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  1. With the Internet of Things (IoT), everyday objects can now connect and exchange data. These smart objects are embedded with sensors, software, and other technologies to facilitate communication and data exchange with similar systems and devices over a network, typically the Internet. By the end of 2025, it is estimated that there will be 38.6 billion IoT-connected devices worldwide. Managing such many devices necessitates a secure and reliable network to support them all. This is where the emerging technology of the Narrowband Internet of Things (NB-IoT) comes into play. Get PCBs for Your Projects Manufactured You must check out PCBWAY for ordering PCBs online for cheap! You get 10 good-quality PCBs manufactured and shipped to your doorstep for cheap. You will also get a discount on shipping on your first order. Upload your Gerber files onto PCBWAY to get them manufactured with good quality and quick turnaround time. PCBWay now could provide a complete product solution, from design to enclosure production. Check out their online Gerber viewer function. With reward points, you can get free stuff from their gift shop. Also, check out this useful blog on PCBWay Plugin for KiCad from here. Using this plugin, you can directly order PCBs in just one click after completing your design in KiCad. What is NB-IoT technology? Narrowband IoT, abbreviated as NB-IoT, or LTE-M2, is a novel wireless technology that deviates from the standard licensed LTE framework. It is an LPWAN (Low Power Wide Area Network) technology operating independently in previously unused 200-kHz bands, initially allocated for Global Systems for Mobile Communications networks (GSM). In 2016, telecommunications giants such as Huawei, Ericsson, Qualcomm, and Vodafone collaborated to designate NB-IoT as 5G technology. They collectively established this standard in conjunction with 3GPP. This emerging technology is being employed to enable a myriad of new IIoT (Industrial IoT) devices, encompassing applications like smart parking, wearables, utilities, and industrial solutions. Why NB-IoT? Narrowband IoT (NB-IoT) enables multiple devices to transmit data even without standard mobile network coverage. The licensed frequency spectrum it utilizes does not interfere with other devices, ensuring more reliable data transfer. As a standards-based Low Power Wide Area Network (LPWAN) technology, NB-IoT can cover expansive areas while consuming minimal energy. NB-IoT enjoys support from major mobile equipment, module, and chipset manufacturers. It can coexist with 2G, 3G, and 4G mobile networks. Its simple infrastructure allows for faster and more straightforward implementation. Additionally, Narrowband IoT can leverage the security and privacy features inherent in mobile networks. Advantages of NB-IoT Power-Efficient and Cost-Effective – Narrowband-IoT exhibits low energy consumption while covering vast areas, connecting up to 50,000 devices per NB-IoT network cell. This enhances the power efficiency of user devices and contributes to the overall cost-effectiveness of the system. The minimal power consumption allows for a battery life exceeding ten years. Secure and Reliable – Leveraging a licensed spectrum ensures greater reliability for users and guarantees resource allocation for managed Quality of Service (QoS). This results in less interference and more reliable transmissions. The underlying technology is straightforward to design, develop, and deploy. It incorporates security and privacy features comparable to LTE mobile networks, supporting user identity confidentiality, data integrity, entity authentication, and mobile equipment identification. Wider Deployment and Global Reach – Narrowband-IoT, with lower bit rates than LTE-M1, can directly connect sensors to the base station without requiring a gateway for connectivity. This characteristic makes it an excellent option for extensive deployment at lower costs. NB-IoT is capable of functioning in deep underground and enclosed spaces. Utilizing a mobile wireless network enhances scalability, providing a broader global reach. Check NB-IoT coverage countries here. Barriers to NB-IoT Easy deployment and good range are just a few of the advantages of NB-IoT. However, as with all technology, NB-IoT also comes with a few limitations, including the following: The data rate is low compared to LTE cat-M1. NB-IoT is considered ideal for idle devices. No support for VoLTE (Voice Over LTE) for speech transmission means no voice transmission. Roaming, though expected soon, is not supported yet. With LTE support finding favor with carriers, deployment could be a problem. Increased initial costs. NarrowBand-IoT in India In India, the predominant practice among mobile operators is to utilize the 900 MHz licensed band for NB-IoT operations. Major players in the Indian Telecom sector have already highlighted the potential use cases for NB-IoT deployment. They frequently emphasize the benefits that businesses and the government can derive from adopting this technology, particularly in the pursuit of Smart Cities. NB-IoT in India holds promise for various applications within a smart city context, ranging from air-quality monitoring and smart parking to damage prediction in the event of a disaster and waste management. Several countries have already initiated the deployment of such solutions and are actively seeking ways to enhance and expand them. NB-IoT has the potential to emerge as a mainstream technological resource in India, positioning the country among the leading global technology innovators. In India, two major telecom service providers, Reliance Jio and Airtel, have introduced NB-IoT services. However, these services are not commercially available for individual users, unlike in other countries where single users can access such services. To utilize NB-IoT services in India, users are required to make purchases through registered firms in large quantities. I obtained this information through interactions with the respective company sales teams. In my attempts to gather technical details, I engaged with Jio and Airtel over several months, holding a series of regular meetings. Unfortunately, Jio repeatedly denied my requests and did not provide basic information regarding the technical aspects. This experience left me dissatisfied with the Reliance Jio NB-IoT sales team. Airtel NB-IoT provided us with the opportunity to conduct basic functionality tests of NB-IoT in their IoT lab. My objective was to assess how NB-IoT works in India. I requested a set of tests to evaluate the performance of NB-IoT connectivity. Before testing NB-IoT in India, I conducted tests on NB-IoT technology in the USA remotely, with the assistance of my friends. For the USA tests, I utilized the nRF Thingy 91 and Arkessa SIM. These tests were successful, and I was able to integrate them with Edge Impulse. Upon returning to India, we tested NB-IoT connectivity using the nRF9160 Development Kit with an Airtel NB-IoT SIM. During this period, I had the opportunity to discuss the NB-IoT test details with Gaurav Kapoor and his team from Nordic Semiconductor. They provided valuable assistance in testing the nRF9160. The nRF9160 was tested at the Airtel Manesar lab, where a straightforward Ping test was conducted using nRF9160 AT commands. The test utilized firmware versions nRF9160_1.3.4 and nRF Connect SDK v2.3.0. Airtel also has an IoT lab in Bengaluru, where NB-IoT-related tests can be conducted. To access the lab, prior permission must be obtained from the respective teams. Google Ping Test using nRF9160 DK and Airtel NB-IoT Service Conducted a Google Ping test utilizing the nRF9160 Development Kit and Airtel's NB-IoT service. The test involved sending Ping requests to Google servers to assess the round-trip time for responses. The nRF9160 DK, coupled with Airtel's NB-IoT service, served as the platform for evaluating the connectivity and performance of the NB-IoT network in this specific test. Step 1: Check the current network registration status of the nRF9160 modem. AT+CEREG=? This command is Essential for determining if the device is connected to the cellular network and able to send and receive data. Step 2: Searches for available cellular networks in the surrounding area. AT+COPS=? Step 3: Verify the configuration of Packet Data Protocol (PDP) contexts, which are essential for establishing data connections over a cellular network. AT+CGDCONT? It retrieves information like the Access Point Name (APN), PDP type, and other parameters for each defined context. Step 4: Initiate a ping operation to test connectivity to a specified IP address or hostname. AT+PING = "www.google.com",45,5000,5,1000 Syntax: AT+PING=<destination_IP_or_hostname>,<packet_size>,<timeout>,<count>,<interval> destination_IP_or_hostname: The IP address or hostname to ping (in this case, "www.google.com") packet_size: The size of the ping packets in bytes (45 bytes in this example) timeout: The maximum time to wait for a response in milliseconds (5000 ms in this example) count: The number of ping packets to send (5 in this example) interval: The time interval between sending ping packets in milliseconds (1000 ms in this example) Received Response for the Ping Output from Wireshark nRf9160 AT Commands Follow the link provided, to know AT Commands in detail. https://infocenter.nordicsemi.com/pdf/nrf9160_at_commands_v2.2.pdf Note: NB-IoT is not deployed in all states of India
  2. 1. Ecosystem LoRaWAN is supported by the LoRa Alliance, an open non-profit association composed of more than 500 members. Its members work closely together and share experiences, promote and promote the success of the LoRaWAN protocol, and become the leading and open global standard for secure, carrier-grade Internet of Things LPWAN connections. NB-IoT is supported by two telecommunications standards associations, 3GPP and GSMA, both of which have the same goal of promoting the interests of mobile networks and equipment. 2. Spectrum LoRaWAN is optimized for ultra-low power consumption and remote applications. Therefore, network operators and equipment manufacturers can access the networks running on the license-free ISM Sub-1GHz spectrum for free. NB-IoT uses a cellular spectrum network, which is optimized for spectrum efficiency. The licensing fee for frequency band usage is very high, and it is limited to a few operators. 3. Deployment status According to the LoRa Alliance, 83 public network operators in 49 countries are currently using LoRaWAN, and more private companies are also using LoRaWAN networks. GSMA is an organization representing the interests of NB-IoT, LTE and other mobile networks. According to it, 40 countries will launch NB-IoT networks in the future. 4. Deployment options LoRaWAN network provides highly flexible deployment. It can be installed in a public, private, or mixed network, indoor or outdoor. LoRaWAN signals can penetrate into urban infrastructure, and each gateway can cover 30 miles (approximately 48.3 kilometers) in an open rural environment. NB-IoT uses LTE cellular infrastructure, which is an outdoor public network and requires the deployment of 4G/LTE cellular towers. If the sensor exceeds the coverage area of the base station, the base station is not easy to move. 5. Protocol The LoRaWAN protocol sends data asynchronously, and the data is sent only when needed. This can extend the battery life of the sensor device up to 10 years, and the battery replacement cost is low. NB-IoT needs to maintain a synchronous connection to the cellular network, regardless of whether it needs to send data. For sensor devices, it consumes a long battery life, resulting in high battery replacement costs, which may be too costly in many applications. 6. Emission current LoRaWAN provides 18 mA emission current at 10 dBm, and 84 mA emission current at 20 dBm. Modulation differences can enable LoRaWAN to support very low-cost batteries, including button batteries.  The NB-IoT sensor consumes ~220 mA at 23 dBm and 100 mA at 13 dBm, which means that it needs more power to operate and requires more frequent battery replacement or a larger capacity battery. 7. Receive current LoRaWAN provides lower sensor BOM cost and battery life for remote sensors. The receiving current is about 5 mA, and the overall power consumption is reduced by 3-5 times.  The NB-IoT receiving current is about ~40 mA. The communication between the cellular network and the device consumes more than 110 mA on average, and a communication lasts for tens of seconds. The protocol overhead has a significant impact on the battery life of devices that need to work for 3, 5, or 10 years or more. 8. Data rate LoRaWAN data rate is about 293 bps-50 kbps. The LoRaWAN protocol dynamically adjusts the data rate according to the distance between the sensor and the gateway, thereby optimizing the air time of the signal and reducing conflicts. The peak data rate of NB-IoT is about 250 kbps, which is more suitable for use cases with higher power budget and higher data rate (above 50 kbps). 9. Link budget LoRaWAN's MCL signal varies according to regional regulatory restrictions. The link budget is between 155 dB and 170 dB.  NB-IoT needs to repeat remote sensors at a low bit rate in order to be able to support remote sensors. The link budget is up to 164 dB. 10. Mobility LoRaWAN can support mobile sensors to track the movement of assets from one place to another. Even without GPS, high enough accuracy can be obtained for many applications.
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