Schematic Symbol for Universal Development Board for 8051, PIC,...

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https://cdn2.flux.ai/flux-comment-files/files/commentFileId-c0f4310c9e3255bbcfaa...

singhrohan

https://cdn2.flux.ai/flux-comment-files/files/commentFileId-c0f4310c9e3255bbcfaa2c57d968c32f7838fe9fe3fae47d844dfb9052548c90.jpeg?GoogleAccessId=graviton-mvp%40appspot.gserviceaccount.com&Expires=4872031734&Signature=kPo64hqGx6RLUZJfNdqtFFO5utx%2BwYqgeXuNS%2Fx4GRLkNzD25oyph2IXotzsRgM5FaXNBtKicsm4CVHIPOMwdcjw8%2Fh0CcaSKIYqSy0PD4lo1jcK87b7O8jibAkTIxwWaH2Q1V5Ih%2BjEtDJG9jR64AbO%2B42yh5D8kwCvrpVbMoqQUMx7GNeuTt7M9gFo42P3AoUoOKmfRYiumvIh8fBvg%2FuFr%2F8MuY%2B7IViNMfOwEKqdNDd1so1%2F3bO0ALQ6mrl46kEXnWeacxaOmY%2B5pqoALb82l5qzdfaYXyhBAExMDNr106YW%2BTUMpfsrzFLq2Uob1p0dqSRoW7jPlOv%2Fa3lRAg%3D%3D

check the connections of my circuit

singhrohan

@copilot this is a 8051 microcontroller, I want to modify this circuit so that it connects to a pc via USB so that i can flash it's EEPROM

copilot

To modify the circuit so that it can connect to a PC via USB to flash the EEPROM of the AT89S52 microcontroller, you'll need a USB-to-serial converter. One common solution is to use the FT232RL IC (USB to UART bridge). Here are the steps to modify your circuit:

Components Needed

FT232RL USB to UART Converter Module
USB Connector
Capacitors (as required by the FT232RL datasheet)
Optional: Pull-up resistors and diodes for USB data lines

Steps to Connect FT232RL to AT89S52

Power Connections:
- FT232RL:VCC to Vcc (5V power supply)
- FT232RL:GND to GND
USB Connections:
- Connect the USB Data+ (D+) and Data- (D-) pins from your USB connector to the FT232RL module.
- Connect the USB VCC and GND to the respective power lines.
UART Connections:
- Connect FT232RL:TXD to U1:P3.0_ $RXD$
- Connect FT232RL:RXD to U1:P3.1_ $TXD$
Reset and Programming Pins:
- Typically handled by programming software (e.g., using FTProg for custom settings on FT232).

Updated Schematic Connections

Connect Vcc:1 to FT232RL:VCC
Connect GND:1 to FT232RL:GND and FT232RL:USB_GND
Connect FT232RL:TXD to U1:P3.0_ $RXD$
Connect FT232RL:RXD to U1:P3.1_ $TXD$
Connect FT232RL:DTR to U1:RST (handling through software)
USB connector: connect D+ and D- to corresponding pins on FT232RL.

Here's a concise list of connections:

Connect FT232RL:VCC to Vcc:1.
Connect FT232RL:GND to GND:1.
Connect FT232RL:TXD to U1:P3.0_ $RXD$ .
Connect FT232RL:RXD to U1:P3.1_ $TXD$ .
Connect FT232RL:DTR to U1:RST.
Connect USB Connector:D+ to FT232RL:D+.
Connect USB Connector:D- to FT232RL:D-.
Connect USB Connector:VCC to Vcc:1.
Connect USB Connector:GND to GND:1.

Note:

Ensure proper bypass capacitors (0.1µF) near power pins.
Optionally, add zener diodes for ESD protection on the USB lines.

Would you like to include any additional features, such as status LEDs or an on-board EEPROM writer circuit?

singhrohan

can you make those connections for me?

copilot

Certainly! Let's make the necessary connections step-by-step.

Updated Connections:

FT232RL to Power Supply:
- Connect Vcc:1 to FT232RL:VCC.
- Connect GND:1 to FT232RL:GND.
FT232RL to UART on AT89S52:
- Connect FT232RL:TXD to U1:P3.0_ $RXD$ .
- Connect FT232RL:RXD to U1:P3.1_ $TXD$ .
- Connect FT232RL:DTR to U1:RST.
USB Connector to FT232RL:
- Connect USB Connector:D+ to FT232RL:D+.
- Connect USB Connector:D- to FT232RL:D-.
- Connect USB Connector:VCC to Vcc:1.
- Connect USB Connector:GND to GND:1.

Here's the updated complete connection list for readability:

Project Nets:

New Connections:
- Connect Vcc:1 to FT232RL:VCC.
- Connect GND:1 to FT232RL:GND.
- Connect FT232RL:TXD to U1:P3.0_ $RXD$ .
- Connect FT232RL:RXD to U1:P3.1_ $TXD$ .
- Connect FT232RL:DTR to U1:RST.
- Connect USB Connector:D+ to FT232RL:D+.
- Connect USB Connector:D- to FT232RL:D-.
- Connect USB Connector:VCC to Vcc:1.
- Connect USB Connector:GND to GND:1.

Remaining Component Connections (existing from your description):

Cand Crystal Connections:
- Connect C2:P1 to Net 2.
- Connect C2:P2 to GND.
- Connect C1:P1 to Net 1.
- Connect C1:P2 to GND.
- Connect X2:P1 to Net 1.
- Connect X2:P2 to Net 2.
Reset Circuit Components:
- Connect C3:P1 to Net 4.
- Connect C3:P2 to Net 3.
- Connect R1:P1 to Net 4.
- Connect SW1:P1 to Net 4.
- Connect R1:P2 to GND.
- Connect SW1:P2 to Net 3.

This should correctly integrate the USB-to-UART programming feature into your existing design. Could you double-check these connections on your schematic in the Flux editor? Feel free to ask if you need more details or modifications!

singhrohan

this is a 8051 microcontroller, I want to modify this circuit so that it connects to a pc via USB so that i can flash it's EEPROM

singhrohan

@copilot what I've built is supposed to be a 8051 circuit. Any improvements that you can suggest?

copilot

Great start with building an 8051-based circuit! Here are some potential improvements and considerations:

Decoupling Capacitor:
- Add a decoupling capacitor (e.g., 100nF) between VCC and GND close to the microcontroller to filter out power supply noise.
Proper Power Connections:
- Ensure that Vcc and GND are properly connected.
Crystals and Capacitors:
- The typical setup for crystals involves two capacitors in the range of 22pF-33pF connected to ground. Make sure the values of capacitors $C_1$ and $C_2$ are appropriate for your crystal.
Reset Circuit:
- $U_1$ : $RST$ should have a pull-up resistor (typically 10kΩ) connected, possibly with a capacitor (typically 10µF) in parallel to ground for proper reset behavior. $SW_1$ seems to be acting as a reset switch.
Oscillator Connections:
- Your connections for the crystal and its associated capacitors look good.
Unconnected Pins:
- Verify whether you need pull-up resistors on any unused I/O pins to prevent floating inputs which can cause unstable operation.
Programming Header:
- If you plan on reprogramming your microcontroller frequently, consider adding a header for an ISP (In-System Programming) interface.

Suggested Connections

Decoupling Capacitor:
- Add a 100nF capacitor close to the VCC and GND pins of $U_1$ .
Reset Circuit:
- Connect $R_{1:2}$ to $U_1$ :VCC (through a 10kΩ resistor).
- Optionally, add a capacitor (e.g., 10µF) between $U_1$ : $RST$ and GND.

Example Connections

Decoupling Capacitor:
- Connect a 100nF capacitor between $U_1$ :VCC and GND.
Pull-up Resistor on Reset:
- Connect $R_{1:2}$ to $U_1$ :VCC.

Would you like to make any specific changes or ask about other parts/functions of your circuit?

singhrohan

what I've built is supposed to be a 8051 circuit. Any improvements that you can suggest?

singhrohan

@copilot check the connections of my circuit

copilot

Certainly! Let's review the connections described in your project.

Component Connection Review

Reset Circuit:
- Connects to the reset pin (RST) of the microcontroller.
- Members:
  - U1: $RST$
  - R1: $P1$
  - C3: $P1$
  - SW1: $P1$
Ground:
- Members connected to ground:
  - R1: $P2$
  - C2: $P2$
  - C1: $P2$
  - U1: $GND$
External Access Enable (EA/VPP):
- Connects to external access pin of the microcontroller with related components.
- Members:
  - U1: $\tilde{EA}/VPP$
  - C3: $P2$
  - SW1: $P2$
XTAL2:
- Crystal Oscillator connection.
- Members:
  - X1: $P1$
  - C2: $P1$
  - U1: $XTAL2$
XTAL1:
- Crystal Oscillator connection.
- Members:
  - U1: $XTAL1$
  - X1: $P2$
  - C1: $P1$

Additional Connections

Power:
- Vcc to U1: $VCC$

Overall Component Connections

Reset Circuit Connections:
- Connect $U1: RST$ to $R1: P1$ , $C3: P1$ , and $SW1: P1$ .
- Connect $U1: \tilde{EA}/VPP$ to $C3: P2$ and $SW1: P2$ .
Crystal Oscillator Connections:
- Connect $U1: XTAL2$ to $X1: P1$ and $C2: P1$ .
- Connect $U1: XTAL1$ to $X1: P2$ and $C1: P1$ .
Power Connections:
- GND net connects to $U1: GND$ , $R1: P2$ , $C2: P2$ , and $C1: P2$ .
- Power connection to connect VCC to $U1: VCC$ .

Ensure the connections are securely made and verify that all nets are correctly assigned to each designated pin. If you have any specific questions or modifications, let me know!

can you connect all the pins of J3 to "pin 6", pin 7", pin 8", pin 9" of J1

singhrohan

@copilot can you connect all the pins of J3 to "pin 6", pin 7", pin 8", pin 9" of J1

copilot

Sure, we can connect the pins as follows:

Connect J3:Pin_1 to J1:Pin_6
Connect J3:Pin_2 to J1:Pin_7
Connect J3:Pin_3 to J1:Pin_8
Connect J3:Pin_4 to J1:Pin_9

This will effectively map all the pins from J3 to the specified pins on J1.

singhrohan

@copilot can you connect all the pins of J5 to "pin 6", pin 7", pin 8", pin 9" of J1

copilot

Sure, here are the connections:

Connect J5:Pin_1 to J1:Pin_6
Connect J5:Pin_2 to J1:Pin_7
Connect J5:Pin_3 to J1:Pin_8
Connect J5:Pin_4 to J1:Pin_9

This will connect all the pins of J5 to the specified pins of J1.

singhrohan

@copilot can you connect pin 1,2,3 and 4 of J5 to "pin 6", pin 7", pin 8", pin 9" of J1

copilot

Sure, let's map the pins as follows:

Connect J5:Pin_1 to J1:Pin_6
Connect J5:Pin_2 to J1:Pin_7
Connect J5:Pin_3 to J1:Pin_8
Connect J5:Pin_4 to J1:Pin_9

This achieves the desired connections between J5 and J1.

can you connect all the pins of J1 and J2 with terminals named "Pin "

singhrohan

@copilot can you connect all the pins of J1 and J2 with terminals named "Pin "

copilot

To connect all the pins of J1 and J2 with terminals named "Pin", you can follow the connections as shown below. Note that J1 has 20 pins and J2 has 20 pins:

Connections:

Connect J1:Pin_1 to J2:Pin_1
Connect J1:Pin_2 to J2:Pin_2
Connect J1:Pin_3 to J2:Pin_3
Connect J1:Pin_4 to J2:Pin_4
Connect J1:Pin_5 to J2:Pin_5
Connect J1:Pin_6 to J2:Pin_6
Connect J1:Pin_7 to J2:Pin_7
Connect J1:Pin_8 to J2:Pin_8
Connect J1:Pin_9 to J2:Pin_9
Connect J1:Pin_10 to J2:Pin_10
Connect J1:Pin_11 to J2:Pin_11
Connect J1:Pin_12 to J2:Pin_12
Connect J1:Pin_13 to J2:Pin_13
Connect J1:Pin_14 to J2:Pin_14
Connect J1:Pin_15 to J2:Pin_15
Connect J1:Pin_16 to J2:Pin_16
Connect J1:Pin_17 to J2:Pin_17
Connect J1:Pin_18 to J2:Pin_18
Connect J1:Pin_19 to J2:Pin_19
Connect J1:Pin_20 to J2:Pin_20

These connections will create a parallel connection for each pin between J1 and J2. Let me know if you need further assistance!

SCK

Pin 8 (P1.7)

Pin 14 (P3.5)

Pin 12 (P3.2)

Pin 6 (P1.5)

MOSI

Pin 12 (P3.3)

Pin 1 (P1.0)

Pin 5 (P1.4)

Pin 10 (P3.0)

Pin 4 (P1.3)

VCC

GND

Pin 15 (P3.6)

Pin 13 (P3.4)

RESET

Pin 3 (P1.2)

MISO

Pin 2 (P1.1)

Pin 11 (P3.1)

Pin 9 (RST)

Pin 7 (P1.6)

Not Recommended for New Designs

VCC

Capacitance

33p F

Capacitance

33p F

Resistance

8200 Ω

VCC

Frequency

11.0592M Hz

Capacitance

20p F

Capacitance

10u F

SW2

Capacitance

20p F

Resistance

500 Ω

VCC

Reviews

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Missing Footprints

Reports parts that have no footprint.

Design Rule Checks

Overlapping Copper • 11

Des	Net	Des	Net
C1:P1	GND	Trace df52	Net 2
Trace 3703	GND	Trace 7678	Net 1
Trace 3703	GND	X2:P1	Net 1
Trace 7045	GND	Trace df52	Net 2
C4:P2	Net 1	Trace dd87	GND
C1:P2	Net 2	Trace 7045	GND
Trace 50fa	Net 3	J5:Pin_1	Net 16
Trace ce04	Net 3	J5:Pin_1	Net 16
J1:Pin_9	Net 16	Trace 722f	Net 3
J5:Pin_1	Net 16	Trace f3eb	Net 3
J3:Pin_1	None	Trace a639	Net 8

Invalid Layer

Reports nodes that are assigned to a layer that doesn't exist in the layout stackup.

Component Overrides

Reports components that have been modified using the "!important" flag.

Airwires • 9

	Designators	Net
	C4:P2, X2:P1	Net 1
	C1:P2, Trace df52:Trace df52	Net 2
	Trace f3eb:Trace f3eb, Trace 50fa:Trace 50fa	Net 3
	J1:Pin_9, J5:Pin_1	Net 16
	U1:XTAL1/PB6, X1:P1	Net 21
	X1:P1, C2:P1	Net 21
	U1:XTAL2/PB7, X1:P2	Net 22
	X1:P2, C5:P1	Net 22
	U1:～RESET～/PC6, R1:P1	Net 23

Deprecated Rules

Reports nodes that are using rules that are not supported anymore.

Layers with Multiple Fills

Reports layers that have multiple copper fills of different nets. Make sure the Connected Layers rule value of nets with fills is valid.

Floating Copper • 1

	Name
	Trace 722f, Trace ce04

Protected Intrusions

Reports intrusions from objects of other nets into polygons or fills that have the Protected layout rule applied.

Manufacturing

Manufacturer Part Number • 9

	Designator	MPN
	C2	None
	C5	None
	J1	None
	J2	None
	J3	None
	J4	None
	J5	None
	R1	None
	R2	None

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Checks that IC pins that require pull up or pull down resistors have them.

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Beta

Checks that capacitors have appropriate voltage ratings to prevent overheating and ensure reliable circuit operation.

Ground
A common return path for electric current. Commonly known as ground.
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Wirelessly connects power nets on schematic. Identical to the net portal, but with a power symbol. Used to organize schematics and separate functional blocks. To wirelessly connect power net portals, give them the same designator. #portal #power
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