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explain the purpose of the circuit
chepin69

chepin69

@copilot explain the purpose of the circuit
2y

copilot

This audio peak detector circuit is designed to process audio signals captured by an electret microphone (MK1). The purpose of the circuit is to detect the highest amplitude (peak) in the audio signal and output a corresponding DC voltage level.
The main component of the circuit, U1 (LMV358IDT), is configured as an operational amplifier (op-amp) in a non-inverting configuration. The audio signal from the microphone goes through a coupling capacitor (C1) to remove the DC bias and then feeds the input of the op-amp. Resistors R2 and R3 form a voltage divider to set the reference voltage for the non-inverting input, while resistors R1 and R4 are used for feedback and gain control. The op-amp is configured to amplify the input audio signal in a linear fashion.
The amplified output from U1 is then processed through a peak detector stage, consisting of a diode (D1), a capacitor (C2), and a resistor (R5). When the audio signal amplitude exceeds the voltage on the capacitor, the diode conducts, charging C2 to the peak level of the signal. When the signal drops below this peak level, the diode becomes reverse-biased and stops conducting, trapping the peak value in C2. The capacitor slowly discharges through resistor R5, allowing the circuit to track the highest peak over time.
Finally, this output voltage, which is proportional to the peak audio amplitude, can be accessed via a connector J1 for further processing or real-time monitoring.
2y
mugen

mugen

what is the purpose of C3?
2y

copilot

C3 is a bypass capacitor placed across the power supply lines of the op-amp U1. It is connected between the VDD pin (supply rail) and the ground (GND). The purpose of C3 is to filter out high-frequency noise and stabilize the voltage supply to the op-amp, ensuring optimal performance and preventing unwanted oscillations or fluctuations in the amplifier output.
By connecting a capacitor like C3 across the power rails, any high-frequency noise or transient voltage spikes present in the supply or generated within the circuit can be effectively shorted to ground before affecting the operation of the op-amp, thus maintaining a clean and stable power supply for the amplifier.
2y
asauter

asauter

are you sure C3 is not the hold in the peak-hold circuit?
1y

copilot

I apologize for the confusion in my previous response. Given the context of the audio peak detector circuit you've described, where C3 is connected along with other components such as D1 (a diode), it indeed plays the role of a hold capacitor in the peak-hold circuit section, rather than serving strictly as a bypass capacitor.
In a peak detector or peak-hold circuit, the hold capacitor (C3 in this context) is charged to the peak voltage of the signal. When the diode (D1) conducts during the positive peaks of the signal, C3 charges up to this peak voltage. Once the input signal voltage drops below this peak, the diode stops conducting, and C3 holds (or stores) the peak voltage level. This stored voltage can then slowly discharge through the load represented by R5, thus providing a measurable output that represents the peak value of the input signal over a period.
This setup allows C3 to act as a storage element that captures and holds the peak amplitude of the signal, making it possible to measure or utilize the peak value for further signal processing or monitoring tasks. This is a crucial function for achieving the desired peak-detection capability of the circuit.
1y
asauter

asauter

what is the transfer function of the microphone
1y

copilot

The transfer function of a microphone, like the electret microphone designated as MK1 (POM-3042P-R) in your project, describes how the microphone converts sound pressure levels (SPL) into an electrical output voltage. However, the detailed transfer function can be complex, dependent on the microphone's design, and is not typically expressed in a simple mathematical form for electret microphones. Instead, electret microphones are often characterized by a few key parameters:
  1. Sensitivity: This is expressed in dBV/Pa or mV/Pa, indicating the voltage output of the microphone for a given sound pressure level. A typical value might be "-44 dBV/Pa" which would mean that the microphone outputs a signal of 0.0063 V (or 6.3 mV) when exposed to a 1 Pascal sound pressure level.
  2. Frequency Response: This describes how the microphone's sensitivity varies over a range of frequencies, typically from 20 Hz up to 20 kHz for microphones meant to capture audible sounds. The frequency response can be presented graphically, showing any variations in sensitivity across the audible spectrum.
  3. Directionality: Electret microphones can have different polar patterns (omnidirectional, cardioid, supercardioid, etc.), influencing how sound is captured from various directions. This is more of a spatial characteristic rather than part of the transfer function but is essential for understanding the microphone's overall performance.
Assuming a simplified model for the electret microphone and ignoring directional and frequency-dependent effects, a basic form of the transfer function could be described as: Vout=SSPLV_{out} =S \cdot SPL Where:
  • $V_{out}$ is the output voltage of the microphone
  • $S$ is the sensitivity of the microphone (in V/Pa)
  • $SPL$ is the sound pressure level (in Pascals)
Remember, this simplification doesn't account for the microphone's frequency response or non-linearities that may occur at high SPLs. For precise analysis or simulation, referring to the specific datasheet of the POM-3042P-R, including its sensitivity, frequency response, and other relevant characteristics, would be necessary.
1y
Someone is typing...
sensor de temperatura
daith

daith

@copilot sensor de temperatura
1y

copilot

Parece que estás interesado en un sensor de temperatura. Hay muchas opciones disponibles dependiendo de tus necesidades específicas, como rango de temperatura, precisión y tipo de interfaz (analógica, digital, etc.). Algunos sensores de temperatura comunes son:
  • LM35: Sensor de temperatura analógico que proporciona una señal de salida de voltaje que es linealmente proporcional a la temperatura en grados Celsius.
  • DS18B20: Sensor de temperatura digital que utiliza una interfaz de bus 1-Wire, lo que permite la comunicación digital en un solo hilo.
  • DHT22 (o AM2302): Sensor de temperatura y humedad que utiliza una interfaz digital.
Si me das más detalles sobre las especificaciones o el contexto del proyecto donde deseas usar el sensor de temperatura, puedo recomendar un componente más específico o ayudarte a integrarlo en tu diseño. ¿Tienes alguno de estos sensores en mente o hay algún requerimiento particular que te gustaría considerar?
1y
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13
que funciòn cumple este capacitor en el circuito
clevis

clevis

@copilot que funciòn cumple este capacitor en el circuito
2y

copilot

El capacitor más cercano a la posición de este hilo de chat es C1. En el contexto de este circuito de detección de picos de audio, C1 está conectado entre el micrófono (MK1) y la entrada del operacional (U1).
C1 cumple la función de un capacitor de acoplamiento. Su propósito principal es bloquear cualquier componente de corriente continua (DC) presente en la señal de audio proveniente del micrófono, permitiendo que sólo las variaciones de la señal (componente alterna, AC) pasen al amplificador operacional.
Esto es importante para evitar que cualquier voltaje DC en la salida del micrófono pueda afectar el funcionamiento del amplificador operacional que está diseñado para amplificar las variaciones de la señal de audio.
2y
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4
explain this project.
siddharth995

siddharth995

@copilot explain this project.
1y

copilot

Certainly! Let's break down the project, which is an audio peak detector for electret microphones. The goal of this device is to detect the peak amplitude of an audio signal from an electret microphone.
Project Overview
  1. Electret Microphone: The microphone (MK1, POM-3042P-R) captures sound and converts it to an electrical signal.
  2. Operational Amplifiers: Two op-amps in the LMV358IDT package are used to amplify and rectify the audio signal.
  3. Diode: The 1N4148WS-7 diode rectifies the amplified signal, allowing only the positive peaks.
  4. Capacitor and Resistor Network: Smooths the rectified signal to indicate the peak level.
Component Breakdown and Connections Operational Amplifier (LMV358IDT)
  • U1: LMV358IDT
    • Op-Amp Input and Output Pins:
      • 8 (VCC): Connected to the power supply.
      • 4 (VDD): Connected to Ground (GND).
      • 1 (OUTPUT 1): Outputs the amplified signal.
      • 7 (OUTPUT 2): Another output for further stages if needed.
      • 3 (IN +1), 2 (IN -1): First op-amp inputs.
      • 5 (IN +2), 6 (IN -2): Second op-amp inputs.
Electret Microphone (POM-3042P-R)
  • MK1: POM-3042P-R
    • N: Connected to Ground.
    • P: Connected to a bias resistor R1 and capacitor C1, which then feed into the op-amp.
Diode and Rectification
  • D1: 1N4148WS-7
    • K (Cathode): Connects to U1$$:$(OUTPUT 2).
    • A (Anode): Connects to U1$$:$(IN -2).
Capacitors and Resistors
  • C1 10µF: Smooths the audio signal from the microphone.
  • C2 100nF and C3 10µF: Further smoothing and filtering of the rectified signal.
  • R1 10kΩ, R2 10kΩ, R3 100kΩ, R4 1kΩ, R5 10kΩ
Connectors
  • J1, CONN1 and various VIN and OUT nets for power and signal routing.
Circuit Functionality
  1. Microphone Signal Conditioning:
    • The electret microphone MK1 receives sound and converts it into an analog signal.
    • This signal is filtered through C1 and biased by R1.
  2. Amplification:
    • The filtered signal is fed into the non-inverting input of the first op-amp U1$$:$(IN +1).
    • The op-amp amplifies the signal, and the output is taken from U1$$:$(OUTPUT 1).
  3. Signal Rectification:
    • The amplified signal is rectified using D1, allowing only the positive part of the signal to pass.
  4. Peak Detection and Smoothing:
    • The rectified signal is smoothed by C3 and other associated components to provide a steady DC output corresponding to the peak audio signal level.
This circuit can be used in various applications where detecting the peak level of an audio signal is essential, such as VU meters, audio level indicators, etc. Let me know if you need further details or assistance with the project!
1y
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7
are there any issues in this project?
inca4k

inca4k

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

copilot

Let's review the project to identify if there are any issues:
Component Overview
  1. U1 - LMV358IDT:
    • Dual operational amplifier
  2. VIN:
    • Power supply net
  3. OUT:
    • Output net
  4. C1 - Capacitor:
    • 10 µF
  5. D1 - 1N4148WS-7:
    • Diode
  6. R2 - Resistor:
    • 10 kΩ resistor
  7. MK1 - POM-3042P-R:
    • Electret microphone
  8. R4 - Resistor:
    • 1 kΩ resistor
  9. R5 - Resistor:
    • 10 kΩ resistor
  10. C3 - Capacitor:
    • 10 µF
  11. C2 - Capacitor:
    • 100 nF
  12. J1 - Connector:
    • 3-pin connector
  13. R1 - Resistor:
    • 10 kΩ resistor
  14. R3 - Resistor:
    • 100 kΩ resistor
Net Connections:
I will now check for common issues such as:
  • Missing or incorrect connections.
  • Floating pins.
  • Potential shorts.
  • Supply issues.
Issue Analysis:
  1. Power Connections:
    • U1 has VCC connected to VIN, which is correct.
    • GND for U1 is probably connected to Net GND, which seems correct from the schematic elements, though the connection seems assigned to VDD instead of GND.
  2. Input Sections and Biasing:
    • Ensure that the microphone MK1MK1 is biased correctly.
    • Biasing Resistors:
      • R2R2 should tie the input to a reference voltage or ground.
      • Ensure there is a proper bias network for the microphone.
  3. Capacitors:
    • C1 and C3 seem to be used for AC coupling and filter, 10 µF appears adequate.
    • C2 is used for decoupling, 100 nF is a typical value.
  4. Signal Path:
    • R4 and R3 seem to form feedback or input networks. Ensure they are properly connected.
Identified Issues:
  1. U1 - GND Pin
    • Verify if the VDD pin of U1 is correctly connected as ground. Typically, an op-amp has a VCC and GND connection.
  2. Duplicate and Unlabeled NETs:
    • Duplicate or redundant designators for VIN and OUT should be avoided for clarity.
    • Break out nets with meaningful names.
  3. Floating Nodes/Unused Pins:
    • Clearly ensure all amplified outputs or nodes are connected somewhere meaningful, no floating nodes unless intended as an open node.
  4. Availability:
    • 1N4148WS-7 is obsolete according to the stock information. Consider replacing it with an active part like 1N41481N4148.
Recommendations:
  • Verify GND connection on U1; if 8th pin is VCC, 4th pin should typically be GND.
  • Replace Obsolete Component: Substitute 1N4148WS-7 with 1N41481N4148.
  • Clean Duplicate Net Designations and clarify as necessary.
Would you like a specific part of the project reviewed further or more detailed connection verification?
1y
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8
what this IC does?
juancastelli

juancastelli

@copilot what this IC does?
1y

copilot

The LMV358IDTLMV358IDT is a dual, low-power operational amplifier (op-amp) from STMicroelectronics. Op-amps are versatile analog ICs that can amplify voltage signals. Here’s a brief overview of its properties and typical applications:
Key Features:
  • Low Supply Current: The LMV358LMV358 consumes very low supply current making it efficient for battery-powered applications.
  • Wide Supply Voltage Range: Operates from 2.7V to 5.5V, suitable for various applications.
  • Rail-to-Rail Output: Can output voltages that are very close to the supply rails, which is useful in low voltage operations.
  • Good Frequency Response: With a bandwidth of 1 MHz, it is suitable for a variety of audio applications.
  • Input Offset Voltage: It has a low offset voltage, which is important for precision applications.
Applications:
  • Audio Processing: Used to amplify and filter audio signals.
  • Signal Conditioning: Used to amplify low-level signals for further processing.
  • Sensor Interfaces: Works well in systems that need to amplify weak sensor signals.
  • General Analog Signal Processing: Can be used for various analog computation tasks such as filtering, summing, and differentiating.
Example Usage in Your Project:
In your specific audio peak detector project, the LMV358IDTLMV358IDT could be used to amplify the microphone signal and detect peaks, which is critical for audio signal processing.
Would you like to dive deeper into the functionality or connections of the LMV358LMV358 in your particular schematic?
1y
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6
hi
high-rang

high-rang

In french à quoi ce composant ?
1y
2y
2y

copilot

Hello! How can I assist you with your Audio Peak Detector project today?
2y
high-rang

high-rang

In french what is this componant ?
1y

copilot

Le composant que vous avez mentionné dans votre projet, un "Audio Peak Detector" utilisant un micro électret, serait appelé en français un "Détecteur de crête audio pour microphone électret". Si vous parlez d'un composant spécifique de votre projet, pourriez-vous préciser lequel vous intéresse ? Par exemple, l'amplificateur opérationnel serait appelé "amplificateur opérationnel", le condensateur "condensateur", la diode "diode", etc.
1y
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5
how do I use Flux?
bruniwis188

bruniwis188

@copilot how do I use Flux?
1y

copilot

Flux is a powerful browser-based electronics design tool that allows you to create schematics, lay out PCBs, and simulate circuits. Here’s a general overview of how to get started with Flux:
  1. Create an Account:
    • Visit flux.ai/signup and create an account using your email or by linking your Google account.
  2. Basic Navigation:
    • After logging in, you will be greeted with the main interface. Here you can start new projects or open existing ones.
    • The interface consists of a canvas where you can place and connect components.
  3. Placing Components:
    • To place components, you can drag components from the library onto the canvas. You can search for parts by part number or type.
  4. Making Connections:
    • Click on component pins to start a wire, then click on another pin to complete the connection. You can also use the "Take Action" button provided by the Copilot to perform specific connections.
  5. Positioning and Routing:
    • Position your components in a logical and organized manner. Use the routing tools to lay out PCB traces if you are designing a PCB.
  6. Simulation:
    • You can simulate your circuit to verify its functionality. Follow the simulator tutorial for detailed instructions on running simulations.
  7. Getting Help:
    • If you run into any issues or have questions, the best place for support is the Flux Slack community, where you can interact with the Flux team and other users. Additionally, there are video tutorials and other resources available on YouTube.
Feel free to ask if you have specific questions about any part of the process!
1y
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10
explain the possible problem that can arise from this circuit and posible solut...
chepin69

chepin69

@copilot explain the possible problem that can arise from this circuit and posible solutions
2y

copilot

Possible problems with the Audio Peak Detector SMD circuit and their corresponding solutions are as follows:
  1. Incorrect input impedance: The combination of R1, R2, and C1 at the input stage may not provide the proper input impedance for the electret microphone (MK1). To solve this, you may need to adjust the values of R1 and R2 according to the impedance requirement of the microphone you are using. Consult the microphone's datasheet to determine the ideal impedance values.
  2. Inadequate supply filtering for the op-amp: The circuit does not have a dedicated decoupling capacitor close to U1's VCC pin, potentially causing instability or noise. To improve supply filtering, add a decoupling capacitor (e.g., 100nF) close to the VCC pin of U1 (LMV358IDT).
  3. Limited frequency response: The passive components C1, R2, and R3 around the op-amp U1 may limit the frequency response of the peak detector. If you want to tailor the response for a specific frequency range, you may need to adjust these component values. Careful selection of the values allows for proper filtering and optimal peak detection.
  4. Inadequate diode speed: The 1N4148 diode (D1) has a reverse recovery time of around 4ns. This may not be fast enough for some applications, which may cause signal distortion or slow response. If faster response is required, you can consider using a Schottky diode or ultrafast diode as a replacement.
  5. Non-adjustable time constant: The circuit lacks a variable resistor to adjust the time constant of the peak detector. The time constant controls the discharge rate of capacitor C3, which in turn affects the sensitivity and response of the peak voltage detection. You can replace R5 with a potentiometer to fine-tune the time constant for different applications.
2y
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2
create a detailed step by step plan table for this project to verify its functio...
milanpopovic

milanpopovic

@copilot create a detailed step by step plan table for this project to verify its functionality.
1y

copilot

Absolutely, here's a detailed step-by-step plan to test and verify the functionality of this simple audio peak detector for electret microphones.

Table

StepActionDetails
1.Visual Inspection- Verify the correct placement of all components according to the schematic. Ensure there are no solder bridges or shorts.- Check that all component values (resistors, capacitors, etc.) match the specified values in the schematic.
2.Continuity Check- Use a multimeter to verify continuity for critical nets, such as power supply lines (VCC, GND).- Check the continuity for signal lines based on the schematic.
3.Power Supply Verification- Apply power to the circuit from a reliable power source.- Verify that the correct voltage is present at the power pins: VINV_{IN}:P1 to GND using a multimeter.
4.Microphone Signal Test- Connect the microphone (MK1) input to a known audio signal.- Use an oscilloscope to verify the presence of the audio signal at MK1 output (P).
5.Op-Amp Output Test- Verify the output of the first op-amp stage (U1:OUTPUT 1) using an oscilloscope. Ensure it amplifies the microphone signal correctly.- Adjust the audio signal and observe changes in the output to verify dynamic response.
6.Diode Rectification Test- Verify the presence of a rectified signal at the output of the diode (D1).- Observe the signal using an oscilloscope and verify it is a rectified version of the amplified signal.
7.Capacitor Filtering Test- Verify the presence of a clean, filtered peak signal at C3:P1 and compare it with the raw rectified signal.- Check with an oscilloscope to ensure there are no significant ripples.
8.Output Signal Test- Verify the final output signal at OUT:P1.- Ensure that the output corresponds to the peak of the input audio signal.
9.Adjust Component Values (if needed)- If the circuit does not behave as expected, adjust component values, such as resistor and capacitor values in the filter stage, to get the desired response.- Re-test the circuit after any adjustments.
10.Final Functionality Test- Re-test the entire circuit end-to-end to ensure reliable operation.- Document the results for future reference or iterations.
Additional Notes:
  • Ensure all connections are secure and there are no loose wires that might cause intermittent issues.
  • Take ESD precautions when handling sensitive components, particularly the op-amps and the electret microphone.
Let me know if you need further details or clarifications on any of the steps!
1y
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9
U1
Manufacturer Part Number
LMV358IDT
VIN
OUT
D1
Manufacturer Part Number
1N4148WS-7
OUT
R5
Resistance
10k Ω
C3
Capacitance
10u F
VIN
CONN1
C2
Capacitance
100n F
J1
VIN
please explain what MK1 does.
zambrands

zambrands

@copilot please explain what MK1 does.
1y

copilot

The component MK1 with MPN: POM-3042P-R is an electret microphone. Electret microphones are a type of condenser microphone that includes a pre-polarized diaphragm with a permanent electric charge. They are commonly used in audio applications for converting sound into an electrical signal.
Here's a bit more detail on its function within the circuit:
  • Sound Detection: The microphone captures audio waves from the environment and converts them into electrical signals. The sound waves cause variations in pressure that move the diaphragm of the microphone, generating a corresponding electrical signal.
  • Integration: In your project, the electret microphone is connected to the amplifier circuit. The output from the microphone is fed as an input to the op-amp in the form of weak electrical signals, which are then amplified to be used by the audio peak detector.
Connections related to MK1 in your project:
  • Power Supply: MK1:$N$ is connected to GND, ensuring that it has a stable reference voltage.
  • Signal Output: MK1:$P$ is connected to C1, which leads to further processing by the operational amplifier (U1) and other components.
Let me know if you have more questions about this component or others in the circuit!
1y
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create a high level mermaid block diagram of this project. Include key component...
ergn78

ergn78

@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, I can create a high-level block diagram of your Audio Peak Detector project using the mermaid syntax. Each block will include the designator and the manufacturer part number (MPN) where available.
Here's a high-level diagram:

Image

Connections
Passive Components
Power
Audio Signal
Processed Signal
Net
Ground
J1 Conn_01x03
GND
U1 LMV358IDT
C1 node_10uF
VIN
C2 node_100nF
OUT
C3 node_10uF
MK1 POM-3042P-R
R1 node_10k
R2 node_10k
R3 node_100k
R4 node_1k
R5 node_10k
D1 node_1N4148WS-7
This diagram represents the main components and their roles in the Audio Peak Detector. The connections between components are simplified for clarity. Let me know if you need any further customization or details!
1y
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12
  • Ground
    Ground
    A common return path for electric current. Commonly known as ground.
    jharwinbarrozo
    20.5M
  • Net Portal
    Net Portal
    Wirelessly connects nets on schematic. Used to organize schematics and separate functional blocks. To wirelessly connect net portals, give them same designator. #portal
    jharwinbarrozo
    43.0M
  • Power Net Portal
    Power Net Portal
    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
    jharwinbarrozo
    11.4M
  • Generic Resistor
    Generic Resistor
    A generic fixed resistor for rapid developing circuit topology. Save precious design time by seamlessly add more information to this part (value, footprint, etc.) as it becomes available. Standard resistor values: 1.0Ω 10Ω 100Ω 1.0kΩ 10kΩ 100kΩ 1.0MΩ 1.1Ω 11Ω 110Ω 1.1kΩ 11kΩ 110kΩ 1.1MΩ 1.2Ω 12Ω 120Ω 1.2kΩ 12kΩ 120kΩ 1.2MΩ 1.3Ω 13Ω 130Ω 1.3kΩ 13kΩ 130kΩ 1.3MΩ 1.5Ω 15Ω 150Ω 1.5kΩ 15kΩ 150kΩ 1.5MΩ 1.6Ω 16Ω 160Ω 1.6kΩ 16kΩ 160kΩ 1.6MΩ 1.8Ω 18Ω 180Ω 1.8KΩ 18kΩ 180kΩ 1.8MΩ 2.0Ω 20Ω 200Ω 2.0kΩ 20kΩ 200kΩ 2.0MΩ 2.2Ω 22Ω 220Ω 2.2kΩ 22kΩ 220kΩ 2.2MΩ 2.4Ω 24Ω 240Ω 2.4kΩ 24kΩ 240kΩ 2.4MΩ 2.7Ω 27Ω 270Ω 2.7kΩ 27kΩ 270kΩ 2.7MΩ 3.0Ω 30Ω 300Ω 3.0KΩ 30KΩ 300KΩ 3.0MΩ 3.3Ω 33Ω 330Ω 3.3kΩ 33kΩ 330kΩ 3.3MΩ 3.6Ω 36Ω 360Ω 3.6kΩ 36kΩ 360kΩ 3.6MΩ 3.9Ω 39Ω 390Ω 3.9kΩ 39kΩ 390kΩ 3.9MΩ 4.3Ω 43Ω 430Ω 4.3kΩ 43KΩ 430KΩ 4.3MΩ 4.7Ω 47Ω 470Ω 4.7kΩ 47kΩ 470kΩ 4.7MΩ 5.1Ω 51Ω 510Ω 5.1kΩ 51kΩ 510kΩ 5.1MΩ 5.6Ω 56Ω 560Ω 5.6kΩ 56kΩ 560kΩ 5.6MΩ 6.2Ω 62Ω 620Ω 6.2kΩ 62KΩ 620KΩ 6.2MΩ 6.8Ω 68Ω 680Ω 6.8kΩ 68kΩ 680kΩ 6.8MΩ 7.5Ω 75Ω 750Ω 7.5kΩ 75kΩ 750kΩ 7.5MΩ 8.2Ω 82Ω 820Ω 8.2kΩ 82kΩ 820kΩ 8.2MΩ 9.1Ω 91Ω 910Ω 9.1kΩ 91kΩ 910kΩ 9.1MΩ #generics #CommonPartsLibrary
    jharwinbarrozo
    1.5M
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Inspect

Audio Peak Detector SMD

Audio Peak Detector SMD
Description

Created
Last updated by milanpopovic
3 Contributor(s)
jecstronic
jharwinbarrozo
milanpopovic

Controls

Properties

Availability & Pricing

DistributorQty 1
Digi-Key$2.23–$2.66
LCSC$1.65
Mouser$2.46

Assets