Header plug, Rectangular Connectors, socket connector 2 pin, PCB header plug

Mini-Universal MATE-N-LOK 4 Position Dual Row Through-Hole Right Angle Header

https://www.futureelectronics.com/p/interconnect--pin-and-socket-connectors--header-plug-board-mount/5499922-6-te-connectivity-1136089

PCB header plug, LED chips, Pin headers, Receptacle housing, Pin receptacles

AMP-LATCH 26 Position Through-Hole Dual Row Straight 2.54 mm Pin Header

https://www.futureelectronics.com/p/interconnect--pin-and-socket-connectors--header-plug-board-mount/bm04b-srss-tb-lf-sn-jst-4527065

Angled pin headers, Pin Connector, Board Mount PCB Header, PCB header plug

BM04B Series 1 mm Pitch 4 Position SMT Single Row Top Entry Shrouded Header

https://www.futureelectronics.com/p/interconnect--pin-and-socket-connectors--header-plug-board-mount/1-794073-1-te-connectivity-3550126

Socket Connector Contacts, micro-plugs, Connectors, Plug connectors, Wire crimp

Mini-Universal MATE-N-LOK 8 Position Dual Row Through-Hole Straight Pin Header

What is a Headers Connector, PCB header plug, 2 pin header connector

DT Series 6 Position Dual Row Male Pin Panel Mount Header Connector

Plug wire, Socket Plug connectors, pin and socket connectors, pin headers

873 Series 6 A 3 Position Push Wire Luminaire Disconnect Connector

For future reference (my own and others), if your TI SilverLink USB cable stops working and starts showing up as "TUSB3410 Boot Device" or similar under device manager (AKA this issue on TI's help page), this is how you can fix it:

Download the TUSB3x10 EEPROM Burner. This is a Windows-only program, but to my knowledge will work on basically any windows machine from XP on -- so long as it's got USB ports. No clue if it'll work in a VM. (You might want to consult this user's manual.)

Download the SilverLink firmware. I got it from here, and compiled it from their de-compilation. It's just a standard 'make' to build. The output file you're looking for is called "ti_graph_link_silver.eep".

Rename "ti_graph_link_silver.eep" to "ti_graph_link_silver.bin".

Open the TUSB3x10 EEPROM Burner, click on the options dropdown and click "Show the 'Program Full Binary Image' button". (page 7 of the manual).

Select the entry under "Computer" labeled "TUSB3410 EEPROM Burner Instance (1.00)".

Set EEPROM size to "64Kb".

Set "File Path" to point to "ti_graph_link_silver.bin". (The renamed .eep, not the original .bin)

I don't know if the VID, PID, Manufacturer string, Product string and Serial # need to be set manually or not with a 'Full Binary Image' burn. Just to be safe, I set VID to 0451, PID to e001, Manufacturer to "Texas Instruments", Product to "TI-GRAPH LINK USB", and checked "Not Serialized"*.

Click the "Program Full Binary Image" button (yellow triangle with the exclamation point), and proceed with the write.

Unplug and re-plug your cable, and it should show up as a SilverLink again!

Additional notes:

The reason that this happens is because the SilverLink cable (revision b, at least) is based on the TUSB3410 microcontroller. That microcontroller's boot process involves checking for an I2C EEPROM containing program code. If it finds that EEPROM and its contents are properly formatted, it'll copy that code into internal RAM and start executing it. If it can't find the EEPROM, or its contents aren't properly formatted, it'll fall back to looking for boot code over USB. Thus: "TUSB3410 Boot Device". Your cable has, in essence, forgotten who it is and and is begging for you to give it a purpose.

The default page-write buffer size (32 bytes) and I2C bus speed (400 KHz) in the burner app are already correct, so no need to change them.

*I don't remember exactly what the Manufacturer string, Product string, or serial number fields were set to pre-corruption. Likewise, no idea about the advanced descriptor options. If someone wants to send the output of lsusb -v -s [whatever their silverlink's bus/id numbers are], I'd really appreciate it!

You might be able to skip the header rigamarole by taking the ti_graph_link_silver.bin file directly ("directly coming from the compiler") -- but I again I don't know exactly what information is in the .eep file and what isn't. Are the PID and VID encoded somewhere in there? I peeked with a hex editor but have no clue. If someone has hardware lying around they're willing to experiment with/potentially brick, I'd love to hear your results!

If you mess up and accidentally forget to do a "Full Binary Image" write, or otherwise brick the firmware, you can force the TUSB3410 to fall back to USB boot mode by opening the plastic shell around the PCB (one Torx screw under the sticker, then just normal plastic tabs) and shorting the right-bottom (Vss) and right-top (SDA), or right-bottom (Vss) and center right-top (SCL) pins of the EEPROM (the chip labeled "24LC64") as you plug it into the USB port. You may need multiple attempts. This works because it temporarily convinces the TUSB3410 that the EEPROM is missing/corrupt, and thus it decides to fall back into USB boot mode -- until you reset it. It might be better to do this with a ~1k resistor instead of a jumper wire, but IDK I'm not an electrical engineer. All I know is that shorting Vss and SDA worked for me. Again, would love feedback.

No clue what causes the corruption in the first place, or how long this fix will last. It might be because the EEPROM's write protect pin is set to "write enable"? It could also just be degrading hardware, for all I know, so no idea how long the fix will last. All I do know is that everything seems nominal right now (immediately after performing this procedure).

Good news: the PCB bus boards for my new Eurorack case came today!

Bad news: building and installing all of them requires 54 of the little 16-pin box headers, and I only actually have 10 on hand. And while I could order them, I really shouldn't until more money comes in, around about Friday.

At any rate, also included in the shipment were a couple of simple modules from Sourcery Studios: their ASMR (A Simple Mixer, Right?) five-channel mixer and their POW module, which provides power LEDs for each rail, a box header for plugging in modules for testing, and a USB-A jack for powering things from the 5V rail. (It also has a switch I won't be using, as it's meant for a different power setup than the one I'm using.) So I'll probably build those before I get to the actual case build.

"Why Wire-to-Board Connectors Matter in Today's Tech Landscape"

In the ever-evolving landscape of electronics and electrical engineering, wire-to-board (WTB) connectors are fundamental components that provide a secure, efficient link between a set of discrete wires and a printed circuit board (PCB). Despite their small size, these connectors are indispensable in a wide range of applications—from consumer electronics and automotive systems to industrial machinery and telecommunications.Get more news about Wire-to-board Connector,you can vist our website!

What Are Wire-to-Board Connectors? Wire-to-board connectors are used to route electrical signals or power from individual wires onto a printed circuit board. Unlike board-to-board connectors that facilitate connections between PCBs or wire-to-wire connectors that link individual wire sets, WTB connectors interface directly between a cable harness and the board, typically through soldering or press-fit terminals. This facilitates modular design, ease of maintenance, and scalable manufacturing.

They consist of two primary components: the plug (housing the wires) and the receptacle or header (mounted on the PCB). These connectors are available in various pitches (the center-to-center spacing between pins) and configurations (vertical or right-angle orientations), making them adaptable for a variety of design constraints and spatial limitations.

Key Features and Considerations Designers and engineers often evaluate several critical factors when selecting WTB connectors:

Current and Voltage Ratings: Depending on the application, connectors must meet safety and performance thresholds.

Pitch Size: Fine-pitch connectors (≤1 mm) allow for compact design, while larger pitches offer greater robustness.

Locking Mechanisms: Latch or friction locks ensure secure connections that resist vibration or accidental disconnection.

Material and Plating: Contact materials, often copper alloys with gold or tin plating, influence conductivity and longevity.

Environmental Resilience: Some WTB connectors are designed for harsh environments with resistance to moisture, dust, or high temperature.

Applications Across Industries The versatility of wire-to-board connectors is reflected in their widespread use across diverse industries:

Consumer Electronics: Used in smartphones, laptops, and wearable devices for internal signal and power connections.

Automotive: Essential for infotainment systems, sensors, and electronic control units (ECUs), where compact, vibration-resistant connectors are critical.

Medical Equipment: Connectors must meet stringent reliability and safety standards in devices like diagnostic equipment and patient monitors.

Industrial Automation: WTB connectors facilitate modular assembly and simplify maintenance for sensors, controllers, and interface devices.

Trends and Innovations Modern trends push the boundaries of connector miniaturization and performance. As electronic devices become more compact and sophisticated, the demand for high-density connectors with increased signal integrity and EMI shielding continues to grow. Additionally, some manufacturers are integrating features like surface-mount technology (SMT) compatibility and automated cable termination to streamline production and assembly.

Another key trend is the development of eco-friendly, RoHS-compliant connectors to meet global environmental standards while ensuring high performance. With the rise of Industry 4.0 and the Internet of Things (IoT), wire-to-board connectors are playing an increasingly strategic role in enabling smart, connected systems.

Conclusion Although often overlooked compared to high-profile semiconductors or processors, wire-to-board connectors are vital enablers of modern electronic innovation. Their reliability, precision, and adaptability allow designers to build smaller, more powerful, and more efficient systems. As technology continues to advance, the humble WTB connector will remain a quiet but essential hero in the background—connecting ideas to reality, one circuit at a time.

Wire mount sockets, PCB Header, board mount headers, header plugs

DEUTSCH 6 Position Rectangular Housing Connector Plug Gray

Transient voltage suppression diode

My studies during the past few months were Microcontrollers, 32 bit, LPC1769FBD100K, NXP, PCB header plug and Transient voltage suppression diode.

https://www.futureelectronics.com/p/interconnect--pin-and-socket-connectors--header-plug-board-mount/5787531-1-te-connectivity-5053790

Socket Connector, Ethernet jacks, IC socket adapters, wire connector pins

6 Position 2.5 mm Pitch Vertical PCB Through Hole Header

Buy ST-Link V2 Programmer at Affordable Price in Ainow

ST-Link V2 Programmer For STM8 and STM32 is fully consistent with the official version, support for automatic upgrades, support the full range STM32 SWD (only 4pins including SWCLK, SWDIO, and power) and a full range STM8 SWIM (only 4pins including SWIM, Reset and power) download and debug. Use this device to send program code to the 32-bit STM32 ARM Cortex or 8-bit STM8 microcontrollers. The header for this ST-Link v2 programmer contains connections for 5V, 3.3V, SWCLK, SWDIO, SWIM, Reset (RST/NRST) and GND. The connector on the opposite side of this device is a USB connector and is intended to be plugged into the computer.

Note: The product is available in Multiple colors Will be shipped randomly.

Supports For ST-LINK V2 Programmer:

ST-LINK Utility 2.0 and above.

STVD 4.2.1 and above.

STVP 3.2.3 and above.

IAR EWARM V6.20 and above.

IAR EWSTM8 V1.30 and above.

KEIL RVMDK V4.21 and above.

Features :

PCB installed inside of aluminum alloy U disk shell, portable, safe and reliable!

Interface definition directly marked on the shell, clear, convenient and practical!

5V, 3.3V offers at the same time, allowing you to program your target board with both 5V and 3.3V

Shell characters using laser engraving, never fade off! Permanent clarity!

500MA internal resettable fuse, complete protection of your expensive computer motherboard!

Red and blue color LED indicator, allowing you to always observe ST-LINK V2 working condition!

With 4 DuPont line, so you can easily respond to different target board line order!

Use anti-static bag packaging.

SWIM specific features:

SWIM cable for connection to the application via a pin header or a 2.54 mm pitch connector

1.65 V to 5.5 V application voltage supported on SWIM interface

SWIM low-speed and high-speed modes supported

SWIM programming speed rate: 9.7 Kbytes/s in low speed and 12.8 Kbytes/s in high speed

SWIM cable for connection to the application

Direct firmware update feature supported (DFU)

Status LED which blinks during communication with the PC

Operating temperature 0 to 50°C

What is a PCB Header, header plug, socket receptacle, Pin headers

DEUTSCH 6 Position Free Hanging Housings Plug Black Rectangular Connector