2032 年能源采集制服市场预测：按制服类型、产量、材料、能源来源、分销管道和地区进行的全球分析

根据 Stratistics MRC 的数据，全球能源采集制服市场预计在 2025 年达到 668 亿美元，到 2032 年将达到 2,423 亿美元，预测期内的复合年增长率为 20.2%。

能源采集制服是一种先进的服装，它采用智慧纺织品，能够捕捉环境能量（例如身体运动、热、光和摩擦），并将其转化为可用的电能。这些面料整合了压电、热电和光伏系统等技术，能够在保持灵活性、耐用性和舒适性的同时产生能量。它们专为持续穿着而设计，可为感测器、通讯工具和健康监测器等低能耗设备供电，是军事、医疗保健和工业应用的理想选择。透过融合功能性和永续性，能源采集制服实现了自供电，减少了对外部电池的依赖，代表了穿戴式科技和自主系统的革命性飞跃。

自供电穿戴装置的需求不断增长

自供电穿戴装置需求的激增是能源采集制服的主要成长动力。随着各行各业对行动性、自主性和即时数据采集的重视，这些服装无需外部电池即可为内建感测器和通讯设备供电，从而提供了一种无缝解决方案。军事、医疗保健和工业领域越来越多地采用此类穿戴式装置来提高营运效率、安全性和监控能力。这一趋势反映了一种更广泛的趋势，即向整合智慧纺织品转变，这种纺织品将能源独立性与高衝击环境下的功能性相结合。

生产和零件成本高

高昂的生产和零件成本是市场成长的一大限制因素。先进的材料、嵌入式感测器和整合能量收集技术推高了製造成本，使得这些制服的价格远高于传统替代品。这一成本壁垒限制了製服的大规模采用，尤其是在成本敏感的行业和地区。此外，研发和製造的复杂性降低了可扩展性，减缓了商业化进程，并阻碍了潜在买家，从而限制了该技术儘管前景光明，但市场扩张却受到了限制。

永续性和能源效率趋势

全球对永续性和能源效率的重视为能源采集制服带来了诱人的商机。这些服装符合循环经济原则，减少对一次性电池的依赖，并能够在低负载下持续能源产出。随着ESG指令和绿色采购政策的日益普及，各行各业将更有奖励采用环保创新。智慧纺织品与可再生能源系统的融合，使能源采集制服成为气候适应型营运的创新解决方案，尤其是在优先考虑碳中和和资源优化的行业。

技术耐久性和耐洗性问题

技术耐用性和可洗性的限制严重阻碍了能源采集制服的普及，尤其是在国防、医疗保健和工业工作服等高磨损领域。频繁清洗劣化内建电子设备的效能，进而影响其性能和使用寿命。这些可靠性问题会削弱买家信心，延长采购週期，并增加维修成本。如果没有坚固耐用、可清洗的集成，市场可扩展性仍然有限，从而阻碍了其商业化，并阻碍了寻求高弹性、低维护的可穿戴能源解决方案的关键行业之间建立战略伙伴关係。

COVID-19的影响

新冠疫情最初扰乱了供应链，并减缓了能源采集制服市场的研发。然而，它加速了对自主、卫生和非接触式穿戴式科技的需求，尤其是在医疗保健和国防领域。这场危机凸显了对自供电系统的需求，以减少对外部基础设施的依赖。疫情后的復苏重新点燃了创新之火，导致对智慧纺织品的投资增加，这些纺织品支持关键产业的韧性和节能运作。

压电材料领域预计将成为预测期内最大的领域

压电材料领域预计将在预测期内占据最大的市场份额，这得益于其卓越的能量转换效率和对动态环境的适应性。这些材料利用身体运动和振动等机械应力发电，非常适合在活跃环境中持续穿戴。它们与柔性纺织品集成，可实现无缝发电，同时不影响舒适度或移动性。随着国防和工业领域对自供电系统的需求不断增长，压电纺织品为下一代穿戴式电子产品提供了可扩展的高性能解决方案。

预计预测期内动能部分将以最高的复合年增长率成长。

受基于运动的能源采集技术进步的推动，动能领域预计将在预测期内实现最高成长率。随着穿戴式装置在现役军人、运动员和产业工人中的应用不断扩展，将运动转化为电能的服装将具有战略意义。柔性压电和摩擦电系统的创新增强了透过行走、弯曲和伸展进行能量捕获的能力。该领域将受益于人们对在离网环境下运作的自主穿戴装置日益增长的兴趣，这些装置能够提供强大的、用户主导的能源产出，同时最大限度地减少对基础设施的依赖。

占比最大的地区：

在预测期内，亚太地区预计将占据最大的市场份额，这得益于其强大的製造能力、不断增长的国防预算以及医疗保健和工业领域对智慧纺织品的日益普及。中国、日本和韩国等国家在材料创新和穿戴式技术整合方面处于领先地位。政府推出的支持永续技术和数位转型的优惠倡议将进一步推动该地区的成长。纺织和电子产品领域主要参与者的存在，加上具有成本效益的生产生态系统，使亚太地区成为市场扩张的主导力量。

复合年增长率最高的地区：

预计北美地区在预测期内将呈现最高的复合年增长率，这得益于强劲的研发投入、先进可穿戴设备的早期应用以及对节能创新的有力监管支持。美国军方和医疗保健部门是该技术的主要应用者，他们将能源采集制服应用于关键任务和病患监测。科技公司、大学和国防机构之间的战略合作正在推动快速的技术创新。此外，消费者意识和永续性要求正在推动对智慧服饰的需求，使北美成为可扩展、高成长部署的热点。

免费客製化服务：

此报告的订阅者可以使用以下免费自订选项之一：

• 公司简介
  • 对最多三家其他市场公司进行全面分析
  • 主要企业的SWOT分析（最多3家公司）
• 区域细分
  • 根据客户兴趣对主要国家进行的市场估计、预测和复合年增长率（註：基于可行性检查）
• 竞争基准化分析
  • 根据产品系列、地理分布和策略联盟对主要企业基准化分析

目录

第一章执行摘要

第二章 前言

• 概述
• 相关利益者
• 调查范围
• 调查方法
  • 资料探勘
  • 数据分析
  • 数据检验
  • 研究途径
• 研究材料
  • 主要研究资料
  • 次级研究资讯来源
  • 先决条件

第三章市场走势分析

• 驱动程式
• 抑制因素
• 机会
• 威胁
• 新兴市场
• COVID-19的影响

第四章 波特五力分析

• 供应商的议价能力
• 买方的议价能力
• 替代品的威胁
• 新进入者的威胁
• 竞争对手之间的竞争

5. 全球能源采集制服市场（依制服类型）

• 军事和国防制服
• 工业和工作制服
• 医护制服
• 运动与健身服装
• 其他制服类型

6. 全球能源采集制服市场（按产量）

• 低功率（最大 10 mW）
• 中功率（10-100 mW）
• 高功率（超过 100 mW）

7. 全球能源采集制服市场（按材料）

• 智慧纺织品
• 奈米材料
• 压电材料
• 热电材料
• 其他成分

8. 全球能源采集制服市场（依能源来源）

• 太阳能
• 动能
• 热能
• 射频（RF）能量
• 混合酱

9. 全球能源采集制服市场（按分销管道）

• 直销
• 经销商
• 网路零售
• 其他分销管道

第 10 章全球能源采集制服市场（按地区）

• 北美洲
  • 美国
  • 加拿大
  • 墨西哥
• 欧洲
  • 德国
  • 英国
  • 义大利
  • 法国
  • 西班牙
  • 其他欧洲国家
• 亚太地区
  • 日本
  • 中国
  • 印度
  • 澳洲
  • 纽西兰
  • 韩国
  • 其他亚太地区
• 南美洲
  • 阿根廷
  • 巴西
  • 智利
  • 其他南美
• 中东和非洲
  • 沙乌地阿拉伯
  • 阿拉伯聯合大公国
  • 卡达
  • 南非
  • 其他中东和非洲地区

第十一章 重大进展

• 协议、伙伴关係、合作和合资企业
• 收购与合併
• 新产品发布
• 业务扩展
• 其他关键策略

第十二章 公司概况

• AiQ Smart Clothing Inc.
• Sensoria Inc.
• Hexoskin（Carre Technologies Inc.）
• Xenoma Inc.
• Schoeller Textil AG
• Outlast Technologies LLC
• Arkema（Piezotech）
• PowerFilm Solar Inc.
• Enfucell Oy
• Printed Energy Pty Ltd
• Pavegen Systems Ltd.
• Teijin（Teijin Frontier）
• STMicroelectronics
• Analog Devices, Inc.
• Wearable X

According to Stratistics MRC, the Global Energy-Harvesting Uniforms Market is accounted for $66.8 billion in 2025 and is expected to reach $242.3 billion by 2032 growing at a CAGR of 20.2% during the forecast period. Energy-harvesting uniforms are advanced garments embedded with smart textiles that capture and convert ambient energy-such as body movement, heat, light, or friction-into usable electrical power. These fabrics integrate technologies like piezoelectric, thermoelectric, and photovoltaic systems to generate energy while maintaining flexibility, durability, and comfort. Designed for continuous wear, they power low-energy devices such as sensors, communication tools, or health monitors, making them ideal for military, healthcare, and industrial applications. By merging functionality with sustainability, energy-harvesting uniforms enable self-powered operations, reduce dependency on external batteries, and represent a transformative leap in wearable technology and autonomous systems.

Market Dynamics:

Driver:

Rising demand for self-powered wearables

The surge in demand for self-powered wearables is a key growth driver for energy-harvesting uniforms. As industries prioritize mobility, autonomy, and real-time data capture, these garments offer a seamless solution by powering embedded sensors and communication devices without external batteries. Military, healthcare, and industrial sectors increasingly adopt such wearables to enhance operational efficiency, safety, and monitoring. This trend reflects a broader shift toward integrated smart textiles that combine energy independence with functional utility across high-impact environments.

Restraint:

High production & component cost

High production and component costs significantly hinder the growth of the market. Advanced materials, embedded sensors, and integrated energy-harvesting technologies drive up manufacturing expenses, making these uniforms far more expensive than conventional alternatives. This cost barrier limits mass adoption, particularly in cost-sensitive industries and regions. Additionally, high R&D and production complexities reduce scalability, slowing commercialization and discouraging potential buyers, thus restraining market expansion despite technological promise.

Opportunity:

Sustainability and energy-efficiency trends

Global emphasis on sustainability and energy efficiency presents a compelling opportunity for energy-harvesting uniforms. These garments align with circular economy principles by reducing reliance on disposable batteries and enabling low-impact, continuous energy generation. As ESG mandates and green procurement policies gain traction, industries are incentivized to adopt eco-conscious innovations. The convergence of smart textiles and renewable energy systems positions energy-harvesting uniforms as a transformative solution for climate-resilient operations, especially in sectors prioritizing carbon neutrality and resource optimization.

Threat:

Technical durability and washability challenges

Technical durability and washability limitations significantly hinder adoption of energy-harvesting uniforms, especially in high-wear sectors like defense, healthcare, and industrial workwear. Frequent laundering degrades embedded electronics, compromising performance and lifespan. These reliability concerns erode buyer confidence, delay procurement cycles, and inflate maintenance costs. Without robust, washable integration, market scalability remains constrained, stalling commercialization and deterring strategic partnerships across key verticals seeking resilient, low-maintenance wearable energy solutions.

Covid-19 Impact

The COVID-19 pandemic initially disrupted supply chains and delayed R&D in the energy-harvesting uniforms market. However, it also accelerated demand for autonomous, hygienic, and contactless wearable technologies, especially in healthcare and defense. The crisis underscored the need for self-powered systems that reduce dependency on external infrastructure. Post-pandemic recovery has reignited innovation, with increased investments in smart textiles that support resilient, energy-efficient operations across critical sectors.

The piezoelectric materials segment is expected to be the largest during the forecast period

The piezoelectric materials segment is expected to account for the largest market share during the forecast period, due to its superior energy conversion efficiency and adaptability to dynamic environments. These materials generate electricity from mechanical stress-such as body movement or vibrations-making them ideal for continuous wear in active settings. Their integration into flexible textiles enables seamless power generation without compromising comfort or mobility. With rising demand from defense and industrial sectors for self-powered systems, piezoelectric fabrics offer a scalable, high-performance solution for next-generation wearable electronics.

The kinetic energy segment is expected to have the highest CAGR during the forecast period

Over the forecast period, the kinetic energy segment is predicted to witness the highest growth rate, due to advancements in motion-based energy harvesting technologies. As wearable applications expand across active-duty personnel, athletes, and industrial workers, garments that convert motion into power gain strategic relevance. Innovations in flexible piezoelectric and triboelectric systems enhance energy capture from walking, bending, or stretching. This segment benefits from growing interest in autonomous wearables that operate in off-grid environments, offering robust, user-driven energy generation with minimal infrastructure dependency.

Region with largest share:

During the forecast period, the Asia Pacific region is expected to hold the largest market share due to strong manufacturing capabilities, rising defense budgets, and growing adoption of smart textiles in healthcare and industrial sectors. Countries like China, Japan, and South Korea lead in material innovation and wearable tech integration. Favorable government initiatives supporting sustainable technologies and digital transformation further accelerate regional growth. The presence of key textile and electronics players, coupled with cost-effective production ecosystems, positions APAC as a dominant force in market expansion.

Region with highest CAGR:

Over the forecast period, the North America region is anticipated to exhibit the highest CAGR, owing to robust R&D investments, early adoption of advanced wearables, and strong regulatory support for energy-efficient innovations. The U.S. military and healthcare sectors are key adopters, leveraging energy-harvesting uniforms for mission-critical and patient-monitoring applications. Strategic collaborations between tech firms, universities, and defense agencies foster rapid innovation. Additionally, consumer awareness and sustainability mandates propel demand for smart garments, making North America a hotbed for scalable, high-growth deployment.

Key players in the market

Some of the key players profiled in the Energy-Harvesting Uniforms Market include AiQ Smart Clothing Inc., Sensoria Inc., Hexoskin (Carre Technologies Inc.), Xenoma Inc., Schoeller Textil AG, Outlast Technologies LLC, Arkema (Piezotech), PowerFilm Solar Inc., Enfucell Oy, Printed Energy Pty Ltd, Pavegen Systems Ltd., Teijin (Teijin Frontier), STMicroelectronics, Analog Devices, Inc. and Wearable X.

Key Developments:

In November 2024, Sensoria Health Inc., alongside AlexiGen, Defender, and Anderson Medical Supplies, unveiled a groundbreaking collaboration at the DFCon Conference Symposium in Los Angeles. Their mission: to launch "Footwear as a Service" (FAAS), an AI-powered remote patient-monitoring platform aiming to reduce amputations in diabetic foot ulcer (DFU) patients.

In August 2023, Hexoskin teamed up with Halo Health to address challenges in running clinical trials. The collaboration integrated Hexoskin's wearable biosensor garments with Halo's remote monitoring platform to improve operational efficiency and patient engagement in virtual trials.

Uniform Types Covered:

• Military & Defense Uniforms
• Industrial & Worker Uniforms
• Healthcare Uniforms
• Sports & Fitness Apparel
• Other Uniform Types

Power Outputs Covered:

• Low Power (<10 mW)
• Medium Power (10-100 mW)
• High Power (>100 mW)

Materials Covered:

• Smart Textiles
• Nanomaterials
• Piezoelectric Materials
• Thermoelectric Materials
• Other Materials

Energy Sources Covered:

• Solar Energy
• Kinetic Energy
• Thermal Energy
• Radiofrequency (RF) Energy
• Hybrid Sources

Distribution Channels Covered:

• Direct Sales
• Distributors
• Online Retail
• Other Distribution Channels

Regions Covered:

• North America
  • US
  • Canada
  • Mexico
• Europe
  • Germany
  • UK
  • Italy
  • France
  • Spain
  • Rest of Europe
• Asia Pacific
  • Japan
  • China
  • India
  • Australia
  • New Zealand
  • South Korea
  • Rest of Asia Pacific
• South America
  • Argentina
  • Brazil
  • Chile
  • Rest of South America
• Middle East & Africa
  • Saudi Arabia
  • UAE
  • Qatar
  • South Africa
  • Rest of Middle East & Africa

What our report offers:

• Market share assessments for the regional and country-level segments
• Strategic recommendations for the new entrants
• Covers Market data for the years 2024, 2025, 2026, 2028, and 2032
• Market Trends (Drivers, Constraints, Opportunities, Threats, Challenges, Investment Opportunities, and recommendations)
• Strategic recommendations in key business segments based on the market estimations
• Competitive landscaping mapping the key common trends
• Company profiling with detailed strategies, financials, and recent developments
• Supply chain trends mapping the latest technological advancements

Free Customization Offerings:

All the customers of this report will be entitled to receive one of the following free customization options:

• Company Profiling
  • Comprehensive profiling of additional market players (up to 3)
  • SWOT Analysis of key players (up to 3)
• Regional Segmentation
  • Market estimations, Forecasts and CAGR of any prominent country as per the client's interest (Note: Depends on feasibility check)
• Competitive Benchmarking
  • Benchmarking of key players based on product portfolio, geographical presence, and strategic alliances

Table of Contents

1 Executive Summary

2 Preface

• 2.1 Abstract
• 2.2 Stake Holders
• 2.3 Research Scope
• 2.4 Research Methodology
  • 2.4.1 Data Mining
  • 2.4.2 Data Analysis
  • 2.4.3 Data Validation
  • 2.4.4 Research Approach
• 2.5 Research Sources
  • 2.5.1 Primary Research Sources
  • 2.5.2 Secondary Research Sources
  • 2.5.3 Assumptions

3 Market Trend Analysis

• 3.1 Introduction
• 3.2 Drivers
• 3.3 Restraints
• 3.4 Opportunities
• 3.5 Threats
• 3.6 Emerging Markets
• 3.7 Impact of Covid-19

4 Porters Five Force Analysis

• 4.1 Bargaining power of suppliers
• 4.2 Bargaining power of buyers
• 4.3 Threat of substitutes
• 4.4 Threat of new entrants
• 4.5 Competitive rivalry

5 Global Energy-Harvesting Uniforms Market, By Uniform Type

• 5.1 Introduction
• 5.2 Military & Defense Uniforms
• 5.3 Industrial & Worker Uniforms
• 5.4 Healthcare Uniforms
• 5.5 Sports & Fitness Apparel
• 5.6 Other Uniform Types

6 Global Energy-Harvesting Uniforms Market, By Power Output

• 6.1 Introduction
• 6.2 Low Power (<10 mW)
• 6.3 Medium Power (10-100 mW)
• 6.4 High Power (>100 mW)

7 Global Energy-Harvesting Uniforms Market, By Material

• 7.1 Introduction
• 7.2 Smart Textiles
• 7.3 Nanomaterials
• 7.4 Piezoelectric Materials
• 7.5 Thermoelectric Materials
• 7.6 Other Materials

8 Global Energy-Harvesting Uniforms Market, By Energy Source

• 8.1 Introduction
• 8.2 Solar Energy
• 8.3 Kinetic Energy
• 8.4 Thermal Energy
• 8.5 Radiofrequency (RF) Energy
• 8.6 Hybrid Sources

9 Global Energy-Harvesting Uniforms Market, By Distribution Channel

• 9.1 Introduction
• 9.2 Direct Sales
• 9.3 Distributors
• 9.4 Online Retail
• 9.5 Other Distribution Channels

10 Global Energy-Harvesting Uniforms Market, By Geography

• 10.1 Introduction
• 10.2 North America
  • 10.2.1 US
  • 10.2.2 Canada
  • 10.2.3 Mexico
• 10.3 Europe
  • 10.3.1 Germany
  • 10.3.2 UK
  • 10.3.3 Italy
  • 10.3.4 France
  • 10.3.5 Spain
  • 10.3.6 Rest of Europe
• 10.4 Asia Pacific
  • 10.4.1 Japan
  • 10.4.2 China
  • 10.4.3 India
  • 10.4.4 Australia
  • 10.4.5 New Zealand
  • 10.4.6 South Korea
  • 10.4.7 Rest of Asia Pacific
• 10.5 South America
  • 10.5.1 Argentina
  • 10.5.2 Brazil
  • 10.5.3 Chile
  • 10.5.4 Rest of South America
• 10.6 Middle East & Africa
  • 10.6.1 Saudi Arabia
  • 10.6.2 UAE
  • 10.6.3 Qatar
  • 10.6.4 South Africa
  • 10.6.5 Rest of Middle East & Africa

11 Key Developments

• 11.1 Agreements, Partnerships, Collaborations and Joint Ventures
• 11.2 Acquisitions & Mergers
• 11.3 New Product Launch
• 11.4 Expansions
• 11.5 Other Key Strategies

12 Company Profiling

• 12.1 AiQ Smart Clothing Inc.
• 12.2 Sensoria Inc.
• 12.3 Hexoskin (Carre Technologies Inc.)
• 12.4 Xenoma Inc.
• 12.5 Schoeller Textil AG
• 12.6 Outlast Technologies LLC
• 12.7 Arkema (Piezotech)
• 12.8 PowerFilm Solar Inc.
• 12.9 Enfucell Oy
• 12.10 Printed Energy Pty Ltd
• 12.11 Pavegen Systems Ltd.
• 12.12 Teijin (Teijin Frontier)
• 12.13 STMicroelectronics
• 12.14 Analog Devices, Inc.
• 12.15 Wearable X

List of Tables

• Table 1 Global Energy-Harvesting Uniforms Market Outlook, By Region (2024-2032) ($MN)
• Table 2 Global Energy-Harvesting Uniforms Market Outlook, By Uniform Type (2024-2032) ($MN)
• Table 3 Global Energy-Harvesting Uniforms Market Outlook, By Military & Defense Uniforms (2024-2032) ($MN)
• Table 4 Global Energy-Harvesting Uniforms Market Outlook, By Industrial & Worker Uniforms (2024-2032) ($MN)
• Table 5 Global Energy-Harvesting Uniforms Market Outlook, By Healthcare Uniforms (2024-2032) ($MN)
• Table 6 Global Energy-Harvesting Uniforms Market Outlook, By Sports & Fitness Apparel (2024-2032) ($MN)
• Table 7 Global Energy-Harvesting Uniforms Market Outlook, By Other Uniform Types (2024-2032) ($MN)
• Table 8 Global Energy-Harvesting Uniforms Market Outlook, By Power Output (2024-2032) ($MN)
• Table 9 Global Energy-Harvesting Uniforms Market Outlook, By Low Power (<10 mW) (2024-2032) ($MN)
• Table 10 Global Energy-Harvesting Uniforms Market Outlook, By Medium Power (10-100 mW) (2024-2032) ($MN)
• Table 11 Global Energy-Harvesting Uniforms Market Outlook, By High Power (>100 mW) (2024-2032) ($MN)
• Table 12 Global Energy-Harvesting Uniforms Market Outlook, By Material (2024-2032) ($MN)
• Table 13 Global Energy-Harvesting Uniforms Market Outlook, By Smart Textiles (2024-2032) ($MN)
• Table 14 Global Energy-Harvesting Uniforms Market Outlook, By Nanomaterials (2024-2032) ($MN)
• Table 15 Global Energy-Harvesting Uniforms Market Outlook, By Piezoelectric Materials (2024-2032) ($MN)
• Table 16 Global Energy-Harvesting Uniforms Market Outlook, By Thermoelectric Materials (2024-2032) ($MN)
• Table 17 Global Energy-Harvesting Uniforms Market Outlook, By Other Materials (2024-2032) ($MN)
• Table 18 Global Energy-Harvesting Uniforms Market Outlook, By Energy Source (2024-2032) ($MN)
• Table 19 Global Energy-Harvesting Uniforms Market Outlook, By Solar Energy (2024-2032) ($MN)
• Table 20 Global Energy-Harvesting Uniforms Market Outlook, By Kinetic Energy (2024-2032) ($MN)
• Table 21 Global Energy-Harvesting Uniforms Market Outlook, By Thermal Energy (2024-2032) ($MN)
• Table 22 Global Energy-Harvesting Uniforms Market Outlook, By Radiofrequency (RF) Energy (2024-2032) ($MN)
• Table 23 Global Energy-Harvesting Uniforms Market Outlook, By Hybrid Sources (2024-2032) ($MN)
• Table 24 Global Energy-Harvesting Uniforms Market Outlook, By Distribution Channel (2024-2032) ($MN)
• Table 25 Global Energy-Harvesting Uniforms Market Outlook, By Direct Sales (2024-2032) ($MN)
• Table 26 Global Energy-Harvesting Uniforms Market Outlook, By Distributors (2024-2032) ($MN)
• Table 27 Global Energy-Harvesting Uniforms Market Outlook, By Online Retail (2024-2032) ($MN)
• Table 28 Global Energy-Harvesting Uniforms Market Outlook, By Other Distribution Channels (2024-2032) ($MN)

Note: Tables for North America, Europe, APAC, South America, and Middle East & Africa Regions are also represented in the same manner as above.