J.A.M.E.S - Explore AM Electronics Today

The Power Of AME
AME enables compact and cost-effective devices while allowing easy testing and adaptation before production. It eliminates complex manufacturing processes like traditional PCB assembly, suitable for small series or individualized single parts.
AME Vs. Traditional PCB
AME and traditional PCB manufacturing differ in terms of sustainability, logistics, and functionality. Traditional PCB uses acids in the etching process; the AME processes do not need the use of such substances, making it more environmentally friendly.
The Future Of AME
AME technology is advancing, promising greater precision in electronics production. Despite early stages, it shows potential in transforming the industry, with various applications for custom devices, rapid prototyping, and small-scale electronics.
Exploring The Future Of AME
Additive Manufacturing Electronics (AME) manufactures electronic components through 3D printing techniques. It involves layering materials to create functional structures that support the capability of electronic circuits or electromagnetic devices.
The Advantages Of AME
AME offers flexibility in production locations and reduces the need for inventory management of electronic components. Replacement electronics can be produced on demand, eliminating the need for a large stock of replacement PCBs in storage.
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Latest Articles
Advanced AME Equipment Enabling Surface Part Mounting Substrates

J.A.M.E.S And Friends Interview Series: Exploring AME Innovation With Fuji

About FPM-Trinity

AME Collection
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Advanced AME Equipment Enabling Surface Part Mounting Substrates

Introduction Of Advanced All In One Machine For AME And SMT Webinar

Design And Performance Of AM In-Circuit Board Planar Capacitors

Innovative Packaging With AME Technology Webinar

J.A.M.E.S And Friends Interview Series: Exploring AME Innovation With Fuji

Breaking Update: J.A.M.E.S And XTPL Redefining 3D Manufacturing

The Energy Consumption Of 3D Printers

Design Parameters For Additive Production Of Electronics Webinar

3D AME Ferrite Ring Core Coil

How To Design AME With CST Studio Suite Webinar

J.A.M.E.S & Nano Dimension Tech Talk Highlights

Historic E-guitar: Idea Pickguard AMEfication

Historic E-guitar: Idea Pickup AMEfication

J.A.M.E.S Coin With NFC Functionality

Introduction To CerAMfacturing At Fraunhofer IKTS

Exploring AME Webinar

Where Is 3D Printing Used?

J.A.M.E.S And TH-Rosenheim Foster Collaboration

RF-Interface Elements

AME Innovation: Harnessing The Power Of ESP-EYE

Explaining The CerAM Vat Photo Polymerization Based On JAMES Coin Design

RF-connector To AME Microstrip

From Concept To Qualified Product

About FPM-Trinity

Educational AME-Motor Experience Bundle

The Next Level Of 3D Printing

How To Design AME: An Overview

Historic E-guitar: Introduction And Idea Behind

The Steps Of AME Into A Qualified Product

Which 3D Printer Is More Sustainable?

Compact Multilayer Bandpass Filter

Additively Manufactured Millimeter-Wave

J.A.M.E.S And Fuji Corporation Join Forces To Drive Innovation In 3D Manufacturing

Is 3D Printing Eco-friendly?

J.A.M.E.S Partners With The Manufacturing Technology Centre (MTC) To Advance And Expand The Network Of AME

The Potential Of 3D Printed Electronics

Can A 3D Printer Print Electronics?

J.A.M.E.S And XTPL Join Forces In A Groundbreaking Collaboration

Exploring The Future Of 3D Electronics With Additive Manufactured Electronics (AME)

DragonFly IV Resolution Changer

DragonFly IV Logger

DragonFly IV Real Ink Status

DragonFly IV To LDM

DragonFly IV Alignment Of Print Jobs

Which 3D Printer Is Best

What 3D Printers Can Do

TH- Rosenheim University Students Visit J.A.M.E.S Office

Why 3D Printing Is The Future

Environmental Test Experience For An Antenna Application

3D Printing Materials Guide

Exploring The Different Processes In 3D Printing

AME And Micro-AM Tech Day Event

J.A.M.E.S Partnership With HeliguyTM Lab

J.A.M.E.S And Global Inkjet Systems Partnership

Historic E-guitar Meets AME

J.A.M.E.S Coin NFC On AME In 3D Ceramics

AME Antenna Array

Investigation Of Material Models For Fiber Reinforced Plastics

Simultaneous Manufacturing And Co-Sintering

Sequential Component Manufacturing

Sintering As A Feature Of The Process Chain

Advanced Ceramic And Conductive Materials

Populating DragonFly IV AMEs

Slicing For DragonFly IV

Design Data For DragonFly IV

Infrastructure For DragonFly IV

Design Parameters For The Additive Production Of Electronics

Introduction To AME And What It Can Do For You

Dragonfly IV Logs Collector Tool

Design AME Coils Tool

Design AME Capacitors Tool

Tutorials To Learn About AME

RF Synthesizer - 3D Heterogeneous Integration

AME Chip Heatsink Capacitor

J.A.M.E.S Coin NFC Side Mounted LED

J.A.M.E.S Coin NFC In AME

Brushless Motor Controller - PCB

J.A.M.E.S Coin NFC On AME - PrintC

Brushless Motor Controller – 3D Wires

AME 3D Test Coupon Testcase 1.0 PTC

J.A.M.E.S Coin NFC On AME 2D To 3D

AME 3D Test Coupon (Testcase 2.0)

J.A.M.E.S Coin NFC Flat Panel

J.A.M.E.S Coin NFC Business Card

J.A.M.E.S Coin NFC On AME - Freestyle

Brushless Motor Controller - Optimized For Pick And Place

StackUp_LF Coupon

Hardware Cyber Security By AME

Lumped AME Filters

AME Drone

J.A.M.E.S Coin Housing

3D AME Hybrid Structure Inlay

Induction Motor Design Concept

Axial Flux Motor

Coils And Caps Coupon

One Print-Job In Two Parts

An Introduction To 3D Printing

Electronics Printing

Silver Nanowires
