AI Systems & Platform Internals - Technical Architect

Accellor is an AI-native services firm purpose-built for the post-ChatGPT era. Free from legacy constraints, we focus on delivering measurable business outcomes through advanced AI, data, and engineering capabilities. Our mission is to operationalize AI at scale and unlock sustained enterprise value.

Our offerings span AI solutions, data services, enterprise applications, and product engineering, tailored to industry-specific needs across healthcare, life sciences, telecom, retail, financial services, and technology. By leveraging design thinking and technology-agnostic architectures, we ensure faster time-to-value and seamless interoperability.

With a proven track record of enabling Fortune 100 enterprises and global innovators, Accellor stands as a trusted partner for organizations seeking to harness the full potential of AI. Our vision is clear: to build intelligent, connected ecosystems that deliver measurable outcomes and redefine the future of enterprise transformation.

Technical Architect — AI Systems & Platform Internals

Experience: 10–12 Years

Role Type: Technical Architect / Staff-Level Systems Architect

Role Summary

Accellor is looking for a Technical Architect — AI Systems, Inference & Platform Internals to help design, scale, and optimize the systems that power ChatGPT, OpenAI API, Codex, agentic systems, multimodal experiences, and internal research workloads.

This role is focused on the internal AI systems stack, including inference runtime, model serving, GPU infrastructure, distributed systems, context engineering, cost optimization, evaluation gates, observability, release safety, and production reliability.

The ideal candidate is a senior hands-on architect who can reason across the full AI platform — from GPU-level performance and distributed inference to product-scale reliability, model deployment, safety, and cost-efficient operations.

Key Responsibilities

1. AI Systems Architecture

Design and evolve large-scale AI systems that support ChatGPT, OpenAI API, Codex, agentic workflows, multimodal models, and research workloads.

Define architecture across inference runtime, model serving, request routing, batching, KV-cache handling, GPU scheduling, distributed execution, observability, release gates, and production rollout.

Own technical trade-offs across latency, throughput, reliability, correctness, safety, scalability, cost, and infrastructure efficiency.

2. Inference Runtime & Model Serving

Architect high-throughput, low-latency inference systems across large-scale GPU clusters.

Work across inference engines, serving layers, scheduling systems, caching, streaming, deployment pipelines, and runtime optimization.

Partner with engineering teams to improve model-serving efficiency, tail latency, GPU utilization, memory efficiency, correctness under load, and cost per request.

Guide architecture decisions involving PyTorch, JAX, Triton, vLLM-style serving, CUDA/Triton kernels, distributed inference, tensor parallelism, pipeline parallelism, model sharding, and long-context serving.

3. GPU, Kernel & Distributed Performance

Analyze and improve performance across GPU kernels, memory movement, collective communication, orchestration, and runtime scheduling.

Guide engineering decisions involving CUDA, Triton, NCCL/RCCL, GPU profiling, memory pressure, compute utilization, tensor layouts, interconnect behavior, and distributed execution.

Identify system-level bottlenecks across compute, memory, networking, scheduling, model execution, and data movement.

4. Context Engineering

Design and guide context engineering frameworks that determine what information should be passed to the model, how it should be structured, how much context should be used, and how context quality should be measured.

Own architecture patterns for prompt structure, dynamic context assembly, retrieval-augmented generation, long-context management, conversation memory, tool context, agent state, multimodal context, source grounding, permission-aware retrieval, context compression, and context auditability.

Ensure AI systems use the right context, from the right source, with the right permissions, at the right cost, and with measurable quality.

5. Cost Optimization Frameworks

Design and build cost optimization frameworks for large-scale LLM and GenAI workloads.

Create architecture patterns that reduce unnecessary token usage, redundant retrieval, repeated model calls, inefficient inference paths, and avoidable infrastructure spend.

Drive model routing, token budgeting, prompt compression, context pruning, semantic caching, response caching, batch inference, async execution, fallback strategies, and cost telemetry across AI workflows.

Ensure cost optimization does not compromise quality, safety, grounding, reliability, or user experience.

6. Training & Research Infrastructure

Collaborate with research and training infrastructure teams to support large-scale model training and post-training workflows.

Contribute to architecture around distributed training, checkpointing, orchestration, fault tolerance, observability, data movement, evaluation infrastructure, and experiment velocity.

Support frontier model workflows across pre-training, post-training, reinforcement learning, agent training, evaluation harnesses, and large-scale experiment execution.

7. Release Safety, Validation & Evaluation Gates

Architect validation and release systems that ensure model updates, inference engine changes, runtime images, prompt changes, context changes, and platform releases are correct, safe, performant, and regression-free.

Define release gates across correctness, numerical stability, latency, throughput, token usage, cost regression, context quality, retrieval quality, safety behavior, reliability, and model output quality.

Ensure platform optimizations do not reduce safety, grounding, quality, or user trust.

8. Reliability, Observability & Production Operations

Design systems that make AI infrastructure observable, debuggable, reliable, and operationally safe.

Define telemetry, tracing, dashboards, alerts, logs, profiling views, runbooks, SLOs, and post-incident learning loops.

Provide visibility into prompts, context payloads, retrieved sources, token consumption, model selection, cache behavior, inference latency, GPU utilization, evaluation scores, safety events, cost, and failures.

Turn production issues into stronger platform abstractions, safer rollout mechanisms, better automation, and more reliable infrastructure.

9. Agentic & Multimodal Platform Internals

Support architecture for AI agents, tool use, memory, function calling, multimodal interaction, long-running workflows, and internal or external agent deployment.

Work across agent harnesses, evaluation pipelines, workflow orchestration, safety controls, state management, tool execution, memory systems, and product-facing runtime constraints.

Ensure agentic and multimodal systems are reliable, observable, secure, cost-aware, and safe under real workloads.

10. Technical Leadership

Work closely with Research, Inference, Runtime, Infrastructure, Product, Safety, Security, Technical Success, and Deployment teams.

Act as a senior technical authority who can cut across layers, resolve ambiguity, identify systemic risks, and drive architecture decisions.

Mentor engineers and technical leads on distributed systems, performance engineering, context engineering, cost optimization, production readiness, AI platform design, and architecture trade-offs.

Represent architecture decisions through design docs, RFCs, diagrams, technical reviews, operational plans, and leadership-level summaries.

Requirements

Required Qualifications

• 10–12 years of experience in software engineering, systems architecture, ML infrastructure, distributed systems, platform engineering, inference systems, cloud infrastructure, or large-scale backend engineering.
• Strong hands-on engineering experience with Python and at least one systems/backend language such as C++, Go, Rust, Java, or TypeScript.
• Deep understanding of distributed systems, production infrastructure, reliability engineering, scalability, observability, and fault-tolerant architecture.
• Experience designing or operating large-scale systems involving APIs, microservices, distributed compute, orchestration, job scheduling, caching, high-availability infrastructure, and production monitoring.
• Strong understanding of AI/ML systems, especially model serving, inference workflows, context engineering, retrieval systems, evaluation pipelines, and production model deployment.
• Practical understanding of GPU systems, accelerator-based workloads, CUDA/Triton-style programming, distributed inference, GPU profiling, memory optimization, and communication libraries such as NCCL or RCCL.
• Experience with ML frameworks and serving stacks such as PyTorch, JAX, TensorFlow, Triton, vLLM-style serving, Apache Ray, Kubernetes-based serving, or internal model-serving systems.
• Ability to debug complex problems across model behavior, runtime systems, distributed infrastructure, networking, GPU execution, context quality, retrieval quality, evaluation harnesses, and production services.
• Strong communication skills with the ability to write clear architecture documents, evaluate trade-offs, review implementation quality, and align teams around technically sound decisions.

Preferred Qualifications

• Experience working on LLM inference, multimodal inference, agent infrastructure, AI assistants, coding agents, or frontier-model serving platforms.
• Experience with tensor parallelism, pipeline parallelism, model sharding, KV-cache optimization, batching, speculative decoding, streaming inference, and long-context serving.
• Experience designing context engineering platforms, prompt/version management systems, model-routing frameworks, semantic caching layers, token-budgeting systems, or LLM cost dashboards.
• Experience profiling GPU workloads using Nsight Systems, Nsight Compute, rocprof, perf, Prometheus, Grafana, OpenTelemetry, or custom profiling systems.
• Experience with large-scale distributed training, RL infrastructure, checkpointing, ML compiler optimizations, model graph transformations, or training runtime systems.
• Experience designing release gates, regression detection systems, canary systems, CI/CD validation frameworks, and production safety controls for performance-sensitive infrastructure.
• Experience with evals, model quality measurement, hallucination detection, grounding evaluation, safety testing, and model behavior monitoring.

Technical Skill Areas

AI Systems: LLM serving, inference runtime, training infrastructure, post-training workflows, agent systems, multimodal models

Inference: batching, routing, KV-cache, streaming, latency optimization, model serving, tensor parallelism, pipeline parallelism

Performance Engineering: CUDA, Triton, GPU profiling, kernel optimization, memory bandwidth, communication libraries, distributed execution

Context Engineering: prompt architecture, dynamic context assembly, RAG, memory, context compression, context ranking, source grounding, permission-aware retrieval

Cost Optimization: token budgeting, caching, model routing, fallback strategies, cost telemetry, batching, async workflows, cost-quality trade-offs

Distributed Systems: scheduling, orchestration, reliability, fault tolerance, observability, scalability, service design

ML Frameworks: PyTorch, JAX, TensorFlow, Triton, vLLM-style serving, Ray

Infrastructure: Kubernetes, Docker, Terraform, CI/CD, cloud platforms, Linux systems, networking, storage

Safety & Validation: evals, release gates, canaries, regression testing, model behavior validation, rollout safety

Candidate Profile

The ideal candidate is a senior hands-on architect who can operate across the full AI systems stack.

They should be able to discuss GPU memory bottlenecks, distributed inference, model-serving reliability, context quality, cost optimization, release validation, eval pipelines, observability, and production rollout with engineering teams, while also explaining architecture decisions clearly to senior leadership.

The candidate should not be limited to architecture diagrams. They must be capable of reviewing implementation quality, identifying bottlenecks, debugging production issues, challenging weak assumptions, and converting repeated failures into stronger platform abstractions.

This role requires the judgment of a senior architect, the debugging mindset of a systems engineer, and the ownership mindset required for production AI infrastructure.