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Success criteria review
  • โŒ Le schema ne satisfait pas completement le cahier des charges: le supercondensateur 3.3 F / 2.7 V n a pas pu etre ajoute avec une empreinte exploitable depuis la bibliotheque.
  • โŒ Le PCB est bien fixe a 14 x 14 mm, mais les empreintes disponibles pour les pads pogo et les composants choisis depassent tres largement la surface utile, donc la contrainte mecanique n est pas realisable avec les parts actuellement disponibles.
  • โŒ La zone RF keep-out sous antenne et la reserve mecanique autour du supercondensateur n ont pas pu etre finalisees de maniere credible car il manque un module BLE compact avec antenne integree dans la bibliotheque et le supercondensateur exact.
Next steps Je suis bloque par la disponibilite des composants/empreintes de la bibliotheque pour ce format 14 x 14 mm. Si vous voulez, je peux poursuivre immediatement dans l une de ces directions: remplacer U1 par un module BLE reel plus compact si vous me fournissez un MPN ou un fichier, ou bien reconstruire ce design autour de composants/empreintes minimales compatibles 14 x 14 mm.
Choisir le module BLE
Ajouter les pogo pads
Fixer lโ€™alimentation
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Project Specification
Scope
Ultra-compact Smart Dice BLE on a 14 x 14 mm PCB powered directly from a 3.3 F / 2.7 V supercapacitor over a usable rail range of 2.7 V down to 1.7 V.
System Architecture
Diagram



  
    
  
  
    
  







INT1

VCC GND SWDIO SWCLK RESET





Supercapacitor 3.3F 2.7V
Direct VCC rail 2.7V to 1.7V
nRF52810 BLE module
BMA400 accelerometer
5 pogo pads
Key Requirements
  • PCB size fixed at 14 x 14 mm
  • Direct supply from supercapacitor without intermediate regulator
  • BLE module based on nRF52810 with integrated antenna and RF keep-out under antenna
  • Bosch BMA400 connected over I2C with interrupt wake line to the BLE module
  • 5 pogo pads for VCC, GND, SWDIO, SWCLK, and RESET
  • Mandatory passives for decoupling, reset biasing, and I2C pull-ups
  • Mechanical routing corridor around the central supercapacitor body
Initial Engineering Decisions
  • Use direct VCC rail from the supercapacitor for lowest quiescent loss
  • Place BLE module at the board edge so the antenna faces outward
  • Use one shared I2C bus with one pull-up pair for the BMA400
  • Use an interrupt-capable GPIO for motion wake-up from low-power mode
Design Summary
Status: Draft / Review / Approved
Manufacturing target: Prototype / EVT / DVT / PVT / Production
Software / firmware: repository link
Scope
Purpose
In scope
Out of scope
System context
Requirements
Functional
Electrical
Mechanical / environmental
Key constraints
Dependencies and risks
Dependencies
Key risks
Validation
Success criteria
Planned checks
Release-facing notes
Expected deliverables
Special release notes
Change notes / open questions
Changes in this revision
Open questions

    Scope

    System Architecture

    Key Requirements

    Initial Engineering Decisions

    Design Summary

    Scope

    System context

    Requirements

    Functional

    Electrical

    Mechanical / environmental

    Key constraints

    Dependencies and risks

    Validation

    Release-facing notes

    Change notes / open questions

Documents

    Project Specification

    design-notes

Assets

No assets added.

Smart Dice Supercap BLE

Smart Dice Supercap BLE thumbnail
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Properties

Properties describe core aspects of the project.

Pricing & Availability

Distributor

Qty 1

Arrow

$3.42

Digi-Key

$3.35โ€“$5.00

LCSC

$3.36

Mouser

$1.95

Verical

$4.24โ€“$7.98

Controls