Schaltplan Überprüfung und Korrektur

1:04

Chat History

Project

Verstanden. Ich fasse dein Pin-/Block-Mapping zusammen und gleiche es mit deinem aktuellen Schaltplan ab, inkl. klarer Signalnamen für den PCB-Header.

A) Zentrale MCU: Teensy 4.1

Versorgung: 3V3 verteilt an alle Peripherien, I/O ist 3.3 V-kompatibel.
SD: BUILTIN_SDCARD, keine externe Buchse nötig.

B) Taster (Start/Stop)

Schaltung: U1:33_ → Taster → GND
Optional: 100 nF nach GND zum Entprellen. Falls gewünscht, kann ich einen 100nF Capacitor parallel zum Taster ergänzen.

C) IIS3DWB Kit über STEVAL-MKIGIBV2 Sockel, Interface SPI0

Teensy Pins zu Netznamen:
- Pin 10 → ACC_CS
- Pin 11 → SPI_MOSI
- Pin 12 → SPI_MISO
- Pin 13 → SPI_SCK
- 3V3 → 3V3
- GND → GND
Auf dem PCB: 2×12 Header für STEVAL-MKIGIBV2. Rausführen: 3V3, GND, SPI_SCK, SPI_MOSI (SDI), SPI_MISO (SDO), ACC_CS.
Optional/Empfohlen: INT1, INT2 zusätzlich auf den Header legen:
- U1:34_ ← INT1
- U1:35_ ← INT2
- Testpunkte TP5, TP6 sind bereits vorgesehen.

D) OLED SSD1306 (I2C, 0x3C)

Teensy Pins zu Netznamen:
- Pin 18 → I2C_SDA
- Pin 19 → I2C_SCL
- 3V3 → 3V3
- GND → GND
PCB 4-Pin-Header (von links nach rechts empfohlen): GND – 3V3 – SDA – SCL
Im Schaltplan korrigiert:
- U3:SDA → SDA, U3:SCL → SCL
- U3:5V ist derzeit an U1:5V geführt. Soll dieses OLED stattdessen an 3V3? Viele SSD1306-Module akzeptieren 3.3–5 V VCC, aber die I2C-Logik ist 3.3 V. Empfehlung: VCC = 3V3, um Level-Mismatch zu vermeiden. Soll ich [U3:5V] auf 3V3 umklemmen?
I2C-Pullups: R1 an SDA→3V3, R2 an SCL→3V3 vorhanden. Bitte Zielwert nennen (4.7 kΩ typ.). Ich kann Eigenschaften setzen.

E) Grove GPS (Air530, Seeed 109020022), UART über Grove-Buchse

Pins:
- GPS_TX (vom Modul) → Teensy RX2 Pin 7 → Net: GPS_RX_T4
- GPS_RX (zum Modul) → Teensy TX2 Pin 8 → Net: GPS_TX_T4
- VCC → bevorzugt 3V3
- GND → GND
Grove-Header-Reihenfolge nach Seeed-Standard: GND – VCC – GPS_TX – GPS_RX. Ich kann die Buchse J3 so beschalten und die Netznamen setzen.

F) SD-Karte

Keine externe SD-Buchse. Nur Teensy-intern, ok.

Offene Punkte zur Bestätigung:

OLED-Versorgung: VCC auf 3V3 statt 5V umklemmen? Dann verbinde ich [U3:5V] mit 3V3.
I2C-Pullups: Zielwert 4.7 kΩ für R1 und R2 bestätigen?
STEVAL Header: Soll ich INT1/INT2 zusätzlich auf den 2×12 Header legen oder nur intern zum Teensy führen?
Grove GPS VCC: 3V3 bestätigen, und Pin-Reihenfolge GND–VCC–GPS_TX–GPS_RX so festlegen?

Wenn du bestätigst, erstelle ich einen Ausführungsplan und setze die Änderungen direkt im Projekt um.

Fragen beantworten / Entscheidungen

Header-Pinout für IIS3DWB konkretisieren

Entprellkondensator Taster klären

I2C-Bus Erweiterbarkeit

Grove-GPS Level-Thema

116 days

Plan completed.

Show Plan

U2 INT1 - TP1 TP

U3 SDA - U1 18_

U2 CS - U1 10_

U2 SPC/SCL - U1 13_

Capacitance

Resistance

500 Ω

TP6

Resistance

4.7kΩ

U2 INT1 - TP1 TP

Resistance

500 Ω

J2 Pin_2 - J3 1

U1 3V3 - U2 VDD

J2 Pin_2 - J3 1

U1 33_ - J2 Pin_1

U1 G_1 - U1 G_2

U1 3V3 - U2 VDD

U1 G_1 - U1 G_2

U3 SDA - U1 18_

U2 INT2 - TP2 TP

U2 SDO/SA0 - U1 12_

U3 SDA - U1 18_

GND

U1 G_1 - U1 G_2

R4 P1 - U1 3V3

U2 SDI/SDO/SDA - U1 11_

U3 SDA - U1 18_

U1 G_1 - U1 G_2

U1 3V3 - U2 VDD

TP5

U2 INT1 - TP1 TP

U1 3V3 - U2 VDD

U2 SPC/SCL - U1 13_

J2 Pin_2 - J3 1

C6 P1 - R1 P1

U2 INT2 - TP2 TP

J2 Pin_2 - J3 1

Capacitance

J2 Pin_2 - J3 1

U1 G_1 - U1 G_2

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Project Name

Description

PCB Layout with Manual Component Placement by Interface

Properties

PWR3V3

3.3V_total_current

I2C

PWR3V3_required_width_mm

SPI

System Architecture

UART2

Pricing & Availability

Distributor	Qty 1
Arrow	$12.78–$14.32
Digi-Key	$53.92
LCSC	$23.54
Mouser	$54.49
Verical	$64.64–$67.39

Assets

Assets are files uploaded to this project which can be used in various ways.

Controls

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