Page 41 – Electronics-Lab.com

New Grid-EYE – 90° from Panasonic increases field of vision for Machine Learning based IR sensing

Posted on 10 December, 2023 by mixos

Panasonic Industry has launched a new member of its popular Grid-EYE sensor family featuring a 90° lens delivering a wider field of view (FoV) and reducing the number of sensors required to cover a given area to enable people counting and tracking applications. Privacy conscious designers have appreciated the 64 pixel resolution of the Grid- EYE family, and the Grid- EYE 90° will enhance systems designed to track and count the movement of people tracking as well as other applications.

Comments Osamu Mitsumura, Product Manager at Panasonic Industry Europe: “Knowing where people are is the key to design a smart space. Today, industries want to understand and optimize how their buildings are being used, especially the businesses in retail, hospitality and healthcare. Similarly, the lighting industry is increasingly moving towards providing personalized ambient spaces. The pandemic has also highlighted the importance of management of highly frequented or confined spaces – like offices or public washroom facilities. The holy grail of people-tracking/counting solutions has always been Scalability and cost-effectiveness. Grid-EYE 90° delivers both.”

A new sensor with 90° field of view for privacy conscious people tracking

Previously, Grid-EYE has been used in a variety of applications where absolute temperature values are used for detecting hot spots in a smart kitchen or hotter areas of a room for smart air conditioning.

At the same time, Grid-EYE is also highly suitable for people tracking/counting applications. Innovative product designers have used Grid-EYE 60° as a cost-effective alternative to camera or wireless solutions.

The new variant of Grid-EYE builds on Panasonic’s deep expertise of innovative sensing technologies. The new 90° wide-angle lens allows Grid-EYE to have a wider field of view (FoV), improving on previous sensors which offer a 36° and 60° FoV. With the launch of Grid-EYE 90°, system designers can capture the IR signature of a larger area, so fewer sensors are required to cover a given area. This makes it an ideal choice for enhancing the efficiency of people tracking/counting devices.

Low-Res Infrared and Machine Learning: A new approach to counting and tracking

Successful data acquisition using Grid-EYE is only the first step in successfully counting people. Different techniques can be employed to exploit the sensor data. The use of standard signal processing algorithms works well, but can run into difficulties with infrared sensors. Unlike visual spectrum devices where the quality of data is unambiguous, infrared signals can be tricky to handle when employed in devices – especially the ones with low resolution which can pick up noise very easily, such as Grid-EYE. Everyday occurrences like a hot coffee cup, an open window or an overheating computer, which are not even a subject of discussion in the visual spectrum, are daunting challenges in infra-red. This makes the algorithm development much more complex.

One way to overcome this problem is to use machine learning (ML). ML is a subset of Artificial Intelligence (AI) techniques, that emphasizes on the use of self-learning neural networks to derive inferences from the input data. The neural network can be trained using a known annotated dataset to design a ML model, which can be then deployed in field. This allows offloading complex tasks to neural networks, which previously required customized algorithm and expensive hardware.

Collaboration with CN Group on Dataset acquisition

An ML model with good performance can only be built by training on a good quality dataset. Contrary to more common applications like computer vision where there are rich datasets already available, sensors like Grid-EYE do not often have any datasets to begin with. Recognizing the need to bridge this gap, Panasonic has started a collaboration with CN Group, a software company which is part of the Ciklum company. CN Group has expertise in a wide array of topics including mechanical design, embedded electronics hardware and software, machine learning and IoT. Using a hardware setup which includes Grid-EYE sensor and a camera, CN Group is working to build datasets containing visual and thermal information from an observed scene. Furthermore, using computer vision techniques, the dataset is automatically annotated when humans are detected in the field of view of the camera. CN Group’s contribution in creating quick annotated datasets opens a wide array of possibilities in creating customized thermal datasets for any given location – meeting rooms, staircases, etc. Panasonic and CN group believe that that this collaboration will enable more customized/personalized ML systems for people-tracking/counting using Grid-EYE.

Learn more on the sensor on Panasonic Industry’s website: IR Thermophile array sensor – Grid-EYE | Panasonic Industry Europe GmbH

ENS161 Air Quality Sensor

Posted on 10 December, 2023 by mixos

ScioSense’s range of digital multi-gas sensors is designed for indoor air quality monitoring

ScioSense’s ENS161 is the latest addition to the ENS16x family, a range of digital multi-gas sensors specifically designed for indoor air quality monitoring. Both ENS160 and ENS161 combine the detection of a wide range of gases, including volatile organic compounds (VOCs) and oxidizing gases, with intelligent on-chip algorithms.

The sensor calculates a series of fully processed outputs such as CO₂ equivalents (eCO₂), total volatile organic compounds (TVOC) equivalents (eTVOC), and a 5-step air quality index (AQI) according to the German Environment Agency, Umweltbundesamt (UBA) (AQI-U), while the ENS161 additionally provides a 500-step relative AQI according to ScioSense (AQI-S) output.

While all this is done on-chip with no required libraries or additional overhead for external controllers or processors, the ENS161 introduces low-power operating modes. By lowering the sample rates of the sensor, low-power and ultra-low-power modes can be offered, reducing average current consumption to 700 µA or 150 µA, respectively. In addition to traditional smart home and building applications, this opens up wearables, battery-powered devices, smart things, and IoT applications to integrate air quality sensing in a space-saving 3 mm x 3 mm LGA package.

Features

Multiple, fully processed output signals including eTVOC, eCO₂, and AQI outputs AQI-U and AQI-S
Low power modes down to 150 μA current consumption
On-chip measurement and heater drive control with integrated sensor fusion and automatic baseline algorithms, no need for external libraries
TrueVOC® air quality sensor with excellent stability
Supply voltage V_DD: 1.71 V to 1.98 V
Wide operating ranges:
- Temperature (T): -40°C to +85°C
- Relative humidity (RH): 5% to 95%
Communication through I²C or SPI interface
Compact size: 3.0 mm x 3.0 mm x 0.9 mm LGA package
Options to access raw sensor data
Evaluation kit and dashboard software available

more information: https://www.sciosense.com/products/environmental-sensors/ens16x-digital-metal-oxide-multi-gas-sensor/

Nexperia Battery Life Booster IC

Posted on 10 December, 202310 December, 2023 by mixos

Battery Life Booster IC – Extend coin cell battery life and optimize peak current for pulse load

The NPS4053 switch limits the output current to a constant current by using a constant-current mode when the output load exceeds the current limit threshold or shorted. An internal voltage comparator disables the load switch when the output voltage is higher than the input to protect devices on the input side of the switch. The FLG pin is an active low output to indicate overcurrent, over temperature and reverse voltage conditions.

Features & benefits

Programmable constant battery load current: 2 mA to 16 mA
Protection against battery voltage dips (Brown-out)
Pulse output current: 150 mA
Regulated programmable output voltage: 1.8 V to 3.6 V
Low output voltage ripple
Ultra-low standby current: < 20 nA
Typical conversion efficiency of 90% with adaptive optimization
Integrated fuel gauge
Integrated balancing circuit
One auxiliary regulated output pin
Small 16 pin lead-free package (SOT763-1/DHVQFN16; 2.5 mm × 3.5 mm × 0.85 mm)
Specified from -40 °C to +85 °C

more information: https://www.nexperia.com/products/analog-logic-ics/power-ics/load-switches/series/NPS4053-Q100.html

nRF7002 Based Arduino Shield: Nordic Adds Wi-Fi 6 to Arduino and RPi

Posted on 10 December, 202310 December, 2023 by Debashis Das

The nRF7002 EK is a Wi-Fi 6 evaluation kit in an Arduino-compatible form factor. It’s designed to integrate with various Nordic development kits like the nRF52840 and supports the nRF Connect SDK and code samples. This kit includes the nRF7002-based Arduino Shield and other peripherals. Additionally, Nordic has released a Linux driver for the nRF70 series, enabling compatibility with Raspberry Pi devices.

The nRF7002 is a compact, energy-efficient Wi-Fi 6 chip by Nordic Semiconductor, designed for IoT devices. It supports dual-band Wi-Fi and Bluetooth LE and can be interfaced with SPI/QSPI bus, which makes it ideal for a lot of microcontrollers. It leverages Target Wake Time to save power. It’s integrated into the nRF Connect SDK for development ease.

This board can be integrated with the nRF Connect SDK, and for simplicity, it also includes sample code for development. The whole device is designed with an Arduino shield in mind but its compatibility with standard Arduino boards isn’t specified by Nordic, particularly regarding the use of Wi-Fi/Bluetooth coexistence features. However, it could be managed by an Arduino via the SPI interface with custom-written software.

Nordic recently introduced a Linux driver for its nRF70 chips, which has been successfully tested with a Raspberry Pi 4 using Ubuntu 22.04 64-bit. This setup involved connecting the nRF7002 Evaluation Kit (EK) through a special interposer board. While this interposer board is not available for purchase, its design files are accessible for anyone to build.

Specifications of nRF7002 Based Arduino Shield:

Wireless chip – Nordic Semi nRF7002
Dual-band Wi-Fi 6 (802.11ax)
Wi-Fistation mode
Target Wake Time (TWT)
20 MHz channel bandwidth
Antenna – 2.4 and 5 GHz antenna for Wi-Fi
SWF port for RF measurement
Host interface – SPI or QSPI interfaces
Dimensions – Arduino shield form factor

The nRF7002 Evaluation Kit is priced at $19 (Not Including Shipping) and available on Crowd Supply, as well as through distributors like Mouser and Digikey. For more information, you can visit the product page.

ESP32-S3 with 3.4-inch Touchscreen: LILYGO New Display Board

Posted on 10 December, 202318 January, 2024 by Debashis Das

LILYGO’s latest T-Display-S3-Long is an ESP32-S3 board featuring a unique 3.4-inch wide touchscreen with a 640×180 resolution, tailored for various applications.

This wireless display board features an ESP32-S3R8 WiSoC with 8MB PSRAM and includes a 16MB SPI flash for storage. It also offers two Qwiic connectors, a 30-pin header for additional attachments, a USB Type-C port for power and programming, and a 2-pin connector for an optional LiPo battery. This makes it versatile for various wireless applications.

In the above parts marking image, you can see the placement of the 3D Wi-Fi Antenna, the Qwicc connectors, and the USB-C connector this becomes important because you will need those measurements if you are trying to make an enclosure for this. you can also verify the placement of other critical components like the power switch, the boot, and the power switch, on the ESP32-S3 with a 3.4-inch Touchscreen. You can also verify the placement of the JST battery connector.

The T-Display-S3-Long from LILYGO offers firmware and samples for PlatformIO/Arduino, including factory test code, TFT and touchscreen samples, and an LVGL demo. It also includes PDF schematics, datasheets, and basic documentation on GitHub. However, due to limited documentation and lack of complete projects, it’s best suited for those experienced in Arduino/PlatformIO programming. Beginners might find it challenging to use.

When you purchase the T-Display-S3-Long board, it comes with a set of accessories that includes one T-Display-S3-long-3.4-V1.0 screen, two STEMMA QT/Qwiic interface lines marked with [P352], one battery cable, and one 1.27mm female pin connector with a 2×15 pin layout.

ESP32-S3 Based T-Display-S3-Long Board Features:

MCU: ESP32-S3R8, dual-core, AI acceleration, 512KB RAM, 8MB PSRAM, Wi-Fi & Bluetooth connectivity
Storage: 16MB flash
Display: 3.4-inch TFT LCD, 640×180, capacitive touchscreen
Connectivity: Wi-Fi 4, BLE 5.0, Bluetooth Mesh, 3D antenna
USB: Type-C OTG port, SY6970 chip for power, charging, and programming
Expansion: 2 Qwiic I2C connectors, 30-pin header
Other: Boot/Reset buttons, power switch for battery/USB
Power: 5V USB-C, LiPo battery connector, SY8089AAAC regulator
Size: 92 x 28 x 16 mm

You can purchase the LILYGO’s T-Display-S3-Long ESP32-S3 board at Aliexpress for $34.98 with shipping, but at the time of writing this article, only 6 pieces are left. more information on the device can be found on LILYGO’s official webpage.

New Software Update Enables Bluetooth for Pico W

Posted on 10 December, 202310 December, 2023 by Debashis Das

In a recent announcement, Raspberry Pi has released 1.5.1 of the C SDK along with the latest MicroPython build. This update enables Bluetooth on the Raspberry Pi Pico W.

Launched last year, the Raspberry Pi Pico W is a small, $6 computer module that can be used for various electronics projects. While releasing the board last year, the board already came with the Infineon CYW43439 module that supports both Wi-Fi and Bluetooth functionality but lacked the necessary drivers required to enable that. But with the new update, you can now use Bluetooth Classic and BLE on this device.

Technical Details:

The Pico W’s new Bluetooth functionality is available through an update in the C SDK version 1.5.1 and the latest MicroPython build.
It supports Bluetooth Classic (except ACL/SCO) and BLE, in both Central and Peripheral roles.
Users have the flexibility to use Bluetooth Classic, BLE, or both.

For those eager to explore this new feature, the Raspberry Pi team has updated their documentation and written a book titled ‘Connecting to the Internet with Raspberry Pi Pico W‘. These resources guide you through using Bluetooth LE with both the C SDK and MicroPython. You can also get the latest version of Micropython on their GitHub Rep0.

According to Raspberry Pi Integrating Wi-Fi and Bluetooth in the Pico W was a complex task. and Raspberry Pi extends its gratitude to Infineon. The Bluetooth functionality is powered by the BTstack library from BlueKitchen, with this Pico W users will also benefit from a commercial license for BTstack, allowing them to use it in their products.

If you are trying to get your hand on a Raspberry Pi Pio W you can get it from their official website.

Sixfab 5G Raspberry Pi 5 Kit Featuring Quectel RM502Q-AE M.2 Module

Posted on 10 December, 2023 by Debashis Das

The New Sixfab 5G HAT for Raspberry Pi 5 features a Raspberry Pi HAT powered by the Quectel RM502Q-AE 5G Sub-6GHz M.2 module for global use (excluding China). Additionally, the HAT features a unique internal antenna designed by SixFab for Sub-6 frequency bands and comes with a USB 3.0 bridge connector.

The Quectel RM502Q-AE is a versatile 5G module for Internet of Things or Enhanced Mobile Broadband (eMBB) applications. It supports 5G Sub-6 GHz frequencies and can transmit high-speed data with downlink rates up to 5 Gbps and uplink rates up to 650 Mbps. Its M.2 form factor and support for MIMO technology make it a powerful choice for applications like industrial routers, PDAs, and rugged tablet applications.

The Quectel module used in this HAT has support for GNSS, but the company decided to deactivate this feature instead they chose to utilize the USB 3.0 port on the Raspberry Pi for connection. This can be due to the lack of documentation available for the new PCIe connector for RPi 5.

The company indicates that the module is not exclusive to the Raspberry Pi 5; since it communicates via USB, it is also compatible with NVIDIA Jetson Nano, Beaglebone, Asus Tinkerboard, NXP i.MX 8 devkits, and regular Windows and Linux PCs, drivers for which are available on their website.

Seeing the design of this board I initially thought that the GPIOs on the RPi would be free to use, but after going through the documentation it was clear that some of the GPIO pins are used to control a fan, turn on/off HAT, select the SIM, access the user button-the user LED and power LED, and some other features.

Key Features of the Sixfab 5G Modem Kit for Raspberry Pi 5

Sixfab 5G Modem HAT for Raspberry Pi 5:
- Includes M.2 socket for 5G module.
- Nano SIM card holder and embedded SIM support.
- USB 3.0 port and 40-pin GPIO header for Raspberry Pi 5 SBC connection.
- User button for easy interaction.
- Status, power, and user (GPIO21) LED indicators.
- EEPROM for Raspberry Pi HAT compliance.
- 2-pin fan connector for cooling.
- Power supply through 5V USB Type-C port (on HAT).
- Dimensions: 88.1 x 57.7 x 21.7 mm.
- Approvals (FCC, IC, CE, UKCA) are in progress.
Quectel RM502Q-AE M.2 Module:
- Supports 5G NR: 3GPP Release 15 NSA/SA operation, Sub-6 GHz.
- LTE Category: DL Cat 20/ UL Cat 18.
- Maximum data rates:
  - 5G SA Sub-6: Up to 4.2 Gbps (DL)/450 Mbps (UL).
  - 5G NSA Sub-6: Up to 5 Gbps (DL)/650 Mbps (UL).
- Host interfaces: USB 3.1 or PCIe 3.0.
- Dimensions: 52 x 30.0 × 2.3 mm.
- Weight: 8.4 grams.
Additional Components:
- Extra tall 40-pin GPIO stacking header.
- Power supply: 5.1V 3.0A DC adapter with universal plugs.
- Plastic spacer kit.

The Sixfab 5G modem kit for Raspberry Pi 5, although compact, remains a high-cost option. The module kit can be purchased for $450 on the company’s website.

Metro ESP32-S3 is The Next Generation IoT Board with Circuit Python Support

Posted on 10 December, 202310 December, 2023 by Debashis Das

The Adafruit Metro ESP32-S3 is a development board based on the ESP32-S3, designed in a form factor similar to an Arduino UNO or Adafruit Metro. The board features built-in Wi-Fi Bluetooth capabilities and can be programmed with Arduino or Circuit Python.

The core of the board is an ESP32-S3 microcontroller, which includes a dual-core LX7 processor clocked at 240 MHz. Additionally, it has integrated 2.4GHz Wi-Fi and Bluetooth 5 (LE), secure boot, and flash encryption features. In terms of memory, it boasts 16 MB Flash and 8 MB PSRAM, supports full-speed USB OTG, and has efficient low-power management for various applications.

The board comes with two STEMMA QT I2C connectors for further IO expansion, a JTAG header for debugging, a microSD card for extended storage, and a two-pin LiPo connector with an integrated battery protection feature. The board is primarily powered by a 5V USB-C connector but there is also this barrel jack for a max of 12V input power.

When it comes to software, the board can be programmed with Circuit Python but you can also program this board with Arduino IDE and ESP-IDF. You can find all the hardware guide and software installation guides on Adafruit’s website. The most fun thing about this board is that the board allows for the installation of Linux, for which Adafruit provides a dedicated guide.

Adafruit Metro ESP32-S3 Key Specification:

Wireless Module: ESP32-S3-WROOM-1.
Processor: ESP32-S3 dual-core LX7, up to 240 MHz, with Vector extension for machine learning.
Memory: 8MB PSRAM.
Storage: 16MB SPI flash; MicroSD card slot.
Connectivity: WiFi 4, Bluetooth 5 with LE/Mesh; PCB antenna.
Certifications: FCC/CE.
USB: USB Type-C for power and programming.
Expansion Options:
- Arduino UNO-compatible headers.
- STEMMA QT connector for I2C devices (with power switch).
Debugging Tools:
- Serial via USB-C.
- 10-pin JTAG header.
- Optional serial debug output pins.
Additional Features:
- Reset and DFU buttons for ROM bootloader access.
- LEDs (On/Charge/User) and status NeoPixel with controlled power.
Power Supply:
- 6V-12V DC via DC jack.
- 5V via USB Type-C.
- LiPo battery support with charging over USB-C; MAX17048 I2C battery monitoring chip.
Power Consumption: Deep sleep mode uses ~100uA from a LiPo battery.
Dimensions: 72 x 53.2 x 14.8mm (Arduino UNO form factor).

A few months back Adafruit the Rev A of the Metro ESP32-S3 board, but it had an issue where they shared signals between the PSRAM, NeoPixel RGB LED, and SPI/SD card pins. That caused malfunctions when these particular features were used together. So Adafruit now offering replacements for those who bought the board before November 8.

You can purchase the Rev B of the board on Adafruit for $24.99 which does not include shipping.

Elecrow’s LR1302 is A LoRa Gateway Module for Advanced IoT Applications

Posted on 10 December, 202310 December, 2023 by Debashis Das

The LR1302 is a new and advanced LoRa gateway module with a mini PCIe form factor. Powered by Semtech’s SX1302 chip, this device can achieve high performance with low power consumption. It can handle 8-channel data transmission, which makes it suitable for applications like industrial automation and smart city management.

At the core of the module, we have the Semtech Network’s SX1302 LoRaWAN chip that surpasses its predecessors (SX1301 and SX1308) in terms of better sensitivity, lower power consumption, and reduced operating temperature.

The LR1302 module is compatible with EU868 (863-870MHz) and US915 (902-928MHz) all credit to the Semtech SX1302 Chip. It features a sensitivity of -125dBm @125K/SF7 and -139dBm @125K/SF12, with TX power of 26 dBm for EU868 and 25 dBm for US915, while operating on a 3.3V power supply.

The LR1302 module features 8-channel data transmission which becomes a must-have where there is a need for high throughput. The device operates at ultra-low operating temperature which removes the need for extra cooling. Additionally, it complies with CE and FCC certifications, streamlining the certification process for products.

The LR1302 module is a small, compact device with a mini PCIe interface with 52 pins. It comes in two versions, SPI and USB, each with different power usage. this device has a wide operating range which ranges from -40°C to 85°C, so it can adapt well to diverse environmental conditions.

LR1302 LoRaWAN Gateway Features:

Chipset: Semtech SX1302
Frequency Bands: 863-870MHz (EU868), 902-928MHz (US915)
Channels: 8
Sensitivity: -125dBm @125K/SF7, -139dBm @125K/SF12
TX Power: 26 dBm (EU868), 25 dBm (US915) with 3.3V supply
Power Consumption: Standby – 7.5 mA, TX max – 415 mA, RX – 40 mA
Connectivity: 1x U.FL antenna connector
Indicators: 3 status LEDs
Features: LBT (Listen Before Talk) support
Operating Temperature: -40°C to 85°C
Physical Size: 30 mm × 50.95 mm, Mini PCIe form-factor, 52-pin connector

The LR1302 LoRaWAN Gateway Module is priced at $23.90. As of now, only the EU868 version is in stock. Note that the module does not come with the LoRaWAN HAT for the Raspberry Pi. The Wiki page provides more information on the setup process.

Digital to Analogue Converter (DAC)

Digital-to-Analogue Converter (Binary Weighted)

The Digital-to-Analogue Converter (DAC) are opposite of the Analogue-to-Digital Converter. It employs a method by which binary digital signals are transformed into analogue signals. With its output (voltage or current) proportionate to the value of its digital input number, DACs transform binary or non-binary numbers and codes into analogue ones.

Conversion of digital to analogue (DAC) is a method by which binary digital signals are transformed into analogue signals, which have an endless number of possible states. For example, a 4-bit digital logic circuit converts 0000₂ to 1111₂ (F₀ to F₁₅), wherein a voltage output ranging from 0 to 10V is produced by the DAC.

There are several ways to convert an “n”-bit digital input code into an equivalent analogue output voltage between 0 and some V_MAX value, but the most popular and simple conversion techniques use an operational amplifier and a resistor ladder network, or weighted resistors and a summing amplifier.

The weights determined by the resistive values employed in the ladder networks provide a varied “weighted” amount to the signals generated in both digital-to-analogue conversion methods, which result in a weighted sum output.

Operational Amplifiers

Negative feedback reduces and controls the extremely high open-loop gain (A_OL) of operational amplifiers, for this purpose inverting op-amp circuit is used. A tiny portion of the output signal is sent back to the input terminal to accomplish this.

The input voltage V_IN of the amplifier is linked directly to its inverting input through an appropriate input resistor R_IN. The closed-loop voltage gain, A_V(CL), of an inverting amplifier is given by the ratio of these two resistors, as indicated.

**Figure 1: Inverter Operational Amplifier Circuit**

From the above fig, we see that V_O is calculated by multiplying V_IN by the closed-loop Gain (A_CL), which is based on the input resistance (R_IN) divided by the feedback resistance (R_F). Therefore, we may modify the closed-loop gain of the op-amp and, the value of V_O (I_F*R_F) for a given input signal by adjusting the values of either R_F or R_IN.

Digital-to-Analogue Converter (Summing Amplifiers)

The aforementioned instance of an inverting operational amplifier uses a single input voltage signal. However, what would happen to the circuit and its gain if we introduced another input resistor for combining two or more analogue signals into a single output?

The single input circuit above may be changed into a summing amplifier, or more specifically, a “summing inverting voltage amplifier” circuit, by connecting numerous inputs to the operational amplifier’s negative end.

Any input signals are essentially electrically separated from one another because the feedback resistor’s R_F negative feedback sets the op-amp’s inverting input at zero potential. The output, then, is the inverted sum of all the input signals. As a result, when a summing amplifier is in the inverting mode, it generates the negative sum of all input voltages, but when it is not inverting, it generates the positive output. Examine the circuit below.

We may adjust the initial equation for the inverting amplifier arrangement above to account for these four additional input values as follows: In the summing amplifier circuit above, the output voltage (V_O) is proportional to the sum of the four input voltages, V_IN1, V_IN2, V_IN3, and V_IN4.

Then, when each input voltage is multiplied by its matching gain and added to the subsequent one to get the total output, we can see that the output voltage is an inverted, scaled sum of the four input voltages.

Each input channel will have a closed-loop voltage gain of unity (1) if all the resistances are the same and have similar values, that is, R_F = R₁ = R₂ = R₃ = R₄. As a result, the output voltage can be found easily by the mentioned equation:

Digital-to-Analogue Converter (4-Bit Binary Weighted)

A 4-bit binary weighted digital-to-analogue converter can be created by assuming that the four inputs of the summing amplifier are binary inputs with voltage values of either 0 or 5 volts (“Low-0” and “High-1”) and by doubling the resistive values of each input resistor to the previous one. This will result in an output condition that would be the weighted sum of these four input voltages.

With the four input resistors ranging from 1kΩ to 8kΩ (or multiples thereof), we may build a straightforward 4-bit binary weighted analogue-to-digital converter circuit as illustrated by labelling the four summing inputs as A, B, C, and D and setting R_F = 1kΩ.

There are 2⁴ = 16 possible combinations for a 4-bit binary number, ranging from 0000₂ to 1111₂. 8-4-2-1 is the binary coding ratio that results from doubling the weight of each input bit to the previous one.

**Figure 3: 4-Bit Binary weighted Digital to Analogue Converter**

The transfer characteristic of the 4-bit binary weighted digital-to-analogue converter would therefore be as follows if we set the input resistances for “D” at 1kΩ, “C” at 2kΩ (i.e., the double of D), “B” at 4kΩ (double of C), and “A” at 8kΩ (double of B), with the feedback resistance (R_F) set at 1kΩ as shown in the figure above,

If we apply a TTL voltage of +5 volts (logic “1”) to the summing amplifier’s input V_D, which represents the most significant bit (MSB), we see that the gain of the op-amp will be R_F/R₄ = 1kΩ/1kΩ = 1 (unity) V_D, Therefore, the output of the digital-to-analogue converter circuit will be -5 volts when a 4-bit binary code of 1000 is applied.

Similarly, if the input V_C of the summing amplifier receives +5 volts (logic 1), the gain of the op-amp is equal to R_F/R₃ = 1kΩ/2kΩ = 1/2 (one-half). Therefore, the analogue output voltage of -2.5 volts would be produced by the 4-bit binary code 0100.

When Logic “1” is applied to the V_B, the gain of the amplifier will be R_F/R₂ = 1kΩ/4kΩ = ¼ (one-fourth). Hence, the 4-bit binary code of 0010 will produce an output voltage of -1.25 volts.

Ultimately, when logic “1” is applied to the least significant bit (LSB) input of the summing amplifier V_A, It would result in an output voltage of -0.625 volts (a 12.5% resolution) and R_F/R₁ = 1kΩ/8kΩ = 1/8 (one-eighth) with the 4-bit binary code of 0001.

The mentioned table will give the detailed result of V_O when +5 volts is applied to 4-bit binary weighted analogue-to-digital converter.

From the above values, we observed that, for each bit changed, there would be a difference of 0.625 volts.

The resolution of the analogue output voltage for a binary-weighted digital-to-analogue converter may be enhanced by increasing the number of binary digits and the resistive summing network such that each resistor has a separate weighting.

For instance, an 8-bit DAC with +5 input volts; will produce (1/128)*5 = 0.0039, similarly, a 12-bit DAC will result in (1/2048)*5 = 0.0024 volts per change in the input binary code.

The downside here is that for a “n”-bit DAC, a binary weighted resistor DAC necessitates a wide range of high precision resistors (one per bit), which makes it unfeasible (and costly) for converters with higher resolution than a few bits.

But by transforming it into an R-2R resistor ladder DAC, which only needs two precise resistance values—R and 2R—we may build on the concept of a binary weighted digital-to-analogue circuit arrangement that employs variable value resistors. We will examine how the R-2R Digital-to-Analogue Converter transforms a digital binary number into an analogue voltage output using just two resistor values in the upcoming update about digital-to-analogue converters.

Conclusion

The Digital-to-Analog Converter (DAC) translates digital data in binary format into analogue signals, such as voltage or current, based on the value of its digital input number.
Inverting Operational Amplifier Circuit is used for the conversion of digital signals to analogue ones. Negative feedback lowers and regulates the operational amplifiers’ extraordinarily high open-loop gain (A_OL).
The closed-loop Gain (ACL) is derived by dividing input resistance (R_IN) by the feedback resistance (R_F). The output Voltage VO is calculated by multiplying the input voltage VIN and Gain (A_CL).
The “Summing Inverting Voltage Amplifier” circuit is used for multiple inputs; inputs are connected to the negative end of the operational amplifier, herein the output voltage (V_O) is proportional to the sum of all the input voltages.
The transfer characteristic of the 4-bit binary weighted digital-to-analogue converter with +5 volts input, with the feedback resistance (R_F) set at 1kΩ, 8-4-2-1 binary weighted DACs will provide an output voltage change of 0.625 volts for each bit that is modified.
The drawback is that a binary weighted resistor DAC for a “n”-bit DAC requires a large range of high precision resistors (one per bit), which renders it impractical (and expensive) for converters with resolutions of more than a few bits. We use R-2R resistor ladder DAC for high resolution.