Yokohama and Santa Clara, Calif., – September 5, 2017 – ROHM Group company LAPIS Semiconductor has recently announced the availability of an RF LSI optimized for LPWA (Low Power Wide Area), which is expected to usher in a new area of wireless IoT communication.
The ML7404 is the first wireless communication LSI in the industry to feature LPWA dual-mode functionality, supporting both the Sigfox standard (subscription-based LPWA using unlicensed sub-GHz), which has been adoped in more than 30 countries and expanding in metropolitan areas including Japan, and the international protocol IEEE802.15.4K that is extremely robust against interference from the same system and has the capacity to cover more terminals under one network. This dual-mode capability enables use in a wide range of applications/specifications.
Communication modules containing this device will be released from partner companies to simplify the development of LPWA-compatible devices that contribute increased IoT adoption. In addition, the protocol stack for IEEE802.15.4k will be provided as open-source from our partner stack vendors.
In recent years, LPWA using the sub-GHz band (which is not subject to RF licensing) is attracting attention for IoT applications. However, because the specific communication protocol varies from one country/region to the next, as of yet no method has been standardized from among the diverse array of IoT networks currently in use.
LAPIS semiconductor has previously released wireless communication LSIs for sub-GHz specified low power radio base stations ahead of the competition, helping to achieve a smarter world through IoT. This time we developed an LPWA device that supports multiple methods, facilitating the early launch of IoT networks and the effective spread of applications and services.
1. Supports dual LPWA modes (Sigfox and IEEE802.15.4k)
The ML7404 is a dual-mode LPWA wireless communication LSI compatible with both IEEE802.15.4k and the Sigfox standard utilized predominately in Europe.
2. The industry's first hardware-based BPSK modulation circuit for Sigfox contributes to lower set power consumption
Sigfox uses the BPSK modulation method which is not employed by conventional sub-GHz communication. However, because standard Sigfox compliant LSIs do not support BPSK modulation, it is necessary to create BPSK symbol data utilizing control MCU software. Unfortunately, this requires that the control MCU be activated each time wireless communication is performed, resulting in unnecessary set power consumption. In contrast, the ML7404 integrates a BPSK modulation circuit that eliminates the need for the control MCU to operate (in the physical layer) during wireless communication, reducing system power consumption.
3. Development support
An optional evaluation kit bundles sample programs (simple MAC) and various test scenarios, with reference module designs currently being prepared. In addition, full support is offered, including manuals and tools that can be downloaded from LAPIS' website (registration required). And in the future, communication modules integrating the ML7404 along with low power protocol stacks for IEEE802.15.4k will be released from partner companies.
*May vary depending on reference values, communication conditions, and the ambient environment
Part No: ML7404
Sample Availability: Now
Mass Production: December 2017
Production Quantity: 100,000pcs./month
Packaging: T&R (1000pcs/reel)
Gas and water meters, sensor networks, building health monitoring, smart agriculture, security systems, and other industrial applications requiring long-distance wireless communication.
A long-range wireless protocol part of the IEEE family of standards. Sensitivity is improved using the direct sequence spread spectrum method (DSSS). The IEEE802 series standardizes physical layers such as wireless LAN, Bluetooth, ZigBee, and Wi-SUN.
DSSS (Direct Sequence Spread Spectrum)
A type of spread spectrum method that spreads and transmits baseband signals within a wider band. Pseudo noise is frequency diffused and de-spread during reception, providing greater resistance against interference.