Low Power Wide Area Network (LPWAN for short), that is, low-power wide-area network, is mainly used for communication between devices. This communication technology has the characteristics of wide network coverage and low terminal power consumption. It is more suitable for Large-scale IoT application deployment, specifically including NB-IoT, LoRa, Sigfox, and eMTC, among which NB-IoT and LoRa have been widely sought after in recent years.

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• Introduction to LoRa
  

• LoRa basic technical indicators

• Advantages of LoRa Technology

• Introduction to NB-IoT Introduction

• Technical Specifications of NB-IoT

• Examples of NB-IoT applications

• Introduction to Sigfox

• Technical Specifications of  Sigfox

• Examples of Sigfox applications

• Introduction to eMTC

• Technical Specifications of  eMTC

• Examples of eMTC applications

Introduction to LoRa

LoRa is a long-distance wireless transmission technology based on spread spectrum technology. In fact, it is also one of many LPWAN communication technologies. It was first adopted and promoted by the American Semtech company. This solution provides users with a simple wireless communication method that can realize long-distance and low power consumption. At present, LoRa mainly operates in the ISM frequency band, mainly including 433, 868, 915 MHz and so on. As a low-power wide-area network communication technology, LoRa wireless transmission technology has the advantages of stronger communication radio frequency distance and longer transmission distance under the same power consumption. The communication distance is 3-5 times that of traditional wireless technology.

Refer article here：LoRa Basics: Best Practices for LPWAN Technology Implementation

                                   LoRa technology: low power consumption, long distance, anti-interference

                                   LoRa gateway: an information bridge between a terminal and a server

Semtech has developed a complete set of LoRa communication chip solutions based on LoRa technology, including different types of LoRa chips for gateways and terminals. In order to promote other companies to participate in the LoRa ecology, in March 2015, Semtech joined forces with Actility, Cisco, IBM and other manufacturers to jointly initiate the establishment of the LoRa Alliance, and launched the constantly iterative LoRaWAN specification, which gave birth to a network consisting of nearly a thousand companies around the world. The wide-area networking standard system supported by manufacturers forms a broad industrial ecology.

There are two representative spread spectrum methods: direct sequence spread spectrum and frequency hopping spread spectrum. LoRa technology is a modulation method based on direct sequence spread spectrum. Direct Sequence Spread Spectrum (DSSS), referred to as Direct Spread (DS), is a widely used spread spectrum method.


1. LoRa basic technical indicators:

     Transmission distance: up to 2~5km in towns and up to 15km in suburbs.

     Working frequency: ISM frequency band includes 433MHz, 470MHz, 868MHz, 915MHz, etc.

     Standards: IEEE 802.15.4g, LoRaWAN.

E890-470LG12 Full Duplex LoRaWAN Gateway                    
      
[Chip scheme]：SX1302
[Working frequency band]：CN470
[Transmit power]：27dBm
[Communication distance]：3km
[Product weight]：417±5g
[Product size]：116*105*41mm
[Introduction]：Full Duplex LoRaWAN Gateway

Based on spread spectrum technology, a variant of CSS has forward error correction (Forward Error Correction, FEC) capability, which belongs to Semtech's private patented technology.

     Capacity: A LoRa gateway can connect thousands of LoRa nodes.

     Battery Life: Up to 10 years.

     Security: AES128 encryption.

     Transmission rate: 18b/s~ 62.5kb/s.

2. LoRa has the following advantages:

1. Low power consumption

LoRa applications are generally IoT devices, usually powered by batteries, and used for more than a few years, which requires LoRa to have extremely low power consumption. The realization of LoRa's low power consumption is mainly determined by two aspects: on the one hand, the chip needs to have low power consumption; on the other hand, the software communication protocol also needs to have low power consumption.

First of all, the power consumption of LoRa in hardware is very low. For example, the current of SX126X series hot start sleep mode is only 1.2uA, the receiving current at 125kHz is 4.6mA, and the sending current at 17dBm power is only 58mA.

Secondly, in terms of software communication protocols, LoRa does not have complex communication protocols like other wireless technologies. The data packets are very simple, and there is no need to send a large amount of handshake data. In order to achieve the purpose of saving power, the industry widely uses the Wake on Radio (WOR) method.

The chip enters the receiving (RX) mode periodically to listen for the wake-up preamble, and is in the sleep (Sleep) mode at other times. The receiving current of WOR is shown in the figure below. Most of the time it is in sleep mode, and only a small part of the time is woken up in receiving mode, so its overall power consumption is very low. For example, Ebyte's E22 and E32 modules all have WOR function, which can meet the low power consumption requirements very well.

2. Long distance

In wireless communication, the standard to measure the communication distance is the link budget, which is equal to the transmit power minus the sensitivity. Sensitivity is a negative number, and the higher the sensitivity, the more negative, so the way to improve the link budget is to increase the transmit power and improve the sensitivity. However, the transmission power has strict requirements in various countries and regions, so the only way to increase the communication distance is to increase the sensitivity. The LoRa sensitivity has reached -123dBm when BW=125kHz, SF=7; when BW=7.81kHz, SF=12, the sensitivity has reached -149.1dBm. The sensitivity of Bluetooth is around -90dbm, and ZigBee is around -85dBm, so the transmission distance of LoRa is much longer than that of other wireless communication technologies. However, LoRa uses bandwidth in exchange for sensitivity, which will result in a very slow transmission rate, so LoRa is suitable for long-distance, low-speed, and small-volume applications.

3. Anti-jamming

LoRa can achieve long-distance transmission. In addition to the advantage of sensitivity, another very important factor is its super anti-interference ability.

LoRa can still communicate when the noise is lower than 20dB, which is not available in existing traditional communication technologies.

LoRa can normally demodulate the signal 20dB below the noise, while FSK theoretically needs to be 8dB above the noise to ensure demodulation. When the communication process encounters external electromagnetic signal interference, LoRa can continue to communicate stably, while traditional wireless technologies cannot communicate. Therefore, in some areas with serious channel interference, customers will choose LoRa technology as the core technology for stable communication. The reason why LoRa modulation has such a strong anti-interference ability is mainly because Chirp debugging can gather useful LoRa signals under the noise during coherent demodulation, and the noise is still noise after coherent demodulation.

In 2022, more than 6.5 million LoRa-based gateways and more than 280 million LoRa-based terminal nodes have been deployed worldwide. There are more than 170 LoRaWAN public network operators and the number is still increasing. According to ABI Research, by 2026, LoRa will account for more than 50% of global non-cellular low-power wide-area network connections.

Introduction to NB-IoT Introduction

Narrowband Internet of Things (NB-IoT) is a Low Power Wide Area Network (LPWAN) radio technology standard developed to enable low power, wide area network communication for Internet of Things (IoT) devices. It is one of the three LPWAN technologies standardized by the 3rd Generation Partnership Project (3GPP) alongside LTE Cat M1 and EC-GSM-IoT.

NB-IoT is designed as a complement to existing LTE networks and is suitable for applications with low data rates and long battery life requirements such as asset tracking, smart metering, and sensor applications. It is optimized for use in licensed spectrum and is particularly suitable for operation in guard bands, in-band deployments and stand-alone deployments.

NB-IoT is based on the same core network as LTE and is fully backward compatible with existing LTE networks. It is optimized for low power, low cost, and low data rate applications.

Technical Specifications of NB-IoT

NB-IoT is optimized for low power, low cost, and low data rate applications. It operates on a single dedicated channel and uses Orthogonal Frequency Division Multiple Access (OFDMA) technology to maximize spectral efficiency.

NB-IoT is designed to use a maximum of 200 kHz of the spectrum, resulting in a maximum data rate of approximately 250 kbps. It is also designed for low-power operation, with a maximum transmit power of 23 dBm and an extended coverage range of up to 50 km.

NB-IoT also supports a variety of features, such as:

• Quality of Service (QoS) classifications
• Low latency
• Power saving modes
• Scheduling of communication
• Multiple access levels
• End-to-end encryption
• Secure access and authentication

Features of NB-IoT

NB-IoT is optimized for low power, low cost, and low data rate applications, making it ideal for IoT applications. It is designed to use a maximum of 200 kHz of the spectrum, resulting in a maximum data rate of approximately 250 kbps.

NB-IoT is also designed for low-power operation, with a maximum transmit power of 23 dBm and an extended coverage range of up to 50 km. Additionally, NB-IoT supports a variety of features, such as Quality of Service (QoS) classifications, low latency, power saving modes, scheduling of communication, multiple access levels, end-to-end encryption, and secure access and authentication.

NB-IoT is suitable for a variety of applications, including asset tracking, smart metering, and sensor applications. It is also suitable for in-building applications such as intelligent lighting and building automation.

NB-IoT is particularly well-suited for applications that require long battery life, such as medical monitoring and remote industrial sensors. It is also suitable for applications that require low data rates, such as environmental monitoring.

Examples of NB-IoT applications

• Smart metering: NB-IoT can be used to collect consumption data from smart meters in order to monitor and manage energy consumption more efficiently.

• Asset tracking: NB-IoT can be used to track the location and status of assets such as vehicles and cargo containers in real time.

• Automated parking: NB-IoT can be used to provide real-time information on the availability of parking spaces in order to optimize parking efficiency.

• Environmental monitoring: NB-IoT can be used to collect data from environmental sensors to monitor air quality, temperature, humidity, and other environmental factors.

Introduction to Sigfox

Sigfox is a Low Power Wide Area Network (LPWAN) radio technology standard developed to enable low power, wide area network communication for Internet of Things (IoT) devices. It is based on the ISM band and is one of the three LPWAN technologies standardized by the 3rd Generation Partnership Project (3GPP) alongside LTE Cat M1 and EC-GSM-IoT.

Sigfox is designed for applications with low data rates and long battery life requirements such as asset tracking, smart metering, and sensor applications. It is optimized for use in unlicensed spectrum and is particularly suitable for operation in urban environments.

Technical Specifications of Sigfox

Sigfox is optimized for low power, low cost, and low data rate applications. It operates on a single dedicated channel and uses Ultra Narrow Band (UNB) technology to maximize spectral efficiency.

Sigfox is designed to use a maximum of 100 kHz of the spectrum, resulting in a maximum data rate of approximately 100 bps. It is also designed for low-power operation, with a maximum transmit power of 14 dBm and an extended coverage range of up to 10 km.

Sigfox also supports a variety of features, such as:

• Quality of Service (QoS) classifications
• Low latency
• Power saving modes
• Scheduling of communication
• Multiple access levels
• End-to-end encryption
• Secure access and authentication

Features of Sigfox

Sigfox is optimized for low power, low cost, and low data rate applications, making it ideal for IoT applications. It is designed to use a maximum of 100 kHz of the spectrum, resulting in a maximum data rate of approximately 100 bps.

Sigfox is also designed for low-power operation, with a maximum transmit power of 14 dBm and an extended coverage range of up to 10 km. Additionally, Sigfox supports a variety of features, such as Quality of Service (QoS) classifications, low latency, power saving modes, scheduling of communication, multiple access levels, end-to-end encryption, and secure access and authentication.

Sigfox is suitable for a variety of applications, including asset tracking, smart metering, and sensor applications. It is also suitable for in-building applications such as intelligent lighting and building automation.

Sigfox is particularly well-suited for applications that require long battery life, such as medical monitoring and remote industrial sensors. It is also suitable for applications that require low data rates, such as environmental monitoring.

Examples of Sigfox applications

• Smart metering: Sigfox can be used to collect consumption data from smart meters in order to monitor and manage energy consumption more efficiently.

• Asset tracking: Sigfox can be used to track the location and status of assets such as vehicles and cargo containers in real time.

• Automated parking: Sigfox can be used to provide real-time information on the availability of parking spaces in order to optimize parking efficiency.

• Environmental monitoring: Sigfox can be used to collect data from environmental sensors to monitor air quality, temperature, humidity, and other environmental factors.

Introduction to eMTC

Enhanced Machine Type Communication (eMTC) is a Low Power Wide Area Network (LPWAN) radio technology standard developed to enable low power, wide area network communication for Internet of Things (IoT) devices. It is one of the three LPWAN technologies standardized by the 3rd Generation Partnership Project (3GPP) alongside LTE Cat M1 and EC-GSM-IoT.

eMTC is designed as an extension to existing LTE networks and is suitable for applications with low data rates and long battery life requirements such as asset tracking, smart metering, and sensor applications. It is optimized for use in licensed spectrum and is particularly suitable for operation in guard bands, in-band deployments and stand-alone deployments.

Technical Specifications of  eMTC

eMTC is optimized for low power, low cost, and low data rate applications. It operates on a single dedicated channel and uses Orthogonal Frequency Division Multiple Access (OFDMA) technology to maximize spectral efficiency.

eMTC is designed to use a maximum of 200 kHz of the spectrum, resulting in a maximum data rate of approximately 250 kbps. It is also designed for low-power operation, with a maximum transmit power of 23 dBm and an extended coverage range of up to 50 km.

eMTC also supports a variety of features, such as:

• Quality of Service (QoS) classifications
• Low latency
• Power saving modes
• Scheduling of communication
• Multiple access levels
• End-to-end encryption
• Secure access and authentication

Features of eMTC

eMTC  is optimized for low power, low cost, and low data rate applications, making it ideal for IoT applications. It is designed to use a maximum of 200 kHz of the spectrum, resulting in a maximum data rate of approximately 250 kbps.

eMTC is also designed for low-power operation, with a maximum transmit power of 23 dBm and an extended coverage range of up to 50 km. Additionally, eMTC supports a variety of features, such as Quality of Service (QoS) classifications, low latency, power saving modes, scheduling of communication, multiple access levels, end-to-end encryption, and secure access and authentication.

eMTC is suitable for a variety of applications, including asset tracking, smart metering, and sensor applications. It is also suitable for in-building applications such as intelligent lighting and building automation.

eMTC is particularly well-suited for applications that require long battery life, such as medical monitoring and remote industrial sensors. It is also suitable for applications that require low data rates, such as environmental monitoring.

Examples of eMTC applications

• Smart metering: eMTC can be used to collect consumption data from smart meters in order to monitor and manage energy consumption more efficiently.

• Asset tracking: eMTC can be used to track the location and status of assets such as vehicles and cargo containers in real time.

• Automated parking: eMTC can be used to provide real-time information on the availability of parking spaces in order to optimize parking efficiency.

• Environmental monitoring: eMTC can be used to collect data from environmental sensors to monitor air quality, temperature, humidity, and other environmental factors.