File Information Extraction
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It looks like you want to pull information from a document, but I’ll need a bit more detail so I can construct the proper @file call.
Could you please let me know:
- Which file or datasheet URL you’d like me to query?
- Exactly what information you need extracted (e.g. “absolute maximum ratings,” “pin descriptions,” “electrical characteristics,” etc.)?
Once I have that, I can use the @file tool with the correct query format.
265 days
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242d 12:8:23
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242 days
Ready.
connect pin 10 of IC1 to Pin\_1 of J6
@copilot connect pin 10 of IC1 to Pin_1 of J6
1y
The connection format would be:
- Connect IC1:10 to J6:Pin1.
To perform this connection in Flux, you would draw a net between these two pins, ensuring you label the net appropriately. Let me know if you need further assistance!
1y
is there any convention i should follow in order to name the nets properly?
1y
Yes, there are some commonly followed conventions to name nets in a schematic for better readability and maintainability:
Common Naming Conventions:
-
Power Nets:
- VCC, VDD, VEE, VSS: Follow commonly accepted power net names.
- Voltage Level: Include voltage levels in net names (e.g., VCC_3V3 for 3.3V, VCC_5V for 5V).
-
Ground Nets:
- GND: The standard naming for ground nets.
- Specific Grounds: If you have separate grounds (analog, digital), name them AGND, DGND respectively.
-
Signals:
- Descriptive Names: Use names that describe the function of the signal (e.g., TXD for transmit data, RXD for receive data).
- Hierarchy/Grouping: Prefix with hierarchical or functional blocks (e.g., USB_D+ for USB data positive, FPGA_CLK for FPGA clock).
- Bus Signals: Use names that indicate they are part of a bus (e.g., DATA[7:0]).
-
Control Signals:
- Active Low: Usually indicated by a trailing underscore (e.g., RESET_, ENABLE_).
-
Test Signals:
- Test Points: Mark them as TP1, TP2, etc.
- Specific Test Names: If for specific functions, name accordingly (e.g., TEST_CLK).
For your specific connection:
- You could name the net something meaningful based on the function, such as
DCD_CTRLif the net connects to a Data Carrier Detect control line, or simplySIG_CONN.
Let's name it
Connecting them in Flux:
DCD_CONN for clarity.- Draw a net between
IC1:10andJ6:Pin_1. - Label the net with
DCD_CONN.
Would you like to proceed with any specific naming convention or address another question?
1y
6
TXL
VCC
TXL
DTR
+3V3
TX
RX
VCC
RXL
RSD
VCC
DATA_OUT
J1
RTS
CTS
RTS
J5
DCD
VCC
C1
Capacitance
100n F
R1
Resistance
0 Ω
CTS
J4
SLEEP
3V3OUT
TX
POWER
DATA_IN
R2
Resistance
1K Ω
RXL
R5
Resistance
10K Ω
LED3
TEN
GND
DATA_OUT
R3
Resistance
1K Ω
LED1
LED2
VCC
J3
+5V
PWREN
J2
VCC
DTR
RI
VCC
POWER
CTS
+5V
RSD
C3
Capacitance
1u F
DTR
SLEEP
RI
RX
TEN
TX
3V3OUT
J6
RX
DATA_IN
R4
Resistance
1K Ω
PWREN
DCD
JP1
IC1
End of Life
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Inspect
FT232RL Serial to USB C Module
Controls
Properties
Designator Prefix
SUBLAYOUT
Availability & Pricing
| Distributor | Qty 1 | |
|---|---|---|
| Arrow | $4.99–$5.01 | |
| Digi-Key | $3.48–$5.87 | |
| LCSC | $5.25 | |
| Mouser | $1.10 | |
| Verical | $4.97–$5.02 | |
Assets
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singhrohan
copilot
-
Power Connections:
- Connect $IC1:VCC$ to the 5V supply (Net6).
- Connect $IC1:3V3OUT$ to $J4:1$ and $J4:3$, providing 3.3V output.
- Ensure the $IC1:GND$ pins and capacitor grounds such as $C1:P2$ are connected to the ground (Net5).
-
USB Data Lines:
- $IC1:USBD+$ should connect to $J1:D+$ via Net2.
- $IC1:USBD-$ should connect to $J1:D-$ via Net4.
-
UART Interfaces:
- TXD (Transmit Data) from FT232RL: Connect $IC1:TXD$ to $J2:Pin_3$ via Net27.
- RXD (Receive Data) for FT232RL: Connect $IC1:RXD$ to $J2:Pin_2$ via Net25.
-
Capacitors:
- Place decoupling capacitors close to power pins. For $C1$, ensure it decouples right near power inputs.
- $C4:10uF$ capacitor should filter on the 5V rail (Net6), ensuring stable VCC.
-
Control Signals:
- Ensure connections for DTR, CTS, RTS, etc., are correctly mapped:
- DTR: $IC1:DTR$ connected to $DTR$ via Net20.
- CTS: $IC1:CTS$ connected to $CTS$ via Net28.
Recommendations:singhrohan
copilot
VBUSpins on the USB4105-GF-A connector to get a single voltage source. This is common practice on USB connectors to ensure that the voltage and current are evenly distributed across the pins, which helps in achieving reliable power delivery.J1:VBUS(Pins 3, 4, 13, 14) together to form a single voltage source.GNDpins for a consistent ground plane: