Analog IC Design Engineer

Cornhill, Greater London

5 days ago

Create job alert

Analog IC Design Engineer (Precision / BiCMOS)
Fully Remote / Berlin | €110,000 to €140,000 | Bonus and Share Scheme
We are seeking a Senior Precision Analog IC Design Engineer to join a technology leader in silicon photonics-based interconnect solutions (data speeds of 200gb/s to 400gb/s). They company offers cointegrated semiconductor chips for next generation data centres using in-house PIC and EIC design capabilities and large-volume CMOS foundries as manufacturing partners. You’ll be joining a team of highly professional design engineers and managers with many years of experience in bringing state-of-the-art products to the market.

Requirements of the role:

Design Analog Circuits in BiCMOS for OpAmps, Regulators, PVT independent biasing, high-speed circuits, control loops including nested loops (DC offset cancellation, Receive Signal Strength Indicator, Loss of Modulation, Loss of Signal, Squelch, AGC), analog based digital gates, analog muxes and be able to build a chip-level schematic hierarchy in Cadence environment.
Design of auxiliary circuits to interface analog ICs with I2C or SPI type digital control interfaces (using IP-blocks eg. ADC).
Design I/O interfaces with ESD protection.
Develop IC pad frame (pad layout) for various technologies such as die bonding, flip-chip, micro-bumps.
Run regression simulation and meet specs.
Leverage your familiarity with layout techniques for device matching, current density and low parasitics. Check LVS/DRC of your circuits.
Develop Product Specs and block level specs for your circuits by interfacing with marketing.
Support IC Design verification methodology to meet spec compliance matrix.
Interface with foundry and make sure PDK updates are all up to date.
Develop testing strategy for your circuits and sync up with test team.
Support IC to qualification and production. Support Customer request for technical support.
Interface with Cadence and other Vendors to make sure tools are functional and monitor possible upcoming license issues.Salary and Benefits

Basic Salary in the range €110,000 to €140,000 dependent of experience
Fully remote working with option for occasional fully expensed travel to Berlin high-tech HQ (Applications are also welcome from candidates who would rather work onsite or hybrid in Germany)
Company Bonus (based on individual / company related targets e.g. outcomes of wafer run or successful implementation of simulation models)
Employee Share Scheme (6 vesting periods for the next 3 years)
High degree of personal responsibility within a flat company hierarchy
Ambitious internationally expanding team
Various future career opportunities for every career level

Subscribe to Future Tech Insights for the latest jobs & insights, direct to your inbox.

Industry Insights

Discover insightful articles, industry insights, expert tips, and curated resources.

Feb 12, 2026

Careers

How Many Semiconductor Tools Do You Need to Know to Get a Semiconductor Job?

If you’re pursuing a career in the semiconductor industry, it can feel like you’re expected to master an endless list of tools, software packages and lab equipment before you even submit a CV. One job advert wants experience with TCAD and process simulation, another mentions SPICE and yield tools, while yet another asks for test automation platforms, yield analysis software, hardware description languages, EDA suites and hundreds of others. With so many technical names thrown around, it’s easy to fall into “tool anxiety” — the feeling that you’re behind because you don’t know every piece of software, every lab instrument and every process control suite. Here’s the honest truth most semiconductor hiring managers won’t say out loud: 👉 They don’t hire you because you know every tool — they hire you because you can use the right tools to solve real engineering problems and explain your reasoning clearly. Tools matter, absolutely. But they exist to help you deliver measurable results — not to be collected like badges. So how many semiconductor tools do you actually need to know to get a job? The answer is a lot fewer than you might think — and far more focused on core capabilities than a long checklist. This guide breaks down what employers really value, which tools are essential, which are role-specific, and how to focus your learning so you are confident and credible.

Feb 3, 2026

Jobs

What Hiring Managers Look for First in Semiconductor Job Applications (UK Guide)

The semiconductor industry is fast-moving, highly technical and critically important to modern technology. Whether you’re targeting roles in device design, process engineering, yield improvement, test and validation, equipment engineering, reliability, failure analysis or fab operations, hiring managers are selective and deliberate in how they review applications. Most candidates still make the same mistake: they throw generic skill lists and duty statements at recruiters and hope it sticks. In reality, hiring managers make an early call — often within the first 10–20 seconds — based on a few key signals that tell them whether you’re a credible, relevant, impactful candidate. This article breaks down exactly what hiring managers look for first in semiconductor job applications — how they scan your CV, portfolio and cover letter, what makes them read deeper, and what causes strong candidates to be passed over in favour of others.

Jan 24, 2026

Education

The Skills Gap in Semiconductor Jobs: What Universities Aren’t Teaching

The semiconductor industry lies at the heart of modern technology. From smartphones and data centres to autonomous vehicles, medical devices and defence systems, semiconductors power the digital age. The UK is investing heavily in semiconductor research, fabrication and talent development as part of its industrial strategy — yet employers continue to report a persistent problem: Many graduates are not job-ready for semiconductor roles. Despite strong academic programmes in engineering, physics and materials science, there remains a tangible skills gap between what universities teach and what semiconductor employers actually need. This article explores that gap in depth: what universities do well, where there are consistent shortfalls, why the divide persists, what employers genuinely want, and how jobseekers can bridge the gap to build successful careers in the semiconductor sector.