmarks, guidance arrows showing active supervision not passive observation. All panels simultaneously visible showing complete development lifecycle: architecture blueprints, code syntax windows, test execution terminals, documentation pages, CI/CD pipeline flow. Atmosphere of professional control, organized collaboration, disciplined engineering approach. Developer clearly engaged in review, guidance, and decision-making, not just watching. Visual sense of "professional team" with AI agents as specialized colleagues under expert direction. Corporate color palette: deep professional blues, slate grays, crisp whites, cyan technological accents, emerald green highlights. Modern semi-realistic corporate digital illustration, clean professional composition with organized complexity. Clean abstract tech background with refined digital networks suggesting enterprise infrastructure. Soft professional lighting with depth emphasizing central orchestrator role. High resolution, sharp details, premium professional quality. Horizontal format optimized for blog section with clear recognizable focal point showing developer in control. No text overlays, no logos, no watermarks, no cartoon style, professional sophisticated aesthetic conveying serious engineering discipline.
024
Hero
make a 3D image illustrating software integration, with the writing: “architecture”, “components” and “data”, with a high-tech design. Show the software in the form of a HOLOGRAPHIC cube in the center with program codes. Around it, insert computers, screens, servers, server clouds and computer chips.
153
FLUX
Currently client is struggling with the current process where they need to manually manage the excel sheets, reporting process and tools not situated in one application. There is No clear visibility of resource allocation, reporting, budget, collaboration, reporting, project management, task management, time consuming. we came up with the proposed solution to improve productivity by eliminating manual work and bringing all project-related processes into one unified PPM tool which will Include key features such as project and task management, resource allocation, budget tracking, reporting and team collaboration- all within a single platform and the tool will replace manual excel-based processes and disconnected tools currently in use. please create the system architecture diagram for proposed system
0107
FLUX
In a vibrant blue background, the text "STEP 2" stands out prominently in a bold, mint green font, followed by a clear directive: "Plant the workflow of your web application" rendered in a softer white. Above the text is an illustrated laptop that features a simplified design, facing slightly toward the viewer, enhancing the message about web application workflow. Thin green lines emanate from the laptop, suggesting a flow or connection, contributing to the tech-oriented theme. The overall layout is clean and modern, emphasizing clarity and guidance for users embarking on web application development.
029
Ideogram
Create a BioRender-style, publication-ready vector infographic titled “研究内容框架图” for a grant proposal. Use clean flat BioRender vectors, thick outlines, minimal shadows, consistent spacing, and a readable sans-serif font (Microsoft YaHei). Use a 16:10 landscape canvas (taller than 16:9). All text inside boxes must be Chinese exactly as specified. Do not include any mathematical letters, symbols, or formulas. Layout The figure has two main sections: Section A (left/center): Research Content Framework (main flowchart) A large framed panel with a top-down or left-to-right flow of four major blocks (Step 1 → Step 2 → Step 3 → Step 4). Each block is a rounded rectangle with a short title plus 2–4 bullet points. Add clear arrows between steps. Add a small triangle badge near Step 3 showing the trade-off. Section B (right side): Three embedded mini-schematics aligned vertically, each framed, with titles: “闭环控制框架(流程图)” “耦合误差示意(维恩图)” “深度递归神经网络示意(时间展开)” Use thin dashed connectors from the main Step 1–3 blocks to the corresponding mini-schematics to show correspondence. Icons (flat, minimal) Multi-agent network graph (nodes + edges), drones and mobile robots, wireless signal, clock/bell for event-triggering, sample-and-hold icon, neural network/RNN icon, Lyapunov/stability icon, and a balance scale icon (performance vs communication vs energy). Keep icons minimal and consistent. Chinese text to place in boxes (exact) Title (top center) “学习辨识—事件触发耦合下非线性多智能体系统分布式一致性控制与收敛性/有界性分析:研究内容框架图” Section A: Main research content framework (4 steps) Step 1 (Block 1) Title: “一致性误差机理刻画” Bullets: “建立统一闭环误差建模框架” “刻画学习误差、触发保持误差与拓扑耦合误差的交叉作用” “解释收敛退化、触发频繁与性能下降的成因” “覆盖无领导一致、领导跟随一致与协同跟踪场景” Step 2 (Block 2) Title: “低保守收敛性与有界性分析” Bullets: “显式利用触发区间信息构造分析工具” “建立收敛性与有界性判据并降低保守性” “推导误差上界、无有限时间无限触发条件与触发间隔下界” “刻画触发间隔与拓扑、触发参数、辨识精度的定量关系” Step 3 (Block 3) Title: “协同设计与权衡机制” Bullets: “协同设计学习辨识器、动态事件触发与分布式控制协议” “保证学习参数与内部递归状态有界” “揭示学习率、触发参数、拓扑特征与一致性性能的定量关系” “建立一致性性能—通信次数—能耗开销的可计算权衡” Add-on icon near Step 3: A small triangular trade-off badge with vertex labels (Chinese): “一致性性能 / 通信次数 / 能耗开销” Caption next to triangle: “可计算权衡” Step 4 (Block 4) Title: “仿真分析与实验验证” Bullets: “搭建含未知非线性、扰动与通信约束的仿真平台” “对比不同触发规则、拓扑与学习精度下的性能与通信开销” “在多无人机与多机器人平台开展验证” “形成可推广的低通信、高可靠、可验证方法” Section B: Three mini-schematics (right side) Mini-panel 1: “闭环控制框架(流程图)” Draw a left-to-right flowchart with rounded blocks and arrows: Blocks (in order, Chinese text exact): “非线性多智能体系统” → “局部/邻域信息获取” → “一致性误差计算” → “学习辨识器(深度递归神经网络)” → “分布式控制器” → “动态事件触发器” → “网络传输与采样保持” → Back arrow to “非线性多智能体系统” Add two dashed feedback arrows from “一致性误差计算” to: “学习辨识器(深度递归神经网络)” (label: “误差驱动更新”) “动态事件触发器” (label: “误差驱动更新”) Add small notes: Under “动态事件触发器”: “按需通信/按需更新” Near “网络传输与采样保持”: “触发保持误差” Add a small timeline icon with ticks labeled in Chinese: “触发时刻…下一次触发时刻” and label “触发间隔”. Mini-panel 2: “耦合误差示意(维恩图)” Draw a three-circle Venn diagram with semi-transparent circles: Circle labels (Chinese): “学习辨识误差” (with RNN icon) “触发保持误差” (with clock + sample-and-hold icon) “拓扑耦合误差” (with network graph icon) Pairwise overlap labels: “学习更新×非均匀更新” “异步通信×拓扑传播” “分布式辨识×邻域耦合” Center overlap (bold): “耦合项集合” Under it: “影响一致性误差演化” Arrow from center to a right-side box titled “结果表征” with bullets: “收敛退化(渐近→最终有界)” “触发频繁/触发间隔变小” “稳态误差界增大/性能下降” Mini-panel 3: “深度递归神经网络示意(时间展开)” Draw a time-unrolled recurrent network schematic along a horizontal timeline labeled in Chinese: “上一时刻 → 当前时刻 → 下一时刻” At each time slice, show stacked recurrent blocks: Input label: “本体状态与邻域信息” → Middle label: “递归记忆状态” → Output label: “未知非线性与不确定项的在线辨识输出” Connect time slices with arrows labeled: “共享参数” Add a side arrow from “一致性误差” into a small box: “参数更新(投影/正则化/学习率调度)” Then arrow into: “学习参数更新” Style constraints BioRender clean scientific infographic, no photorealism, no clutter, high readability. Strict rule: do not include any math symbols, letters, equations, or subscripts. Negative prompt: Avoid photorealistic style, avoid dense paragraphs, avoid handwritten fonts, avoid low resolution, avoid formulas, avoid math letters.
136
Nano Banana
make a 3D infographic that illustrates software integration, with the writing: “architecture”, “components” and “data”, with a high-tech design. Show the software in the form of a HOLOGRAPHIC cube in the center with program codes. Around it, insert computers, screens, servers, server clouds and computer chips.
2120
FLUX
make a 3D image illustrating software integration, with the writing: “architecture”, “components” and “data”, with a high-tech design. Show the software in the form of a HOLOGRAPHIC cube in the center with program codes. Around it, insert computers, screens, servers, server clouds and computer chips.
186
FLUX
Modern corporate illustration of "Agentic Engineering" concept - Colombian software developer as orchestrator or architect in central elevated position with commanding perspective, actively supervising multiple specialized AI agents working in parallel on different aspects of development project. Developer in confident professional stance with directing gesture, one hand raised coordinating workflow, expression of focused professional control and collaboration. Elevated or privileged viewpoint showing developer overseeing organized system. Five distinct specialized AI agents represented as elegant geometric holographic forms, each clearly differentiated and working in their specific area: Architecture Agent with blueprint diagrams and system design visualizations, Code Generator Agent actively writing and structuring code, Testing Agent executing automated tests with results panels, Documentation Agent creating technical docs and diagrams, CI/CD Agent managing deployment pipeline and infrastructure. Each agent positioned in its own clear workspace panel or station around the developer, visually organized like specialized team members. Bidirectional communication lines flowing between developer and each agent - glowing data streams, approval checkmarks, guidance arrows showing active supervision not passive observation. All panels simultaneously visible showing complete development lifecycle: architecture blueprints, code syntax windows, test execution terminals, documentation pages, CI/CD pipeline flow. Atmosphere of professional control, organized collaboration, disciplined engineering approach. Developer clearly engaged in review, guidance, and decision-making, not just watching. Visual sense of "professional team" with AI agents as specialized colleagues under expert direction. Corporate color palette: deep professional blues, slate grays, crisp whites, cyan technological accents, emerald green highlights. Modern semi-realistic corporate digital illustration, clean professional composition with organized complexity. Clean abstract tech background with refined digital networks suggesting enterprise infrastructure. Soft professional lighting with depth emphasizing central orchestrator role. High resolution, sharp details, premium professional quality. Horizontal format optimized for blog section with clear recognizable focal point showing developer in control. No text overlays, no logos, no watermarks, no cartoon style, professional sophisticated aesthetic conveying serious engineering discipline.
024
Hero
Currently client is struggling with the current process where they need to manually manage the excel sheets, reporting process and tools not situated in one application. There is No clear visibility of resource allocation, reporting, budget, collaboration, reporting, project management, task management, time consuming. we came up with the proposed solution to improve productivity by eliminating manual work and bringing all project-related processes into one unified PPM tool which will Include key features such as project and task management, resource allocation, budget tracking, reporting and team collaboration- all within a single platform and the tool will replace manual excel-based processes and disconnected tools currently in use. please create the system architecture diagram for proposed system
0107
FLUX
make a 3D image illustrating software integration, with the writing: “architecture”, “components” and “data”, with a high-tech design. Show the software in the form of a HOLOGRAPHIC cube in the center with program codes. Around it, insert computers, screens, servers, server clouds and computer chips.
186
FLUX
Create a BioRender-style, publication-ready vector infographic titled “研究内容框架图” for a grant proposal. Use clean flat BioRender vectors, thick outlines, minimal shadows, consistent spacing, and a readable sans-serif font (Microsoft YaHei). Use a 16:10 landscape canvas (taller than 16:9). All text inside boxes must be Chinese exactly as specified. Do not include any mathematical letters, symbols, or formulas. Layout The figure has two main sections: Section A (left/center): Research Content Framework (main flowchart) A large framed panel with a top-down or left-to-right flow of four major blocks (Step 1 → Step 2 → Step 3 → Step 4). Each block is a rounded rectangle with a short title plus 2–4 bullet points. Add clear arrows between steps. Add a small triangle badge near Step 3 showing the trade-off. Section B (right side): Three embedded mini-schematics aligned vertically, each framed, with titles: “闭环控制框架(流程图)” “耦合误差示意(维恩图)” “深度递归神经网络示意(时间展开)” Use thin dashed connectors from the main Step 1–3 blocks to the corresponding mini-schematics to show correspondence. Icons (flat, minimal) Multi-agent network graph (nodes + edges), drones and mobile robots, wireless signal, clock/bell for event-triggering, sample-and-hold icon, neural network/RNN icon, Lyapunov/stability icon, and a balance scale icon (performance vs communication vs energy). Keep icons minimal and consistent. Chinese text to place in boxes (exact) Title (top center) “学习辨识—事件触发耦合下非线性多智能体系统分布式一致性控制与收敛性/有界性分析:研究内容框架图” Section A: Main research content framework (4 steps) Step 1 (Block 1) Title: “一致性误差机理刻画” Bullets: “建立统一闭环误差建模框架” “刻画学习误差、触发保持误差与拓扑耦合误差的交叉作用” “解释收敛退化、触发频繁与性能下降的成因” “覆盖无领导一致、领导跟随一致与协同跟踪场景” Step 2 (Block 2) Title: “低保守收敛性与有界性分析” Bullets: “显式利用触发区间信息构造分析工具” “建立收敛性与有界性判据并降低保守性” “推导误差上界、无有限时间无限触发条件与触发间隔下界” “刻画触发间隔与拓扑、触发参数、辨识精度的定量关系” Step 3 (Block 3) Title: “协同设计与权衡机制” Bullets: “协同设计学习辨识器、动态事件触发与分布式控制协议” “保证学习参数与内部递归状态有界” “揭示学习率、触发参数、拓扑特征与一致性性能的定量关系” “建立一致性性能—通信次数—能耗开销的可计算权衡” Add-on icon near Step 3: A small triangular trade-off badge with vertex labels (Chinese): “一致性性能 / 通信次数 / 能耗开销” Caption next to triangle: “可计算权衡” Step 4 (Block 4) Title: “仿真分析与实验验证” Bullets: “搭建含未知非线性、扰动与通信约束的仿真平台” “对比不同触发规则、拓扑与学习精度下的性能与通信开销” “在多无人机与多机器人平台开展验证” “形成可推广的低通信、高可靠、可验证方法” Section B: Three mini-schematics (right side) Mini-panel 1: “闭环控制框架(流程图)” Draw a left-to-right flowchart with rounded blocks and arrows: Blocks (in order, Chinese text exact): “非线性多智能体系统” → “局部/邻域信息获取” → “一致性误差计算” → “学习辨识器(深度递归神经网络)” → “分布式控制器” → “动态事件触发器” → “网络传输与采样保持” → Back arrow to “非线性多智能体系统” Add two dashed feedback arrows from “一致性误差计算” to: “学习辨识器(深度递归神经网络)” (label: “误差驱动更新”) “动态事件触发器” (label: “误差驱动更新”) Add small notes: Under “动态事件触发器”: “按需通信/按需更新” Near “网络传输与采样保持”: “触发保持误差” Add a small timeline icon with ticks labeled in Chinese: “触发时刻…下一次触发时刻” and label “触发间隔”. Mini-panel 2: “耦合误差示意(维恩图)” Draw a three-circle Venn diagram with semi-transparent circles: Circle labels (Chinese): “学习辨识误差” (with RNN icon) “触发保持误差” (with clock + sample-and-hold icon) “拓扑耦合误差” (with network graph icon) Pairwise overlap labels: “学习更新×非均匀更新” “异步通信×拓扑传播” “分布式辨识×邻域耦合” Center overlap (bold): “耦合项集合” Under it: “影响一致性误差演化” Arrow from center to a right-side box titled “结果表征” with bullets: “收敛退化(渐近→最终有界)” “触发频繁/触发间隔变小” “稳态误差界增大/性能下降” Mini-panel 3: “深度递归神经网络示意(时间展开)” Draw a time-unrolled recurrent network schematic along a horizontal timeline labeled in Chinese: “上一时刻 → 当前时刻 → 下一时刻” At each time slice, show stacked recurrent blocks: Input label: “本体状态与邻域信息” → Middle label: “递归记忆状态” → Output label: “未知非线性与不确定项的在线辨识输出” Connect time slices with arrows labeled: “共享参数” Add a side arrow from “一致性误差” into a small box: “参数更新(投影/正则化/学习率调度)” Then arrow into: “学习参数更新” Style constraints BioRender clean scientific infographic, no photorealism, no clutter, high readability. Strict rule: do not include any math symbols, letters, equations, or subscripts. Negative prompt: Avoid photorealistic style, avoid dense paragraphs, avoid handwritten fonts, avoid low resolution, avoid formulas, avoid math letters.
136
Nano Banana
make a 3D infographic that illustrates software integration, with the writing: “architecture”, “components” and “data”, with a high-tech design. Show the software in the form of a HOLOGRAPHIC cube in the center with program codes. Around it, insert computers, screens, servers, server clouds and computer chips.
2120
FLUX
make a 3D image illustrating software integration, with the writing: “architecture”, “components” and “data”, with a high-tech design. Show the software in the form of a HOLOGRAPHIC cube in the center with program codes. Around it, insert computers, screens, servers, server clouds and computer chips.
153
FLUX
In a vibrant blue background, the text "STEP 2" stands out prominently in a bold, mint green font, followed by a clear directive: "Plant the workflow of your web application" rendered in a softer white. Above the text is an illustrated laptop that features a simplified design, facing slightly toward the viewer, enhancing the message about web application workflow. Thin green lines emanate from the laptop, suggesting a flow or connection, contributing to the tech-oriented theme. The overall layout is clean and modern, emphasizing clarity and guidance for users embarking on web application development.
029
Ideogram
Modern corporate illustration of "Agentic Engineering" concept - Colombian software developer as orchestrator or architect in central elevated position with commanding perspective, actively supervising multiple specialized AI agents working in parallel on different aspects of development project. Developer in confident professional stance with directing gesture, one hand raised coordinating workflow, expression of focused professional control and collaboration. Elevated or privileged viewpoint showing developer overseeing organized system. Five distinct specialized AI agents represented as elegant geometric holographic forms, each clearly differentiated and working in their specific area: Architecture Agent with blueprint diagrams and system design visualizations, Code Generator Agent actively writing and structuring code, Testing Agent executing automated tests with results panels, Documentation Agent creating technical docs and diagrams, CI/CD Agent managing deployment pipeline and infrastructure. Each agent positioned in its own clear workspace panel or station around the developer, visually organized like specialized team members. Bidirectional communication lines flowing between developer and each agent - glowing data streams, approval checkmarks, guidance arrows showing active supervision not passive observation. All panels simultaneously visible showing complete development lifecycle: architecture blueprints, code syntax windows, test execution terminals, documentation pages, CI/CD pipeline flow. Atmosphere of professional control, organized collaboration, disciplined engineering approach. Developer clearly engaged in review, guidance, and decision-making, not just watching. Visual sense of "professional team" with AI agents as specialized colleagues under expert direction. Corporate color palette: deep professional blues, slate grays, crisp whites, cyan technological accents, emerald green highlights. Modern semi-realistic corporate digital illustration, clean professional composition with organized complexity. Clean abstract tech background with refined digital networks suggesting enterprise infrastructure. Soft professional lighting with depth emphasizing central orchestrator role. High resolution, sharp details, premium professional quality. Horizontal format optimized for blog section with clear recognizable focal point showing developer in control. No text overlays, no logos, no watermarks, no cartoon style, professional sophisticated aesthetic conveying serious engineering discipline.
024
Hero
Create a BioRender-style, publication-ready vector infographic titled “研究内容框架图” for a grant proposal. Use clean flat BioRender vectors, thick outlines, minimal shadows, consistent spacing, and a readable sans-serif font (Microsoft YaHei). Use a 16:10 landscape canvas (taller than 16:9). All text inside boxes must be Chinese exactly as specified. Do not include any mathematical letters, symbols, or formulas. Layout The figure has two main sections: Section A (left/center): Research Content Framework (main flowchart) A large framed panel with a top-down or left-to-right flow of four major blocks (Step 1 → Step 2 → Step 3 → Step 4). Each block is a rounded rectangle with a short title plus 2–4 bullet points. Add clear arrows between steps. Add a small triangle badge near Step 3 showing the trade-off. Section B (right side): Three embedded mini-schematics aligned vertically, each framed, with titles: “闭环控制框架(流程图)” “耦合误差示意(维恩图)” “深度递归神经网络示意(时间展开)” Use thin dashed connectors from the main Step 1–3 blocks to the corresponding mini-schematics to show correspondence. Icons (flat, minimal) Multi-agent network graph (nodes + edges), drones and mobile robots, wireless signal, clock/bell for event-triggering, sample-and-hold icon, neural network/RNN icon, Lyapunov/stability icon, and a balance scale icon (performance vs communication vs energy). Keep icons minimal and consistent. Chinese text to place in boxes (exact) Title (top center) “学习辨识—事件触发耦合下非线性多智能体系统分布式一致性控制与收敛性/有界性分析:研究内容框架图” Section A: Main research content framework (4 steps) Step 1 (Block 1) Title: “一致性误差机理刻画” Bullets: “建立统一闭环误差建模框架” “刻画学习误差、触发保持误差与拓扑耦合误差的交叉作用” “解释收敛退化、触发频繁与性能下降的成因” “覆盖无领导一致、领导跟随一致与协同跟踪场景” Step 2 (Block 2) Title: “低保守收敛性与有界性分析” Bullets: “显式利用触发区间信息构造分析工具” “建立收敛性与有界性判据并降低保守性” “推导误差上界、无有限时间无限触发条件与触发间隔下界” “刻画触发间隔与拓扑、触发参数、辨识精度的定量关系” Step 3 (Block 3) Title: “协同设计与权衡机制” Bullets: “协同设计学习辨识器、动态事件触发与分布式控制协议” “保证学习参数与内部递归状态有界” “揭示学习率、触发参数、拓扑特征与一致性性能的定量关系” “建立一致性性能—通信次数—能耗开销的可计算权衡” Add-on icon near Step 3: A small triangular trade-off badge with vertex labels (Chinese): “一致性性能 / 通信次数 / 能耗开销” Caption next to triangle: “可计算权衡” Step 4 (Block 4) Title: “仿真分析与实验验证” Bullets: “搭建含未知非线性、扰动与通信约束的仿真平台” “对比不同触发规则、拓扑与学习精度下的性能与通信开销” “在多无人机与多机器人平台开展验证” “形成可推广的低通信、高可靠、可验证方法” Section B: Three mini-schematics (right side) Mini-panel 1: “闭环控制框架(流程图)” Draw a left-to-right flowchart with rounded blocks and arrows: Blocks (in order, Chinese text exact): “非线性多智能体系统” → “局部/邻域信息获取” → “一致性误差计算” → “学习辨识器(深度递归神经网络)” → “分布式控制器” → “动态事件触发器” → “网络传输与采样保持” → Back arrow to “非线性多智能体系统” Add two dashed feedback arrows from “一致性误差计算” to: “学习辨识器(深度递归神经网络)” (label: “误差驱动更新”) “动态事件触发器” (label: “误差驱动更新”) Add small notes: Under “动态事件触发器”: “按需通信/按需更新” Near “网络传输与采样保持”: “触发保持误差” Add a small timeline icon with ticks labeled in Chinese: “触发时刻…下一次触发时刻” and label “触发间隔”. Mini-panel 2: “耦合误差示意(维恩图)” Draw a three-circle Venn diagram with semi-transparent circles: Circle labels (Chinese): “学习辨识误差” (with RNN icon) “触发保持误差” (with clock + sample-and-hold icon) “拓扑耦合误差” (with network graph icon) Pairwise overlap labels: “学习更新×非均匀更新” “异步通信×拓扑传播” “分布式辨识×邻域耦合” Center overlap (bold): “耦合项集合” Under it: “影响一致性误差演化” Arrow from center to a right-side box titled “结果表征” with bullets: “收敛退化(渐近→最终有界)” “触发频繁/触发间隔变小” “稳态误差界增大/性能下降” Mini-panel 3: “深度递归神经网络示意(时间展开)” Draw a time-unrolled recurrent network schematic along a horizontal timeline labeled in Chinese: “上一时刻 → 当前时刻 → 下一时刻” At each time slice, show stacked recurrent blocks: Input label: “本体状态与邻域信息” → Middle label: “递归记忆状态” → Output label: “未知非线性与不确定项的在线辨识输出” Connect time slices with arrows labeled: “共享参数” Add a side arrow from “一致性误差” into a small box: “参数更新(投影/正则化/学习率调度)” Then arrow into: “学习参数更新” Style constraints BioRender clean scientific infographic, no photorealism, no clutter, high readability. Strict rule: do not include any math symbols, letters, equations, or subscripts. Negative prompt: Avoid photorealistic style, avoid dense paragraphs, avoid handwritten fonts, avoid low resolution, avoid formulas, avoid math letters.
136
Nano Banana
make a 3D image illustrating software integration, with the writing: “architecture”, “components” and “data”, with a high-tech design. Show the software in the form of a HOLOGRAPHIC cube in the center with program codes. Around it, insert computers, screens, servers, server clouds and computer chips.
153
FLUX
make a 3D infographic that illustrates software integration, with the writing: “architecture”, “components” and “data”, with a high-tech design. Show the software in the form of a HOLOGRAPHIC cube in the center with program codes. Around it, insert computers, screens, servers, server clouds and computer chips.
2120
FLUX
In a vibrant blue background, the text "STEP 2" stands out prominently in a bold, mint green font, followed by a clear directive: "Plant the workflow of your web application" rendered in a softer white. Above the text is an illustrated laptop that features a simplified design, facing slightly toward the viewer, enhancing the message about web application workflow. Thin green lines emanate from the laptop, suggesting a flow or connection, contributing to the tech-oriented theme. The overall layout is clean and modern, emphasizing clarity and guidance for users embarking on web application development.
029
Ideogram
make a 3D image illustrating software integration, with the writing: “architecture”, “components” and “data”, with a high-tech design. Show the software in the form of a HOLOGRAPHIC cube in the center with program codes. Around it, insert computers, screens, servers, server clouds and computer chips.
186
FLUX
Currently client is struggling with the current process where they need to manually manage the excel sheets, reporting process and tools not situated in one application. There is No clear visibility of resource allocation, reporting, budget, collaboration, reporting, project management, task management, time consuming. we came up with the proposed solution to improve productivity by eliminating manual work and bringing all project-related processes into one unified PPM tool which will Include key features such as project and task management, resource allocation, budget tracking, reporting and team collaboration- all within a single platform and the tool will replace manual excel-based processes and disconnected tools currently in use. please create the system architecture diagram for proposed system
0107
FLUX
Modern corporate illustration of "Agentic Engineering" concept - Colombian software developer as orchestrator or architect in central elevated position with commanding perspective, actively supervising multiple specialized AI agents working in parallel on different aspects of development project. Developer in confident professional stance with directing gesture, one hand raised coordinating workflow, expression of focused professional control and collaboration. Elevated or privileged viewpoint showing developer overseeing organized system. Five distinct specialized AI agents represented as elegant geometric holographic forms, each clearly differentiated and working in their specific area: Architecture Agent with blueprint diagrams and system design visualizations, Code Generator Agent actively writing and structuring code, Testing Agent executing automated tests with results panels, Documentation Agent creating technical docs and diagrams, CI/CD Agent managing deployment pipeline and infrastructure. Each agent positioned in its own clear workspace panel or station around the developer, visually organized like specialized team members. Bidirectional communication lines flowing between developer and each agent - glowing data streams, approval checkmarks, guidance arrows showing active supervision not passive observation. All panels simultaneously visible showing complete development lifecycle: architecture blueprints, code syntax windows, test execution terminals, documentation pages, CI/CD pipeline flow. Atmosphere of professional control, organized collaboration, disciplined engineering approach. Developer clearly engaged in review, guidance, and decision-making, not just watching. Visual sense of "professional team" with AI agents as specialized colleagues under expert direction. Corporate color palette: deep professional blues, slate grays, crisp whites, cyan technological accents, emerald green highlights. Modern semi-realistic corporate digital illustration, clean professional composition with organized complexity. Clean abstract tech background with refined digital networks suggesting enterprise infrastructure. Soft professional lighting with depth emphasizing central orchestrator role. High resolution, sharp details, premium professional quality. Horizontal format optimized for blog section with clear recognizable focal point showing developer in control. No text overlays, no logos, no watermarks, no cartoon style, professional sophisticated aesthetic conveying serious engineering discipline.
024
Hero
Create a BioRender-style, publication-ready vector infographic titled “研究内容框架图” for a grant proposal. Use clean flat BioRender vectors, thick outlines, minimal shadows, consistent spacing, and a readable sans-serif font (Microsoft YaHei). Use a 16:10 landscape canvas (taller than 16:9). All text inside boxes must be Chinese exactly as specified. Do not include any mathematical letters, symbols, or formulas. Layout The figure has two main sections: Section A (left/center): Research Content Framework (main flowchart) A large framed panel with a top-down or left-to-right flow of four major blocks (Step 1 → Step 2 → Step 3 → Step 4). Each block is a rounded rectangle with a short title plus 2–4 bullet points. Add clear arrows between steps. Add a small triangle badge near Step 3 showing the trade-off. Section B (right side): Three embedded mini-schematics aligned vertically, each framed, with titles: “闭环控制框架(流程图)” “耦合误差示意(维恩图)” “深度递归神经网络示意(时间展开)” Use thin dashed connectors from the main Step 1–3 blocks to the corresponding mini-schematics to show correspondence. Icons (flat, minimal) Multi-agent network graph (nodes + edges), drones and mobile robots, wireless signal, clock/bell for event-triggering, sample-and-hold icon, neural network/RNN icon, Lyapunov/stability icon, and a balance scale icon (performance vs communication vs energy). Keep icons minimal and consistent. Chinese text to place in boxes (exact) Title (top center) “学习辨识—事件触发耦合下非线性多智能体系统分布式一致性控制与收敛性/有界性分析:研究内容框架图” Section A: Main research content framework (4 steps) Step 1 (Block 1) Title: “一致性误差机理刻画” Bullets: “建立统一闭环误差建模框架” “刻画学习误差、触发保持误差与拓扑耦合误差的交叉作用” “解释收敛退化、触发频繁与性能下降的成因” “覆盖无领导一致、领导跟随一致与协同跟踪场景” Step 2 (Block 2) Title: “低保守收敛性与有界性分析” Bullets: “显式利用触发区间信息构造分析工具” “建立收敛性与有界性判据并降低保守性” “推导误差上界、无有限时间无限触发条件与触发间隔下界” “刻画触发间隔与拓扑、触发参数、辨识精度的定量关系” Step 3 (Block 3) Title: “协同设计与权衡机制” Bullets: “协同设计学习辨识器、动态事件触发与分布式控制协议” “保证学习参数与内部递归状态有界” “揭示学习率、触发参数、拓扑特征与一致性性能的定量关系” “建立一致性性能—通信次数—能耗开销的可计算权衡” Add-on icon near Step 3: A small triangular trade-off badge with vertex labels (Chinese): “一致性性能 / 通信次数 / 能耗开销” Caption next to triangle: “可计算权衡” Step 4 (Block 4) Title: “仿真分析与实验验证” Bullets: “搭建含未知非线性、扰动与通信约束的仿真平台” “对比不同触发规则、拓扑与学习精度下的性能与通信开销” “在多无人机与多机器人平台开展验证” “形成可推广的低通信、高可靠、可验证方法” Section B: Three mini-schematics (right side) Mini-panel 1: “闭环控制框架(流程图)” Draw a left-to-right flowchart with rounded blocks and arrows: Blocks (in order, Chinese text exact): “非线性多智能体系统” → “局部/邻域信息获取” → “一致性误差计算” → “学习辨识器(深度递归神经网络)” → “分布式控制器” → “动态事件触发器” → “网络传输与采样保持” → Back arrow to “非线性多智能体系统” Add two dashed feedback arrows from “一致性误差计算” to: “学习辨识器(深度递归神经网络)” (label: “误差驱动更新”) “动态事件触发器” (label: “误差驱动更新”) Add small notes: Under “动态事件触发器”: “按需通信/按需更新” Near “网络传输与采样保持”: “触发保持误差” Add a small timeline icon with ticks labeled in Chinese: “触发时刻…下一次触发时刻” and label “触发间隔”. Mini-panel 2: “耦合误差示意(维恩图)” Draw a three-circle Venn diagram with semi-transparent circles: Circle labels (Chinese): “学习辨识误差” (with RNN icon) “触发保持误差” (with clock + sample-and-hold icon) “拓扑耦合误差” (with network graph icon) Pairwise overlap labels: “学习更新×非均匀更新” “异步通信×拓扑传播” “分布式辨识×邻域耦合” Center overlap (bold): “耦合项集合” Under it: “影响一致性误差演化” Arrow from center to a right-side box titled “结果表征” with bullets: “收敛退化(渐近→最终有界)” “触发频繁/触发间隔变小” “稳态误差界增大/性能下降” Mini-panel 3: “深度递归神经网络示意(时间展开)” Draw a time-unrolled recurrent network schematic along a horizontal timeline labeled in Chinese: “上一时刻 → 当前时刻 → 下一时刻” At each time slice, show stacked recurrent blocks: Input label: “本体状态与邻域信息” → Middle label: “递归记忆状态” → Output label: “未知非线性与不确定项的在线辨识输出” Connect time slices with arrows labeled: “共享参数” Add a side arrow from “一致性误差” into a small box: “参数更新(投影/正则化/学习率调度)” Then arrow into: “学习参数更新” Style constraints BioRender clean scientific infographic, no photorealism, no clutter, high readability. Strict rule: do not include any math symbols, letters, equations, or subscripts. Negative prompt: Avoid photorealistic style, avoid dense paragraphs, avoid handwritten fonts, avoid low resolution, avoid formulas, avoid math letters.
136
Nano Banana
make a 3D infographic that illustrates software integration, with the writing: “architecture”, “components” and “data”, with a high-tech design. Show the software in the form of a HOLOGRAPHIC cube in the center with program codes. Around it, insert computers, screens, servers, server clouds and computer chips.
2120
FLUX
Currently client is struggling with the current process where they need to manually manage the excel sheets, reporting process and tools not situated in one application. There is No clear visibility of resource allocation, reporting, budget, collaboration, reporting, project management, task management, time consuming. we came up with the proposed solution to improve productivity by eliminating manual work and bringing all project-related processes into one unified PPM tool which will Include key features such as project and task management, resource allocation, budget tracking, reporting and team collaboration- all within a single platform and the tool will replace manual excel-based processes and disconnected tools currently in use. please create the system architecture diagram for proposed system
0107
FLUX
In a vibrant blue background, the text "STEP 2" stands out prominently in a bold, mint green font, followed by a clear directive: "Plant the workflow of your web application" rendered in a softer white. Above the text is an illustrated laptop that features a simplified design, facing slightly toward the viewer, enhancing the message about web application workflow. Thin green lines emanate from the laptop, suggesting a flow or connection, contributing to the tech-oriented theme. The overall layout is clean and modern, emphasizing clarity and guidance for users embarking on web application development.
029
Ideogram
make a 3D image illustrating software integration, with the writing: “architecture”, “components” and “data”, with a high-tech design. Show the software in the form of a HOLOGRAPHIC cube in the center with program codes. Around it, insert computers, screens, servers, server clouds and computer chips.
186
FLUX
make a 3D image illustrating software integration, with the writing: “architecture”, “components” and “data”, with a high-tech design. Show the software in the form of a HOLOGRAPHIC cube in the center with program codes. Around it, insert computers, screens, servers, server clouds and computer chips.
153
FLUX