Electronics
Electronics Design for Connected Devices & Systems
We design circuit boards, power systems, and RF connectivity for consumer devices.
BLE, WiFi, and cellular connectivity are designed for real enclosures and coexistence.
Miniaturized layouts for wearables, implantables, and space-constrained devices.
Battery selection and power management are designed for multi-year operation.
IEC 60601 safety, EMC, and FDA design control are built into our workflow.
Electronics Engineering in connected systems
Hardware defines what your connected system can deliver.
Poor electronics architecture cascades through your entire product, forcing firmware workarounds, mechanical compromises, or products that can't meet regulatory requirements.
We design electronics with system-level constraints in mind, working across firmware, mechanical, and RF engineering to ensure electronics enable rather than limit your product.
The Result: Hardware that integrates cleanly with your connected system, meets regulatory requirements, and transitions to manufacturing without costly redesigns.
What We Solve For
Electronics Design & Engineering at Every Stage
Whether building from scratch, validating approaches, or resolving production issues, we bring the electronics depth you need.
Building New Products
You're designing device electronics and need a hardware architecture ready for regulatory testing and manufacturing.
Challenges we help prevent:
› Power Architecture
- › Battery dying faster than projected from underestimated BLE/WiFi power draw
- ›Sleep mode failing to reduce power consumption due to peripheral design
- ›Charging circuits causing safety failures or regulatory rejection
- › Power sequencing issues corrupting firmware or sensor data
› RF Integration & Performance
- ›Antenna detuned by enclosure materials or hand proximity
- ›BLE/WiFi range failing requirements in target environments
- ›Radio coexistence causing dropped connections or data corruption
- ›PCB layout creating self-interference discovered during EMC testing
› Regulatory-Ready Design
- ›Isolation barriers or leakage current failing IEC 60601 testing
- ›Inadequate ESD protection causing compliance failures
- ›Ground and shielding decisions blocking FCC and CE compliance
- ›Missing design documentation requiring expensive board respins
› Design for Manufacturing & Test
- ›Component obsolescence forcing redesigns mid-production
- ›Missing test points preventing calibration or field diagnostics
- ›Layout choices causing poor yields or field reliability issues
- ›Assembly problems discovered after tooling investment
Validating Feasibility
You need proof that the power budget, RF performance, and sensing accuracy will work under production conditions.
Scenarios we help answer:
› Power Budget Reality Check
- ›Battery life achievement with real connectivity patterns and wireless duty cycles
- ›Sleep mode effectiveness with actual peripheral and sensor configurations
- ›Power consumption staying within limits across all operating modes
- ›Charging performance meeting both speed and safety requirements
- ›Battery selection balancing capacity, form factor, cost, and chemistry requirements
› RF Performance in Enclosure
- ›Antenna range with mechanical design, materials, and hand loading
- ›BLE/WiFi connection reliability in target environments and use cases
- ›Radio coexistence without interference from other electronics
- ›RF compliance readiness through pre-scan testing
› Manufacturing & Supply Chain
- ›Component availability at target volumes with acceptable lead times
- ›Alternative parts existing for obsolescence risk mitigation
- ›BOM costs staying within budget at production volumes
- ›Contract manufacturer ability to source and assemble specified components
- ›Design testability for functional verification and production calibration
› Sensor & Analog Performance
- ›Analog front-end accuracy in target operating conditions
- ›Signal conditioning providing adequate signal-to-noise ratio
- ›Sensing approach handling environmental variations (temperature, humidity, EMI)
- ›Sensor feasibility validated via prototype with real-world data
Accelerating Development
You need electronics expertise to deliver production-ready hardware and meet your timeline.
Bottlenecks we help clear:
› Complete Hardware Design
- ›Schematic and layout taking longer than timeline allows
- ›Uncertainty about DFM and EMC considerations delaying PCB release
- ›Component selection paralysis from supply chain and cost tradeoffs
- ›Integration challenges between power, analog, and digital subsystems
› RF & Connectivity Implementation
- ›BLE/WiFi module integration consuming engineering bandwidth
- ›Antenna matching and tuning requiring specialized RF knowledge
- ›PCB layout uncertainty about grounding and isolation best practices
- ›Pre-compliance testing needed before committing to certification
› Design Validation & Testing
- ›Board bring-up revealing issues requiring fast diagnosis and fixes
- ›Hardware/firmware integration and rapid system validation
- ›Environmental testing uncovering thermal or reliability problems
- ›Missing design validation evidence needed for regulatory submission
- ›Gaps in test documentation delaying certification timeline
› Manufacturing Transition
- ›Production test strategy undefined or incomplete
- ›Manufacturing documentation insufficient for CM handoff
- ›First article builds revealing assembly or yield issues
- ›Lack of bandwidth to support CM questions and design reviews
Electronics Capabilities
Specialized Electronics Design for Connected Devices
Hardware design that enables reliable sensing, processing, and communication in regulated applications.
RF & Antenna Design ›
Wireless connectivity design for BLE, WiFi, cellular, and proprietary RF protocols in real enclosures with coexistence and regulatory constraints.
We design RF integration that accounts for mechanical constraints, hand loading, and multi-radio coexistence to achieve the required range and pass certification testing.
Key Capabilities:
› Antenna Design & Integration
- › Antenna selection for target frequency, range, and form factor
- › Custom antenna design for space-constrained or implantable devices
- › Antenna matching and tuning for target impedance
- › Placement optimization for enclosure constraints and hand proximity
- › Multi-antenna systems for diversity or MIMO
› Wireless Performance & Certification
- › Range and link budget optimization
- › Multi-radio coexistence (BLE, WiFi, cellular, proprietary)
- › Pre-compliance testing for FCC, CE, and wireless certifications
- › Radiated emissions and immunity testing preparation
› RF Protocol & Power Transfer
- › placeholder
PCB Design & Miniaturization ›
PCB layout for wearables, implantables, and space-constrained devices where size, flexibility, and signal integrity are critical.
We design high-density boards with rigid-flex, HDI, and advanced stackup techniques that meet miniaturization requirements without sacrificing performance or manufacturability.
Key Capabilities:
› Advanced PCB Technologies
- › Rigid, flex, and rigid-flex circuit design in Altium Designer
- › HDI (high-density interconnect) with microvias and buried vias
- › Layer stackup optimization for impedance control and EMI
- › Advanced materials for high-frequency or high-temperature applications
› Miniaturization & Packaging
- › Component placement for extreme space constraints
- › Via-in-pad and advanced assembly techniques
- › High-density mixed-signal integration (analog, digital, RF)
- › Thermal management in compact layouts
› Signal Integrity & Performance
- › High-speed signal routing and impedance matching
- › Crosstalk and EMI mitigation in dense layouts
- › Power distribution network (PDN) design for clean power delivery
- › Ground plane strategies for mixed-signal designs
Power Architecture & Battery Management ›
Power system design for connected devices requiring multi-year battery life, wireless charging, or precise power sequencing.
We architect power systems that deliver target battery life with real connectivity duty cycles while meeting safety and regulatory requirements.
Key Capabilities:
› Ultra-Low Power Design
- › Power budgeting across sleep, active, and transmission modes
- › Peripheral and sensor selection for low-power operation
- › Power sequencing and domain isolation
- › Leakage current minimization techniques
› Battery & Charging Systems
- › Battery chemistry selection and capacity sizing
- › Charging circuit design (linear, switching, wireless)
- › Fuel gauging and battery management systems
- › Battery protection and safety monitoring
- › Closed-loop charging for implantable systems
› Power Distribution & Regulation
- › Multi-rail power architecture design
- › Low-noise regulators for sensitive analog circuits
- › Switching regulator design and layout (SMPS)
- › Power-good sequencing and brownout protection
- › Load switching and hot-swap protection
Precision Analog Circuit Design ›
Analog front-ends for biosignal acquisition, sensor interfaces, and stimulation circuits requiring high accuracy and low noise.
We design analog signal chains that achieve required specifications in the presence of noise, interference, and real-world operating conditions.
Key Capabilities:
› Therapeutic & Stimulation Circuits
- › Electrical stimulation output stages with compliance monitoring
- › High-voltage stimulation and precision driver design
- › Charge balancing and safety-limited outputs
- › Isolation and patient-protection mechanisms
› Data Conversion & Processing
- › ADC selection and interface design (SAR, Delta-Sigma, Pipeline)
- › DAC interface design and reconstruction filtering
- › Anti-aliasing filter design
- › Analog reference design and noise management
- › Gain and offset calibration strategies
› Biosignal & Sensor Interfaces
- › ECG, EEG, EMG acquisition front-ends
- › Photoplethysmography (PPG) and optical sensing
- › Bioimpedance and impedance spectroscopy measurement
- › Temperature, pressure, and flow sensor interfaces
- › Chemical and electrochemical sensor conditioning
- › Strain gauge and load cell amplification
Electromechanical Integration ›
Electronics design for devices with motors, actuators, solenoids, and mechanical sensors requiring control circuits and feedback systems.
We design control electronics that integrate with mechanical systems while managing thermal constraints, position feedback, and enclosure integration.
Key Capabilities:
› Actuator Control & Drive Circuits
- › DC motor control circuits with PWM and current sensing
- › Stepper motor driver design and microstepping control
- › Brushless DC (BLDC) motor control
- › Solenoid and valve driver circuits
- › Haptic feedback implementation (LRA, ERM)
› Sensing & Feedback Systems
- › Position sensing (optical encoders, magnetic encoders, Hall effect)
- › Motion sensing (accelerometers, gyroscopes, IMU integration)
- › Force and torque measurement interfaces
- › Limit switch and safety interlock circuits
- › Proximity and contact detection
› Mechanical & Thermal Integration
- › Component placement for thermal management and airflow
- › Heatsink and cooling design for power components
- › Connector and cable design for mechanical constraints
- › Enclosure integration considerations (mounting, sealing, EMI)
- › Vibration and shock tolerance design
Certification & Regulatory Readiness ›
Electronics design with IEC 60601 safety margins, EMC considerations, and documentation practices required for medical device certification.
We design circuits and PCB layouts that support FDA submissions and international certifications without late-stage redesigns.
Key Capabilities:
› Medical Device Safety Standards
- › IEC 60601 electrical safety design (isolation, leakage current, protective earth)
- › Means of patient protection (MOPP) and means of operator protection (MOOP)
- › Applied part design and patient protection
- › Creepage and clearance requirements
- › Biocompatibility material selection and documentation
› EMC & Wireless Certification
- › EMC/EMI design for emissions and immunity (IEC 60601-1-2)
- › PCB layout techniques for EMC compliance
- › Shielding, filtering, and grounding strategies
- › Pre-compliance testing and troubleshooting
- › Wireless certification preparation (FCC Part 15/18, CE RED, IC)
› Design Documentation & Traceability
- › Design history file (DHF) documentation for electronics
- › Requirements traceability matrices
- › Design verification and validation evidence
- › Risk management documentation (ISO 14971) for hardware hazards
- › Change control and configuration management
Design for Manufacturing & Test ›
Electronics design with manufacturability, test access, and production validation built in from schematic through first article.
We design boards that transition to contract manufacturing with acceptable yields, test coverage, and field reliability.
Key Capabilities:
› Design for Manufacturability (DFM)
- › Component selection for supply chain stability and lifecycle
- › PCB design rules for fabrication and assembly yield
- › Panelization and depaneling strategy
- › Contract manufacturer coordination and design review
- › Cost optimization and value engineering
› Design for Test (DFT)
- › Test point placement and accessibility
- › Boundary scan (JTAG) and programming interface design
- › Built-in self-test (BIST) for critical subsystems
- › Test coverage analysis and fault isolation strategy
› Production Support & Validation
- › Production test fixture design and programming
- › Automated test equipment (ATE) integration
- › First article inspection and yield optimization
- › Calibration procedures and traceability
- › Engineering liaison between product teams and contract manufacturers
RF & Antenna Design
Wireless connectivity design for BLE, WiFi, cellular, and proprietary RF protocols in real enclosures with coexistence and regulatory constraints.
We design RF integration that accounts for mechanical constraints, hand loading, and multi-radio coexistence to achieve the required range and pass certification testing.
Key Capabilities:
› Antenna Design & Integration
- › Antenna selection for target frequency, range, and form factor
- › Custom antenna design for space-constrained or implantable devices
- › Antenna matching and tuning for target impedance
- › Placement optimization for enclosure constraints and hand proximity
- › Multi-antenna systems for diversity or MIMO
› Wireless Performance & Certification
- › Range and link budget optimization
- › Multi-radio coexistence (BLE, WiFi, cellular, proprietary)
- › Pre-compliance testing for FCC, CE, and wireless certifications
- › Radiated emissions and immunity testing preparation
› RF Protocol & Power Transfer
- › placeholder
PCB Design & Miniaturization
PCB layout for wearables, implantables, and space-constrained devices where size, flexibility, and signal integrity are critical.
We design high-density boards with rigid-flex, HDI, and advanced stackup techniques that meet miniaturization requirements without sacrificing performance or manufacturability.
Key Capabilities:
› Advanced PCB Technologies
- › Rigid, flex, and rigid-flex circuit design in Altium Designer
- › HDI (high-density interconnect) with microvias and buried vias
- › Layer stackup optimization for impedance control and EMI
- › Advanced materials for high-frequency or high-temperature applications
› Miniaturization & Packaging
- › Component placement for extreme space constraints
- › Via-in-pad and advanced assembly techniques
- › High-density mixed-signal integration (analog, digital, RF)
- › Thermal management in compact layouts
› Signal Integrity & Performance
- › High-speed signal routing and impedance matching
- › Crosstalk and EMI mitigation in dense layouts
- › Power distribution network (PDN) design for clean power delivery
- › Ground plane strategies for mixed-signal designs
Power Architecture & Battery Management
Power system design for connected devices requiring multi-year battery life, wireless charging, or precise power sequencing.
We architect power systems that deliver target battery life with real connectivity duty cycles while meeting safety and regulatory requirements.
Key Capabilities:
› Ultra-Low Power Design
- › Power budgeting across sleep, active, and transmission modes
- › Peripheral and sensor selection for low-power operation
- › Power sequencing and domain isolation
- › Leakage current minimization techniques
› Battery & Charging Systems
- › Battery chemistry selection and capacity sizing
- › Charging circuit design (linear, switching, wireless)
- › Fuel gauging and battery management systems
- › Battery protection and safety monitoring
- › Closed-loop charging for implantable systems
› Power Distribution & Regulation
- › Multi-rail power architecture design
- › Low-noise regulators for sensitive analog circuits
- › Switching regulator design and layout (SMPS)
- › Power-good sequencing and brownout protection
- › Load switching and hot-swap protection
Precision Analog Circuit Design
Analog front-ends for biosignal acquisition, sensor interfaces, and stimulation circuits requiring high accuracy and low noise.
We design analog signal chains that achieve required specifications in the presence of noise, interference, and real-world operating conditions.
Key Capabilities:
› Therapeutic & Stimulation Circuits
- › Electrical stimulation output stages with compliance monitoring
- › High-voltage stimulation and precision driver design
- › Charge balancing and safety-limited outputs
- › Isolation and patient-protection mechanisms
› Data Conversion & Processing
- › ADC selection and interface design (SAR, Delta-Sigma, Pipeline)
- › DAC interface design and reconstruction filtering
- › Anti-aliasing filter design
- › Analog reference design and noise management
- › Gain and offset calibration strategies
› Biosignal & Sensor Interfaces
- › ECG, EEG, EMG acquisition front-ends
- › Photoplethysmography (PPG) and optical sensing
- › Bioimpedance and impedance spectroscopy measurement
- › Temperature, pressure, and flow sensor interfaces
- › Chemical and electrochemical sensor conditioning
- › Strain gauge and load cell amplification
Electromechanical Integration
Electronics design for devices with motors, actuators, solenoids, and mechanical sensors requiring control circuits and feedback systems.
We design control electronics that integrate with mechanical systems while managing thermal constraints, position feedback, and enclosure integration.
Key Capabilities:
› Actuator Control & Drive Circuits
- › DC motor control circuits with PWM and current sensing
- › Stepper motor driver design and microstepping control
- › Brushless DC (BLDC) motor control
- › Solenoid and valve driver circuits
- › Haptic feedback implementation (LRA, ERM)
› Sensing & Feedback Systems
- › Position sensing (optical encoders, magnetic encoders, Hall effect)
- › Motion sensing (accelerometers, gyroscopes, IMU integration)
- › Force and torque measurement interfaces
- › Limit switch and safety interlock circuits
- › Proximity and contact detection
› Mechanical & Thermal Integration
- › Component placement for thermal management and airflow
- › Heatsink and cooling design for power components
- › Connector and cable design for mechanical constraints
- › Enclosure integration considerations (mounting, sealing, EMI)
- › Vibration and shock tolerance design
Certification & Regulatory Readiness
Electronics design with IEC 60601 safety margins, EMC considerations, and documentation practices required for medical device certification.
We design circuits and PCB layouts that support FDA submissions and international certifications without late-stage redesigns.
Key Capabilities:
› Medical Device Safety Standards
- › IEC 60601 electrical safety design (isolation, leakage current, protective earth)
- › Means of patient protection (MOPP) and means of operator protection (MOOP)
- › Applied part design and patient protection
- › Creepage and clearance requirements
- › Biocompatibility material selection and documentation
› EMC & Wireless Certification
- › EMC/EMI design for emissions and immunity (IEC 60601-1-2)
- › PCB layout techniques for EMC compliance
- › Shielding, filtering, and grounding strategies
- › Pre-compliance testing and troubleshooting
- › Wireless certification preparation (FCC Part 15/18, CE RED, IC)
› Design Documentation & Traceability
- › Design history file (DHF) documentation for electronics
- › Requirements traceability matrices
- › Design verification and validation evidence
- › Risk management documentation (ISO 14971) for hardware hazards
- › Change control and configuration management
Design for Manufacturing & Test
Electronics design with manufacturability, test access, and production validation built in from schematic through first article.
We design boards that transition to contract manufacturing with acceptable yields, test coverage, and field reliability.
Key Capabilities:
› Design for Manufacturability (DFM)
- › Component selection for supply chain stability and lifecycle
- › PCB design rules for fabrication and assembly yield
- › Panelization and depaneling strategy
- › Contract manufacturer coordination and design review
- › Cost optimization and value engineering
› Design for Test (DFT)
- › Test point placement and accessibility
- › Boundary scan (JTAG) and programming interface design
- › Built-in self-test (BIST) for critical subsystems
- › Test coverage analysis and fault isolation strategy
› Production Support & Validation
- › Production test fixture design and programming
- › Automated test equipment (ATE) integration
- › First article inspection and yield optimization
- › Calibration procedures and traceability
- › Engineering liaison between product teams and contract manufacturers
What You Get
Electronics Ready for Your Manufacturing Partner
We deliver tested electronics with the files, documentation, and traceability that manufacturers and regulators require.
Depending on your project scope, deliverables may include any of the following:
Schematics & PCB Layout Files
Bill of Materials (BOM)
Fabrication & Assembly Drawings
Design Verification Test Reports
EMC Testing Support
Design History Files (DHF)
How We Work
Electronics Designed Within Your Connected System
We design electronics as part of your connected system, with manufacturing and regulatory requirements built into our process from the start.
System-level Design
We design circuit boards within your full system architecture.
We review your system requirements, embedded software interfaces, power budgets, and sensor specifications before layout begins.
Our engineers work with your embedded, mechanical, and systems teams to align interfaces, timing, and protocols early. This prevents integration surprises and reduces rework from designing boards in isolation.
Design Controls
We build FDA design control requirements into our electronic workflow.
Design History Files are part of our process, not assembled at the end. We document design inputs, risk assessments, and verification plans as we design, creating the traceability FDA expects.
Our schematics, BOMs, and test plans support regulatory submissions and design transfer from the start, providing audit-ready documentation when you need it.
Incremental Validation
We validate electronic performance throughout design, not just at the end.
Circuit simulations, power analysis, and signal integrity reviews happen during schematic and layout phases. We validate critical subsystems as soon as prototypes arrive, identifying issues when changes are cheap. This catches thermal problems, EMC risks, and interface mismatches before they require expensive respins or delay validation.
Hardware Decisions Lock In More Than the Schematic
Let's talk about your design before the rest of the stack finds out.
Quick Discovery Call
Share what you're building, timelines, and constraints. We'll confirm fit and the next best step.
Team Consultation
We dig deeper into technical challenges, needs, and where we can add the most value.
Scope & Kickoff
We align on milestones, documentation, and delivery. Then we get moving and keep you informed.
We reply within 1–2 business days. NDA available.