Japan’s smart cities: advancements in sustainability and quality of life
Japan has emerged as a global leader in developing smart cities that integrate advanced technologies to enhance sustainability and improve the quality of urban life. By leveraging the Internet of Things (IoT) and other digital innovations, Japanese cities have achieved significant reductions in carbon emissions and have fostered more livable urban environments.
Energy management and CO₂ reduction
Japan has positioned itself as a global leader in developing smart cities that seamlessly integrate advanced technologies to enhance sustainability and improve urban living standards. By leveraging the Internet of Things (IoT) and other digital innovations, Japanese cities have achieved significant reductions in carbon emissions and fostered more livable urban environments.
Japan has made significant strides in energy management and CO₂ reduction through the implementation of smart city initiatives and technological innovations. A notable example is the Fujisawa Sustainable Smart Town (FSST) in Kanagawa Prefecture, which opened to residents in 2014. Developed by Panasonic, FSST focuses on five primary domains: energy, security, mobility, wellness, and community. The town has achieved a 70% reduction in CO₂ emissions, a 30% decrease in water consumption, and incorporates 30% renewable energy into its overall consumption. Additionally, FSST’s energy system is designed to store enough energy for up to three days in case of emergencies.
Fujisawa Sustainable Smart Town (FSST) in Japan
Another example is the city of Minamata in Kumamoto Prefecture, which has transformed into an Eco-Town. The city has implemented various environmental initiatives, including the development of a nature-oriented ecological town, preservation of natural environments, and utilization of new and natural energy sources such as wind and solar power. These efforts have contributed to carbon dioxide absorption and revitalization of marine plant life.
In Tokyo, efforts to realize a Zero‐Emission city include promoting the introduction of renewable energy from various angles, such as approaches to both the demand side (businesses and individuals) and the supply side (construction of renewable energy equipment). These initiatives aim to decarbonize energy consumption in the city. Tokyo has implemented effective strategies to enhance energy management and reduce CO₂ emissions. The Tokyo Cap-and-Trade Program (TCTP), initiated in 2010, achieved a 22% reduction in greenhouse gas emissions from baseline levels by the end of fiscal year 2012.
In fiscal year 2021, emissions from covered entities totaled 11.1 million tonnes, marking a 33% reduction below base-year emissions. Complementing the TCTP, the Carbon Reduction Reporting Program led to an average CO₂ emissions reduction of 13% and a 18% decrease in energy use among participating companies between 2010 and 2015. Additionally, the “Cool Biz” campaign, launched in 2005, encouraged higher office air conditioning settings and lighter attire, resulting in an estimated reduction of 460,000 tons of CO₂ emissions in its inaugural year. These initiatives collectively demonstrate Tokyo’s commitment to sustainable urban development and environmental stewardship.
Nationally, Japan has set ambitious targets to combat climate change. The government aims to reduce greenhouse gas emissions by 46% from 2013 levels by 2030 and achieve carbon neutrality by 2050. These goals are supported by strategies such as the Green Growth Strategy, which emphasizes innovation and the development of green technologies.
Piezoelectric energy to generate electricity
In its pursuit of sustainable energy solutions, Japan is pioneering the use of piezoelectric tiles that transform everyday foot traffic into small, yet cumulatively significant, amounts of renewable energy. These innovative tiles leverage the piezoelectric effect where materials like lead zirconate titanate (PZT) generate an electrical charge when mechanically stressed to harvest energy in high-traffic areas such as train stations and urban sidewalks.
When a person steps on a tile, the slight compression (around 5 mm) induces an electrical output that can momentarily reach between 12 to 30 V at currents of about 5 mA. Research shows that a single 30 × 30 cm tile can harvest approximately 511 millijoules of energy per step. Considering that an average person takes between 3,000 and 5,000 steps per day, even a modest installation can accumulate several kilojoules of energy daily.
Piezoelectric energy tile generating energy
Despite each footstep generating only milliwatts of power, the cumulative effect in densely populated urban settings is noteworthy. For example, a pilot installation at Tokyo Station covering 25 square meters of piezoelectric floor has been estimated to generate roughly 1,400 kWh of energy per day. In practical terms, this means that each pedestrian’s step might generate enough electricity to power an LED street lamp for about 30 seconds.
Modeling studies further indicate that if approximately 3.1% of a building’s floor area in high-footfall zones is paved with piezoelectric tiles, the system could harvest around 1.1 megawatt-hours annually meeting nearly 0.5% of that building’s energy needs. The overall conversion efficiency of these tiles typically ranges between 5% and 15%, reflecting the fraction of mechanical energy that is effectively transformed into electrical energy.
In continuous walking scenarios, some prototypes have demonstrated power outputs up to 0.57 watts, while carefully engineered series–parallel configurations help balance voltage and current to optimize energy extraction. Although the individual energy yield is modest compared to solar or wind power, the decentralized nature of piezoelectric energy harvesting makes it particularly attractive for supplementing urban power needs and reducing carbon footprints.
Looking ahead, as manufacturing scales up and production costs potentially decrease by 30–50% over the next few years, these tiles could become a more cost-effective option for powering low-consumption devices such as LED lighting, sensors, or digital signage—in busy public spaces. In Japan’s evolving smart cities, every step taken can contribute to a greener, more sustainable energy ecosystem.
Public safety and disaster management
Japan’s susceptibility to natural disasters, including earthquakes, tsunamis, and typhoons, has historically posed significant challenges to public safety and disaster management. Traditional methods, such as manual observations and community-based warning systems, often resulted in delayed responses, leading to increased casualties and property damage. In recent years, the integration of Internet of Things (IoT) technologies has markedly enhanced Japan’s disaster preparedness and response capabilities, yielding substantial improvements in mitigating the impacts of such events.
A notable advancement is the implementation of the J-Alert system, introduced in 2007. This satellite-based early warning system enables authorities to rapidly disseminate alerts regarding earthquakes, tsunamis, and other emergencies directly to citizens via loudspeakers, television, radio, email, and cell broadcasts. By March 2019, enhancements reduced the system’s information processing time from twenty seconds to approximately two seconds, significantly expediting evacuations and reducing potential casualties.
J-Alert system overwiew
Complementing J-Alert, Japan has invested in AI-driven platforms like Spectee Pro, launched in 2020. Developed by the Japanese startup Spectee Inc., this cloud-based crisis management service utilizes artificial intelligence to analyze diverse data sources including social media posts, meteorological measurements, river and road camera footage, and local vehicle data to provide real-time reports on disaster conditions and locations. Since its inception, Spectee Pro has secured over 1,100 contracts with local governments and businesses involved in disaster response and management, maintaining a near 100% retention rate. The system’s ability to swiftly process and disseminate accurate information has been instrumental in enhancing situational awareness and coordinating effective responses during disasters.
Spectee Pro overview of system
Financially, Japan’s commitment to disaster management is evident in its budget allocations. In the fiscal year 2022, the disaster management-related science and technology research budget amounted to approximately 24.81 billion Japanese yen. Although this budget was planned to decrease to about 7.43 billion yen in fiscal year 2023, the substantial investment underscores Japan’s dedication to advancing disaster resilience through technological innovation.
These technological advancements have significantly improved Japan’s disaster preparedness and response strategies. The rapid dissemination of information through systems like J-Alert has reduced evacuation times, while AI-driven platforms such as Spectee Pro have enhanced situational awareness, enabling authorities to allocate resources more effectively during emergencies. These improvements have collectively contributed to a decrease in casualties and property damage during natural disasters.
Waste management and environmental monitoring
Japan has long been recognized for its meticulous waste management practices and commitment to environmental sustainability. Historically, the nation implemented rigorous waste segregation policies and recycling programs, achieving a recycling rate of approximately 20% in the 1990s. However, as urban populations grew and waste generation increased, traditional methods faced challenges in maintaining efficiency and environmental sustainability. In response, Japanese cities have integrated Internet of Things (IoT) technologies into their waste management and environmental monitoring systems, leading to significant improvements.
The adoption of IoT-enabled smart waste management systems has revolutionized how Japanese cities handle waste collection and disposal. Smart bins equipped with sensors monitor waste levels in real-time, transmitting data to waste collection centers. This information allows for the optimization of collection routes and schedules, reducing fuel consumption and operational costs. For instance, a demonstration of a contactless waste collection system in Japan showed that the system could safely lift a 700-liter waste container containing 212 kilograms of waste to the collection truck without human contact, enhancing both efficiency and safety.
Explanation and demonstration of a contactless waste collection system in Japan
Public perception studies have also highlighted the potential of smart bins to support Pay-As-You-Throw (PAYT) schemes, encouraging waste reduction and increased recycling. A survey of 1,000 Japanese individuals revealed a positive attitude towards smart bin features, indicating their potential to promote sustainable waste management practices.
Beyond waste management, IoT technologies have significantly improved environmental monitoring in Japanese cities. Sensors deployed throughout urban areas collect real-time data on air and water quality, noise levels, and other environmental parameters. This data-driven approach enables authorities to promptly address pollution incidents, enforce environmental regulations, and develop policies aimed at improving public health and urban livability. The environmental monitoring market in Japan was valued at USD 920.4 million in 2024, reflecting the country’s investment in this sector.
Kamikatsu Zero-Waste Center in Japan
An exemplary model of Japan’s commitment to waste management is the Kamikatsu Zero-Waste Center. Located in Tokushima Prefecture, this facility recycles over 80% of the waste produced in Kamikatsu, significantly higher than the national average of 20%. The center serves as a learning hub, promoting sustainable practices and aiming for a fully zero-waste community.
The integration of IoT in Japan’s smart cities has led to notable improvements: Operational efficiency has been enhanced through the optimization of waste collection routes and schedules, leading to reduced fuel consumption and operational costs. Public engagement has increased, with surveys indicating that smart waste management systems have the potential to encourage waste reduction and increased recycling among citizens. Environmental quality has improved, as real-time environmental monitoring enables prompt responses to pollution incidents, contributing to better air and water quality in urban areas.
Devices for measuring energy collection and data visualization
Smart meters
Japan’s commitment to sustainability within its smart cities is exemplified by the deployment of advanced devices and systems designed for precise energy measurement and data visualization. A cornerstone of Japan’s energy management strategy is the widespread implementation of smart meters. These IoT-enabled devices enable two-way communication between consumers and utility providers, offering real-time data on electricity usage. By 2024, Japan had installed approximately 80 million smart meters nationwide, achieving near-total coverage of households and businesses.
This extensive deployment has contributed to a 10% reduction in peak electricity demand, bolstering grid stability and promoting energy conservation. For instance, smart meters manufactured by industry leaders such as Hitachi and Toshiba have been widely implemented across residential and commercial areas. One notable example is the Hitachi Smart Meter Model HSM-200, which offers an accuracy of ±0.5% and supports two-way communication, allowing for remote readings and dynamic energy management.
Hitachi Smart Meter Model HSM-200
IoT sensors for environmental monitoring
Beyond energy consumption, IoT sensors play a pivotal role in monitoring environmental parameters such as air quality, temperature, and humidity. In Tokyo, a network of over 5,000 environmental sensors has been established across the city, providing real-time data that informs policies on pollution control and public health. A widely used sensor in many Japanese smart city projects is the Bosch BME280, renowned for its precision in measuring temperature, humidity, and barometric pressure. Despite being a globally recognized component, the BME280 is pivotal in Japan’s urban networks, where these sensors provide continuous real-time data that has been correlated with a 15% improvement in air quality indices over the past five years.
Additionally, in commercial buildings, Fujitsu’s IoT Energy Monitor Model FEM-500 has been implemented to provide granular insights into energy consumption patterns, enabling facility managers to identify inefficiencies and reduce energy usage by up to 20%. Moreover, Japan’s approach to water quality management has been bolstered by advanced multiparameter sensors such as the YSI EXO2 sonde, which measures critical parameters like dissolved oxygen, pH, and conductivity, ensuring that urban water quality remains within safe limits. The data provided by these sensors has allowed municipal authorities to act swiftly during pollution incidents, thereby maintaining public health standards.
YSI EXO2 sonde ensuring that urban water quality remains within safe limits
Data visualization tools
Transforming raw data into actionable insights requires robust data visualization tools, and Japanese cities employ platforms like Tableau as well as custom-developed dashboards to interpret complex datasets. For instance, the Yokohama Smart City Project utilizes a centralized dashboard that integrates data from various IoT devices including smart meters, environmental sensors like the Bosch BME280, and energy monitors from Fujitsu to enable city officials to monitor energy consumption patterns, detect inefficiencies, and implement targeted interventions. This approach has resulted in a 7% decrease in municipal energy expenditures since its inception, reflecting the tangible benefits of real-time data analytics.
Bosch BME280 humidity sensor
Real-life applications and Impact
Real-life applications further underscore the impact of these technologies. In Kyoto, the implementation of smart lighting systems equipped with motion sensors, such as Omron’s E3X-DF1 series, has led to a 40% reduction in streetlight energy consumption by automatically adjusting lighting levels based on pedestrian presence. Similarly, in Osaka, the integration of Building Energy Management Systems (BEMS) in commercial complexes has achieved energy savings of up to 20%, showcasing the efficacy of IoT solutions in reducing urban energy footprints. These innovations not only result in energy savings but also contribute to improved environmental quality and enhanced public health by enabling precise control over urban infrastructure.
Spain’s smart city transformation: embracing japanese Innovations with Cloud Studio IoT
Spain is uniquely positioned to revolutionize its urban energy landscape by integrating innovative technologies inspired by Japan’s smart city initiatives, including piezoelectric tile energy harvesting and IoT-based solutions powered by platforms like Cloud Studio IoT. These approaches offer transformative potential to reduce energy consumption, lower CO₂ emissions, and enhance urban sustainability and quality of life, addressing Spain’s pressing challenges of high energy demand, increasing pollution, and inefficient resource management.
Japan has pioneered the use of piezoelectric tiles in high-traffic areas such as Shibuya and Narita train stations, harnessing the piezoelectric effect to convert mechanical pressure from foot traffic into electricity. Materials like barium titanate, zinc oxide, and quartz generate small electrical outputs from each step, which cumulatively power LED displays, emergency lighting, and low-power sensors. While a single step generates only a few joules of energy, environments with heavy pedestrian traffic can accumulate significant outputs. For example, a piezoelectric system capturing 1.5 joules per step in an area with 100,000 daily steps would yield approximately 150,000 joules (42 watt-hours) per day. Scaling this technology across multiple platforms could produce several kilowatt-hours daily, contributing meaningfully to renewable energy sources. If Spanish cities like Madrid or Barcelona integrate piezoelectric tiles into major transit hubs such as Atocha Station or Sants Station, they could harness the kinetic energy of millions of commuters to supplement their renewable energy mix.
Atocha train station – the biggest train station in Spain
At the same time, Spain can leverage Cloud Studio IoT’s advanced platform to modernize its urban infrastructure by replicating Japan’s successes in IoT-driven smart city solutions. Japan’s deployment of approximately 80 million smart meters has led to a 10% reduction in peak electricity demand. For Spain, which consumes around 250 terawatt-hours (TWh) annually, achieving similar results would save roughly 25 TWh per year equivalent to the annual electricity consumption of over 6 million households and reduce CO₂ emissions by nearly 5 million tonnes annually (based on an emission factor of 200 grams per kilowatt-hour). Cloud Studio IoT enables Spanish municipalities to connect and manage diverse IoT devices such as smart meters, environmental sensors, energy monitors, and water quality sondes through a centralized platform. This integration allows for real-time data collection and advanced analytics that optimize grid performance, detect inefficiencies, and support data-driven decision-making.
For example, centralized dashboards modeled after Yokohama’s Smart City Project in Japan have contributed to a 7% reduction in municipal energy expenditures. In Madrid alone where annual municipal energy costs amount to €100 million such an approach could save approximately €7 million per year. Additionally, deploying environmental sensors similar to Tokyo’s network of over 5,000 Bosch BME280 units which have improved air quality indices by 15% over five years could help Spanish cities monitor pollutants like PM2.5 and NO₂ alongside temperature and humidity levels in real time. These capabilities would not only yield significant public health benefits but also lower healthcare costs associated with pollution-related illnesses.
Yokohama’s Smart City Project in Japan
The integration of piezoelectric tiles alongside IoT-enabled solutions creates a synergistic effect that enhances urban sustainability. While piezoelectric tiles capture otherwise wasted human kinetic energy in busy public spaces like train stations or pedestrian zones, IoT platforms such as Cloud Studio IoT centralize data from multiple renewable sources into one unified system. For instance, if Spanish cities install piezoelectric tiles across 10 major stations and each station generates an additional 5 kWh per day, this would result in an annual output of approximately 18,250 kWh per station. Although modest compared to total energy usage, these contributions combined with savings from smart meter deployments would significantly reduce overall energy demand and greenhouse gas emissions.
Implementing these technologies in Spain would begin with pilot projects in high-density urban areas such as Madrid’s Atocha Station or Barcelona Sants Station. Feasibility studies would assess factors like material durability in Mediterranean climates and the efficiency of energy conversion from pedestrian movement. Partnerships with leading technology providers could support these efforts; for example, using the Hitachi Smart Meter Model HSM-200 for its ±0.5% accuracy and robust two-way communication would facilitate nationwide smart meter rollouts. Similarly, multiparameter devices like the Hach HQ40d sonde for water quality monitoring could be integrated alongside piezoelectric tiles into existing urban infrastructures.
Hach HQ40d monitoring parameters like dissolved oxygen, pH, and conductivity
Cost considerations remain important for technologies like piezoelectric tiles due to high initial setup expenses and ongoing maintenance requirements. However, as economies of scale are achieved and material costs decrease over time, these systems will become more economically viable for widespread adoption. Cloud Studio IoT further reduces implementation barriers by offering a no-code architecture that simplifies deployment processes while ensuring compatibility with diverse hardware systems across verticals such as public lighting, smart buildings, environmental monitoring, and mobility management.
In our ever-evolving urban landscapes, Japan is leading the way in smart city innovations, harnessing IoT and sustainable technologies to transform energy management, public safety, and environmental monitoring. Discover how these advancements are shaping smarter, greener cities worldwide.
Frequently Asked Questions
What are Japan’s smart cities?
Japan’s smart cities integrate advanced IoT and digital innovations to enhance sustainability and quality of urban life, achieving significant reductions in carbon emissions and improved livability, as seen in projects like the Fujisawa Sustainable Smart Town.
How has Japan advanced energy management and CO₂ reduction?
Japan has made remarkable progress through initiatives such as the Fujisawa Sustainable Smart Town, Minamata Eco-Town, and Tokyo’s Cap-and-Trade Program, which have led to notable reductions in CO₂ emissions, water usage, and overall energy consumption while integrating renewable energy sources.
What role do piezoelectric tiles play in Japan’s smart city initiatives?
Piezoelectric tiles convert the mechanical pressure from pedestrian foot traffic into renewable energy. Installed in high-traffic areas like train stations, they capture kinetic energy that can power low-consumption devices, contributing to Japan’s sustainable energy ecosystem.
How is public safety and disaster management enhanced in Japan’s smart cities?
Japan employs advanced systems such as the J-Alert early warning system and AI-driven platforms like Spectee Pro to rapidly disseminate emergency alerts and analyze real-time data, significantly reducing evacuation times and improving disaster response efficiency.
How has IoT improved waste management and environmental monitoring?
IoT-enabled solutions, including smart bins and environmental sensors, optimize waste collection routes, monitor pollution levels, and gather real-time data on air and water quality, thereby enhancing both operational efficiency and urban livability.
What devices are used for energy measurement and data visualization?
Devices such as smart meters (e.g., Hitachi Smart Meter Model HSM-200), environmental sensors (e.g., Bosch BME280), and advanced dashboards for data visualization enable precise energy monitoring and real-time insights, leading to more efficient urban management.
How can these smart city technologies benefit other urban environments?
By adopting these innovations, cities worldwide can reduce energy consumption, lower CO₂ emissions, and enhance urban quality of life. For instance, integrating smart meters, environmental sensors, and piezoelectric energy harvesting through platforms like Cloud Studio IoT can modernize infrastructure and drive sustainable development in other urban areas.
