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are there any issues in this project?
rex-flux

rex-flux

@copilot are there any issues in this project?
1y

copilot

Let's review the components and pin connections planned for this project to ensure that the key aspects of your LTC3109 application are correctly set up. Here are a few considerations and potential issues:
Major Points to Verify:
  1. Input Connections:
    • VIN1 and VIN2: These should be connected to your energy harvesting sources (e.g., thermoelectric generators). Make sure they are correctly configured.
  2. Decoupling Capacitors:
    • Proper placement of capacitors on power input pins to stabilize voltage and mitigate noise.
  3. Output Configuration:
    • Ensure that VOUT is correctly configured with respect to the desired output voltage. This often involves setting VPRG1 and VPRG2 pins.
  4. Ground Connections:
    • All ground pins (e.g., GND) should be correctly connected to a common ground.
  5. Storage Capacitor:
    • VSTORE Pin: Correctly connect an appropriate capacitor to store excess harvested energy.
  6. LDO Regulator:
    • LDO_OUT: Ensure this pin is correctly routed if you intend to use the Low Dropout Regulator.
  7. Other Pins:
    • PGD, VREF, IRQ, SW, and others: These should be connected according to the specific functionality and application needs tailored to your project's requirements.
Initial Design Schematic Review:
Here is a basic connection setup for the LTC3109:
  1. Power and Ground Connections:
    • Connect VIN1:1 to your energy harvesting source.
    • Connect VIN2:3 to your energy harvesting source.
    • Connect GND:2 to your ground plane.
  2. Output Voltage Configuration:
    • Set VPRG1:10 and VPRG2:11 to achieve the desired output voltage by either tying to ground or leaving open (check specific configurations in the data sheet).
  3. Capacitor Connections:
    • Connect C1+:4 to a capacitor (C1).
    • Connect C1-:5 to the other side of C1.
  4. Energy Storage:
    • Connect VSTORE:8 to an appropriate storage capacitor (e.g., 1 µF or greater).
  5. LDO Regulator:
    • Connect LDO_OUT:6 to the LDO regulator if needed.
  6. Switching Regulator and Load Connection:
    • Connect SW:12 to the necessary components for the switching regulator.
    • Connect VOUT:9 to your load.
  7. Other Functional Pins:
    • Check if any specific functionality needed, connect PGD:14, VREF:13, IRQ:15 accordingly.
Example Detailed Connections:
Here are specific connections for a basic setup:
  • VIN1: Connect VIN1:1 to your energy harvesting source positive terminal.
  • VIN2: Connect VIN2:3 to your energy harvesting source negative terminal.
  • Ground: Connect GND:2 to your ground plane.
  • Capacitor: Connect C1+:4 to one side of a capacitor, and C1-:5 to the other side of the same capacitor.
  • Output Voltage Programming: Connect VPRG1:10 to GND (sets 3.3V output), leave VPRG2:11 open (adjust based on your desired output voltage).
  • VSTORE: Connect VSTORE:8 to a storage capacitor (e.g., 10 µF).
  • LDO Output: Connect LDO_OUT:6 to your load if using LDO.
Next Steps:
  1. Complete the Pin Connections: Start making the electrical connections in your Flux.ai project according to the example detailed connections above.
  2. Component Values: Ensure the values of capacitors and other components are appropriate as per LTC3109’s datasheet and application notes.
  3. Simulation and Validation: Once the connections are complete, simulate and check the circuit to validate functionality.
If you correct or update any assumptions, please let me know, and I can assist you further!
1y
create a high level mermaid block diagram of this project. Include key component...
rex-flux

rex-flux

@copilot create a high level mermaid block diagram of this project. Include key component's manufacturer part number in each block whenever possible.
1y

copilot

Sure! Below is a high-level Mermaid block diagram of the project. Each block represents key components, and I'll include the manufacturer part number for clarity.

Image

Other Pins
Outputs
Controls
Inputs
Energy Harvesting Inputs
Outputs
Outputs
Outputs
Control Inputs
Control Inputs
Control Outputs
Other Connections
Other Connections
Other Connections
Other Connections
Other Connections
Other Connections
Other Connections
Other Connections
Other Connections
Other Connections
Other Connections
GND $$(Pin 2$$)
SW $$(Pin 12$$)
VREF $$(Pin 13$$)
IRQ $$(Pin 15$$)
PGD $$(Pin 14$$)
VAUX $$(Pin 7$$)
C1+ $$(Pin 4$$)
C1- $$(Pin 5$$)
DCA $$(Pin 19$$)
DCB $$(Pin 20$$)
DCTR $$(Pin 18$$)
VOUT $$(Pin 9$$)
LDO_OUT $$(Pin 6$$)
VSTORE $$(Pin 8$$)
VPRG1 $$(Pin 10$$)
VPRG2 $$(Pin 11$$)
ENOUT2 $$(Pin 16$$)
VIN1 $$(Pin 1$$)
VIN2 $$(Pin 3$$)
DCIN $$(Pin 17$$)
LTC3109EUF#PBF DC/DC Converter
This diagram represents the main blocks and their connections in the project. Let me know if you need any further details!
1y
4
explain this project.
rex-flux

rex-flux

@copilot explain this project.
1y

copilot

This project involves the LTC3109EUF#PBFLTC3109EUF\#PBF from Linear Technology Corporation. It’s a highly integrated DC/DC converter specifically designed for energy harvesting applications. Below is a detailed explanation:
LTC3109 Features
  • Ultra-low Input Voltage: Can operate from as low as 30mV, which is suitable for energy harvesting from thermoelectric generators (TEGs)(TEGs) and thermopiles.
  • Auto-Polarity Architecture: Functions regardless of the polarity of the input voltage.
  • Output Voltage Selection: Selectable output voltages of 2.35V, 3.3V, 4.1V, or 5V.
  • Low-Dropout Regulator: Includes a 2.2V LDO regulator.
  • Logic Controlled Output: To facilitate easy integration with microcontrollers or other logic-level devices.
  • Energy Storage: Ensures continuous operation through a brief power interruption.
  • Compact Package: Encapsulated in a small, 20-lead (4mm×4mm)(4mm \times 4mm) QFN or SSOP package, suitable for space-constrained applications.
  • Power Good Indicator: To signal the status of the output voltage.
  • Use of Compact Step-Up Transformers: Enhanced efficiency for low-power energy harvesting systems.
Key Specifications
  • Voltage Input Range: 30mV to 500mV
  • Operating Temperature Range: -40°C to 85°C
  • Output Current Max: 26mA
  • Output Voltage Range: 2.3V to 5.1V
  • Quiescent Current: 0.2μ\muA
Pins and Functions
Here are the key pins and their functions:
  • VIN1 and VIN2: Input voltages that can be fed from a thermoelectric generator.
  • GND: Ground.
  • VOUT: Output voltage pin.
  • LDO_OUT: Output pin for the low-dropout regulator.
  • VSTORE: Storage capacitor connection to maintain operation during power interruptions.
  • VPRG1 and VPRG2: Voltage selection pins to set the output voltage.
  • ENOUT2: Control logic output.
  • IRQ: Interrupt request output.
  • PGD: Power Good indicator.
  • C1+ and C1-: Pins for the external energy storage capacitor.
  • DCTR and DCA, DCB: Connections for compact step-up transformers.
  • SW: Switching node for the step-up transformer.
  • VREF: Reference voltage pin.
No electrical connections have been made in this project yet, but here’s a basic outline of how you might connect the key components:
Example Connections
  1. Input Connections:
    • Connect VIN1 and VIN2 to the thermoelectric generator.
    • Connect GND to the ground plane of the system.
  2. Energy Storage Capacitor:
    • Connect C1+ and C1- to a suitable capacitor for energy storage.
  3. Output Voltage:
    • Connect VOUT to the desired load.
    • Connect LDO_OUT to the load that requires regulated 2.2V.
  4. Voltage Selection:
    • Connect VPRG1 and VPRG2 to select the desired output voltage.
  5. Interrupt and Power Good:
    • Connect IRQ to an interrupt pin of the microcontroller.
    • Connect PGD to a digital input pin to monitor the power status.
Further Steps
  • More specific components, resistors, capacitors, and transformers need to be chosen according to the application requirements.
  • Implementation of feedback mechanisms, if needed, to stabilize the output.
Let me know if you need specific connections or any other details!
1y
6
explain this project.
rex-flux

rex-flux

@copilot explain this project.
1y

copilot

Certainly! Let’s break down the project:
Overview:
The project involves using the LTC3109EUF#PBF component from Linear Technology Corporation. This component is a DC/DC converter designed for energy harvesting applications. It can operate from ultra-low input voltages and efficiently convert this energy to power devices such as remote sensors and wireless transmitters.
Key Features of LTC3109:
  • Ultra-low Input Voltage Operation: As low as 30mV.
  • Auto-polarity Architecture: Operates regardless of input polarity, unique to LTC3109.
  • Selectable Output Voltages: 2.35V, 3.3V, 4.1V, or 5V.
  • 2.2V LDO Regulator: Low-dropout regulator.
  • Logic-controlled Output: For effective control.
  • Energy Storage System: Maintains operation during power interruptions.
  • Power Good Indicator: Provides status of power availability.
  • Compact Package: QFN or SSOP (4mm × 4mm) suitable for space-constrained applications.
Application Areas:
  • HVAC Systems
  • Building Automation
  • Industrial Wireless Sensing
  • Thermoelectric Generators (TEGs)
  • Thermopiles
Design Aspects:
  • Manufacturer Name: Linear Technology Corporation
  • Package or Case: QFN65P500X500X80-21WN
  • Mounting Type: Surface Mount Technology (SMT)
  • Operating Temperature Range: -40°C to 85°C
  • Output Accuracy: 2 - 3%
  • Maximum Output Current: 26mA
  • Output Voltage Range: 2.30V to 5.10V
  • Quiescent Current: 0.2µA
  • Maximum Input Voltage: 500mV
  • Minimum Input Voltage: 30mV
Pins Breakdown:
  • Power and Ground:
    • VIN1 (Pin 1): Power input
    • VIN2 (Pin 3): Power input
    • GND (Pin 2): Ground
    • VREF (Pin 13): Reference voltage
  • Output Pins:
    • VOUT (Pin 9): Main output voltage
    • LDO_OUT (Pin 6): LDO regulator output
    • VAUX (Pin 7): Auxiliary output
  • Control Pins:
    • ENOUT2 (Pin 16): Enable output
    • VPRG1 (Pin 10): Voltage programming
    • VPRG2 (Pin 11): Voltage programming
    • IRQ (Pin 15): Interrupt request
    • PGD (Pin 14): Power Good Indicator
  • Energy Storage and Switching:
    • VSTORE (Pin 8): Energy storage
    • SW (Pin 12): Switch
    • C1+/C1- (Pins 4/5): Capacitor connections
Initial Setup:
No connections have been made yet in the project, so you'll need to connect appropriate power sources, capacitors, and set up the correct voltage programming to harness energy effectively and use the LTC3109.
Connections Example:
Here is a simple starting point for the connections:
  • Power Inputs:
    • Connect VIN1 P1P_1 and VIN2 P3P_3 to your energy harvesting source.
  • Ground:
    • Connect GND P2P_2 to your ground plane.
  • Main Output:
    • Connect VOUT P9P_9 to the load you intend to power.
Would you like to proceed with specific connections or have any specific questions about the component or its usage?
1y
2
how do I use Flux?
rex-flux

rex-flux

@copilot how do I use Flux?
1y

copilot

Welcome to Flux! To get started with using Flux, here are some key steps and resources for you:
  1. Creating an Account:
    • Visit Flux Signup to create an account. Simply enter your username, email, and password. You can also create an account by linking your Google account.
  2. Getting Help:
    • If you need help with Flux, the best place for support is the @support. Here, you can ask questions directly to the Flux team and connect with other engineers, designers, and hardware enthusiasts.
  3. Learning Resources:
    • Explore the library of
      for crash courses and recorded events. Independent content creators also have great videos on how to use Flux.
  4. Using the Simulation:
  5. Positioning and Routing:
    • For a detailed guide on positioning and routing components in Flux, you can refer to the /docs/routing.
  6. Interactive Help:
    • When Copilot suggests specific connections on your schematic, you can have it perform those connections for you by clicking the "Take Action" button.
Starting with these steps should give you a solid foundation in using Flux for your electronics projects. If you need further assistance, feel free to ask!
1y
5
C1
Capacitance
Capacitance
P3
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Inspect

LTC3109EUF#PBF

LTC3109EUF#PBF
Description

Created
Last updated by rex-flux
1 Contributor(s)
rex-flux

Controls

Properties

Part Type
Switching Regulator
Manufacturer Name
https://www.analog.com/
Manufacturer Part Number
LTC3109EUF#PBF
Designator Prefix
U
Compliance
+30 mV
Package or Case Code
QFN65P500X500X80-21WN
Materials
Mounting Type
Surface Mount Technology (SMT)
Operating Temperature Range
-40 - 85 C
Output Accuracy
2 - 3 %
Output Current Max
26 mA, A
Output Type
2.35 V
Quiescent Current
0.2 µA
Voltage Input Max
500 mV
Voltage Input Min
30 mV
Voltage Output Max
5.10 V
Voltage Output Min
2.30 V

Availability & Pricing

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172$13.93
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