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China Autonomous Retail Vehicle Industry Report, 2022

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    Report

  • 160 Pages
  • June 2022
  • Region: China, Global
  • Research In China
  • ID: 5631515
Research on Autonomous Retail Vehicles: Lower Costs Accelerate Mass Production with Ever-spreading Retail Scenarios

Autonomous retail vehicles integrate technologies such as 5G, artificial intelligence, big data, mobile Internet and autonomous driving. They can move with the changes in the surrounding traffic autonomously. Users can hail such vehicles directly through APPs, and then they will arrive at the designated location accurately to provide convenient services.

At present, the digital economy has become the key engine of China's economic development. According to information from the Ministry of Industry and Information Technology, China has built 1.615 million 5G base stations so far, serving more than 400 million 5G users. China is a global leader in 5G infrastructure, mobile Internet ecology, and e-commerce. Smartphones have become the preferred terminals of the digital economy, smart cars will become the second-ranking terminals, and autonomous retail vehicles act as not only important terminals connecting e-commerce services and smartphones, but also core intelligent terminals that realize the transition from `people looking for services` to `services looking for people` (or `goods looking for people`).

Autonomous retail vehicles are widely used in smart scenic spots, AI parks, commercial streets, zones, squares and other places for selling high-demand products such as beverages, breakfast, fast food, fresh products, and even shoes. Mobile new retail lets goods look for people. Users can stop autonomous vending vehicles by scanning QR codes, beckoning, and touching displays, and pay for what they choose by QR code scanning. This mode is time-saving, convenient and easy. For merchants, presenting products in front of customers in crowded areas (subway entrances, business districts, zones, etc.) during rush hours and lunch break when the demand hits the maximum can significantly increase the transaction volume. The service radius of merchants has been expanded from 1-2 kilometers to 5 kilometers.

1. The policies for low-speed autonomous vehicles have been gradually improved


As low-speed autonomous vehicles, autonomous retail vehicles are used in cargo-carrying scenarios that are easier to handle. On May 25, 2021, Beijing High-level Autonomous Driving Demonstration Zone released the `Implementation Rules for the Management of Autonomous Delivery Vehicles`, and issued vehicle numbers for autonomous delivery vehicles of JD.com, Meituan and Neolix. Since then, L4 autonomous driving technology has been verified by large-scale testing and on-road operation, which has promoted the vigorous development of China’s autonomous delivery industry.

Neolix launched nearly 1,000 autonomous vehicles in 2021, and plans to roll out another 2,000 autonomous delivery vehicles in 2022. Meituan plans to deploy 1,000 autonomous delivery vehicles in Shunyi District within three years, and put a total of 10,000 such vehicles into operation nationwide to achieve multi-city, multi-scenario and all-weather coverage.

Up to now, Beijing High-level Autonomous Driving Demonstration Zone has granted a total of 225 test licenses, including 86 body codes for autonomous delivery vehicles. So far, the demonstration zone has started the third phase of the construction project. In the demonstration zone, 332 digital intelligent intersections have been fully covered by the infrastructure within a range of 60 square kilometers. Scenarios such as autonomous retail, autonomous police patrols, and micro-circulation shuttling have approached citizens.

At the beginning of March 2022, Shanghai Municipal Transportation Commission announced that a total of 13 solutions for Shanghai Intelligent Connected Vehicle Demonstration Application Innovation Project had been confirmed after companies' voluntary application, on-site evaluation and solution review according to the `Implementation Plan for the Expansion of Demonstration Application Scenarios of Intelligent Connected Vehicles in Shanghai (2021-2023)`. Among them, 2 solutions were involved with `smart retail`, requiring `no less than 20 smart retail vehicles” in operation.

2. The costs of low-speed autonomous delivery vehicles are gradually sinking, promoting mass production of such vehicles for more scenarios


Depending on models, sensor solutions, etc., an autonomous delivery vehicle generally costs RMB200,000 ~ 500,000, let alone other expenses incurred by insurance, vehicle operation and maintenance, on-site safe operation and maintenance, remote monitoring, labor, cloud platform services, etc. China-based Haomo.AI has launched its first autonomous delivery vehicle, the Little Magic Camel, priced at RMB130,000. It is equipped with 3 mechanical LiDAR sensors worth about RMB40,000, radar, cameras and a computing platform. The total cost is nearly RMB100,000. Among the three basic systems of perception, decision-making and actuation, the computing platform plays a key role in the safe operation of autonomous retail vehicles.

With the gradual penetration of autonomous retail vehicles from fixed scenarios to more complex public road scenarios, extremely high requirements are placed on low-latency processing and multi-sensor information fusion of computing platforms. In the field of computing platforms, typical automotive chip enterprises include Horizon Robotics, Huawei, Idriverplus, Haomo.AI, Neolix, WeDrive.Al, Go Further AI, etc. The current mainstream computing platform is the NVIDIA Jetson AGX Xavier platform which is estimated at around RMB10,000 according to the supplier's price that is expected to further drop in the future.

In addition, LiDAR whose cost is on a downward trend plays an extremely critical role in the perception system. Most of the current autonomous delivery vehicles use 16-channel LiDAR. Under the stimulation of demand, Chinese LiDAR vendors, such as LeiShen Intelligent System, RoboSense, HESAI, Livox, Huawei, etc., have sprung up, and they can basically meet the demand of autonomous delivery vehicles.

Chassis-by-wire is one of three core components of an autonomous delivery vehicle. In China, main chassis-by-wire players include PIX, Teemo, UISEE, Skywilling, Neolix, and Haomo.AI. For example, PIX Moving offers chassis-by-wire at the price of RMB80,000 ~ 100,000. With the continuous deployment of autonomous delivery vehicles and autonomous retail vehicles in China, large-scale mass production will further drag down the price of chassis-by-wire.
  • The chassis of autonomous vehicles is changeable, and a specific service function can be fixed horizontally like autonomous retail vehicles, autonomous media vehicles, etc.
  • UISEE’s autonomous vehicles: Different services can be performed at different times of the day with a higher operational efficiency.
UISEE, which is committed to all-scenario strategy, continues to expand application scenarios of its products. On September 25, 2021, it officially released UiBox (an L4 autonomous driving solution for urban services) and UiBox (an autonomous delivery vehicle) to further promote `commercial application of AI drivers` in all scenarios. UiBox can offer different services at different times to improve operational efficiency.

3. The application scenarios of autonomous retail vehicles have spread from semi-enclosed zones to open roads and then to large communities


In 2021, Jushi Technology deployed an autonomous fleet in Zhangjiang Artificial Intelligence Island in Shanghai where employees can buy a variety of food, office supplies, and daily necessities from autonomous retail vehicles. Autonomous delivery vehicles can provide food delivery services such as pizza delivery to restaurants on the artificial intelligence island. After employees place orders through their mobile phones, autonomous vehicles will automatically deliver the meals prepared by restaurants to employees who only need pick up the meals according to the notification on their mobile phones. In addition, the supporting monitoring platform can surveil the operation of autonomous vehicles around the clock to ensure safety.

On June 1, 2022, Shanghai WeDrive.Al officially introduced autonomous retail vehicles to Nanfeng Future Community, Shangyu, Shaoxing, Zhejiang to provide autonomous sales services for the community. Nanfeng Future Community consists of City Star, Liangjiang Home and Community Center Complex, which are home to more than 40,000 residents and more than 12,700 families.

On April 22, 2022, Neolix’s autonomous vehicles were also welcomed into the large community of Shanghai Lijing in Pudong District, Shanghai. Autonomous retail companies are covering more application scenarios.

4. OEMs use their advantages in technology and manufacturing to explore new businesses


On April 30, 2021, In-driving Tech was invited to participate in the Science Night of Han Street in Wuhan. The interactive area displayed the Sharing-Box, a high-tech autonomous smart car developed by In-driving Tech and Dongfeng Motor.

Sharing Box is an autonomous intelligent point-to-point transportation platform launched by Dongfeng Motor. It is constructed by integrating TITAN (an autonomous driving domain controller of In-driving Tech) and Athena Software to realize L4 autonomous driving based on HD maps in specific scenarios.

In addition to Dongfeng Motor, Wuling has also explored new businesses with its own technology and manufacturing advantages, and launched `Xiaoling` driverless smart retail vehicle, which has been practically applied.

In Baoding, Haomo.AI, a company backed up by Great Wall Motor, has built the world's first flexible manufacturing base for L4 low-speed autonomous vehicles. It produces a variety of models (including autonomous retail vehicles). After the latest upgrade, the design capacity of the production line can reach 10,000 vehicles per year.

5. With the support of capital, major players aggressively enhance resilience, use closed data loop to continuously improve technology and ensure safe operation


During the R&D process of Little Donkey, which can run more than 100 kilometers on a charge of 4 kWh, Alibaba DAMO Academy has built its own autonomous driving cloud platform from the very beginning, which uploads massive data (scenario databases, autonomous vehicle data, data from data collection vehicles) to Alibaba Cloud. Carrying out data management, simulation testing and algorithm model training on the cloud has greatly improved the R&D efficiency of autonomous driving algorithms. Based on this autonomous driving cloud platform, Alibaba DAMO Academy has launched the world's first `hybrid simulation test platform` for autonomous driving. The platform uses a combination of virtual and reality simulation technologies, introduces real road test scenarios and cloud trainers. It takes only 30 seconds to simulate an extreme scenario, and the system’s daily virtual test mileage can exceed 8 million kilometers, greatly improving the training efficiency of autonomous driving AI models.

From its debut in September 2020 to March 31, 2022, Little Donkey delivered more than 10 million logistics orders.


According to Jie Jinghua, a partner of Neolix, the current commercial scenarios of Neolix’s autonomous vehicles include both open roads and closed zones such as campuses. A vehicle can obtain 100T data per day, and it actively captures about 20G/day of valuable data (including the original point cloud of LiDAR, images, intermediate results, logs and so on). The Ocean data system completes the storage, cleaning, labeling and model training of these data before finally forming a closed data loop.

When autonomous vehicles become more sophisticated, the ultimate challenge no longer lies in underlying architectures or technical problems, but fragmented scenarios, special extreme situations and human behaviors that can never be predicted instead which account for 5%.


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Table of Contents

1 Overview of Autonomous Retail Vehicles
1.1 Mobile Retail Is a Form of Autonomous Delivery
1.1.1 Hardware Indicators of 12 Typical Autonomous Delivery Vehicles
1.1.2 Cost Downtrend of Autonomous Delivery Vehicles
1.2 Introduction to Autonomous Retail Vehicles
1.3 Business Models of Autonomous Retail Vehicles
1.4 Three Core Components of Autonomous Retail Vehicles: LiDAR
1.4 Three Core Components of Autonomous Retail Vehicles: Computing Platform
1.4 Three Core Components of Autonomous Retail Vehicles: Chassis-by-Wire
1.5 Growth Background of Autonomous Retail Vehicles (1): Vigorous Growth of Social Logistics
1.5 Growth Background of Unmanned Retail Vehicles (2): Blowout of Express Delivery Business
1.5 Growth Background of Unmanned Retail Vehicles (3): Enormous Number of Mobile Payment Netizens
1.5 Growth Background of Unmanned Retail Vehicles (IV): Gradual Maturity of Autonomous Delivery Industry Chain
2 Autonomous Delivery Policies
2.1 Some Chinese Policies for Autonomous Delivery
2.2 Overseas Policies for Autonomous Delivery
2.3 Low-speed Autonomous Vehicle Safety Management and Accident Insurance
3 Autonomous Retail Vehicle Companies in China
3.1 WeDrive.Al
3.1.1 Profile
3.1.2 Overview of Pangolin Robot (Parent Company)
3.1.3 Wedrive S3 (Autonomous Vending Vehicle)
3.1.4 Pandora (Self-developed Autonomous Driving Computing Platform)
3.1.5 Application Cases of Autonomous Retail Vehicles
3.2 Go Further AI
3.2.1 Profile
3.2.2"Juedi" Series Autonomous Retail Vehicles
3.2.3 Core Autonomous Driving Technology
3.2.3 Core Autonomous Driving Suite
3.2.4 Application Cases of Autonomous Retail Vehicles (Parks)
3.2.4 Application Cases of Autonomous Retail Vehicles (Campuses)
3.2.4 Application Cases of Autonomous Retail Vehicles (High Speed Rail Station, etc.)
3.2.4 Application Cases of Autonomous Retail Vehicles (Exhibition Services)
3.2.5 Production
3.2.6 Partners and Operation
3.3 Yours
3.3.1 Profile
3.3.2 Autonomous Retail Vehicles
3.3.3 Competitive Advantages of Autonomous Retail Vehicles
3.3.4 Startup and Financing of Autonomous Vehicle Project
3.3.5 Application Cases of Autonomous Retail Vehicles (1)
3.3.5 Application Cases of Autonomous Retail Vehicles (2)
3.3.6 Cooperative Malls/Shops
3.4 Neolix
3.4.1 Profile
3.4.2 Autonomous Retail Vehicles
3.4.3 NeoWise (Self-developed Autonomous Driving Computing Platform)
3.4.4 Production of L4 Autonomous Vehicles
3.4.5 Application Cases of Autonomous Retail Vehicles (Parks)
3.4.5 Application Cases of Autonomous Retail Vehicles (Zones)
3.4.5 Application Cases of Autonomous Retail Vehicles (Exhibition Services)
3.4.5 Application Cases of Autonomous Retail Vehicles (Communities + Open Roads)
3.4.6 Partners
3.5 Unity Drive
3.5.1 Profile
3.5.2 Autonomous Retail Vehicles
3.5.3 Technical Advantages
3.5.4 Hardware Configuration of Autonomous Retail Vehicles
3.5.5 Application Cases of Autonomous Retail Vehicles
3.5.6 Overall Application
3.5.7 Autonomous Vehicle Partners
3.6 Go Further AI
3.6.1 Profile
3.6.2 Autonomous Retail Vehicles
3.6.3 Configuration and Features of Autonomous Retail Vehicles (1)
3.6.3 Configuration and Features of Autonomous Retail Vehicles (2)
3.6.4 Application Cases of Autonomous Retail Vehicles
3.7 UISEE
3.7.1 Profile
3.7.2 Development History
3.7.3 UiBox (L4 Autonomous Driving Solution)
3.7.4 Autonomous Retail Vehicles
3.7.5 Core Technology
3.7.6 Application Cases of Autonomous Delivery Vehicles (Guangzhou)
3.7.6 Application Cases of Autonomous Delivery Vehicles (Shanghai)
3.7.6 Application Cases of Autonomous Delivery Vehicles (Saudi Arabia)
3.7.6 Establishment of"Autonomous Driving & Smart City Service Innovation Lab”
3.8 CYBER-AI
3.8.1 Profile
3.8.2 Core Team Members
3.8.3 CYBER-EXP-01 Autonomous Vehicle
3.8.4 Hardware Configuration of CYBER-EXP-01
3.8.5 CYBER-VCU
3.8.6 Partners
3.9 Hangzhou Skywilling
3.9.1 Profile
3.9.2"Little Ant" Chassis-by-Wire (NWD01)
3.9.2"Little Fish" Chassis-by-Wire (JD01)
3.9.3 Derivatives of"Little Ant" Chassis-by-Wire
3.9.3 Autonomous Vending Vehicles Based on"Little Ant" Chassis-by-Wire
3.9.4 Chassis Technology of Autonomous Vending Vehicles
3.9.5 Application Cases of Autonomous Retail Vehicles
3.9.5 Exhibited Intelligent Vehicles
3.9.6 Shipments of Autonomous Vehicles
3.9.7 Partners
3.10 Hunan Apollo Intelligent Transportation
3.10.1 Profile
3.10.2 Autonomous Driving R&D Center
3.10.3 Overview of BOBO?GO Autonomous Retail Vehicle
3.10.4 Debut of BOBO?GO
3.10.4 Application Cases of Autonomous Retail Vehicles (Expressway Service Areas)
3.10.4 BOBO?GO (Exhibition)
3.10.4 Application Cases of BOBO?GO (Zones)
3.10.4 Application Cases of BOBO?GO (Scenic Spots)
3.11 In-driving Tech
3.11.1 Profile
3.11.2 TITAN (L4 Autonomous Driving Domain Controller)
3.11.3 Athena Autonomous Driving Platform Software
3.11.4 Application Cases of “Sharing Box” Autonomous Vending Vehicles (Campuses)
3.11.4 Application Cases of “Sharing Box” Autonomous Vending Vehicles (Business Districts)
3.12 Jushi Technology
3.12.1 Profile
3.12.2 Development History
3.12.3 Core Technology
3.12.4 QBOX Autonomous Retail Vehicle
3.12.5 Application Cases of Autonomous Retail Vehicles (1)
3.12.5 Application Cases of Autonomous Retail Vehicles (2)
3.12.5 Application Cases of Autonomous Retail Vehicles (3)
3.12.6 Partners
3.13 Elife
3.13.1 Profile
3.13.2 Autonomous Technology: Autonomous Retail Vehicles
3.14 Wuling
3.14.1 Autonomous Retail Vehicles
3.14.2 Application Cases of Autonomous Retail Vehicles
3.15 White Rhino
3.15.1 Profile
3.15.2 Configuration of Autonomous Vehicles
3.15.3 Core Technology
3.15.4 Typical Application Cases of Autonomous Vehicles (1)
3.15.5 Typical Application Cases of Autonomous Vehicles (2)
3.15.6 Typical Application Cases of Autonomous Vehicles (3)
3.15.7 Typical Application Cases of Autonomous Vehicles (4)
3.15.8 Support for Autonomous Vehicles
4 Major Providers of Basic Chassis for Autonomous Retail Vehicles in China
4.1 Ecar Tech
4.1.1 Profile
4.1.2 IDV
4.1.3 Automotive Chassis Configuration
4.1.4 Chassis-by-Wire Empowers Autonomous Retail Vehicles
4.2 Teemo
4.2.1 Profile
4.2.2 Chassis
4.2.3 Chassis Extension: Autonomous Retail Vehicles
4.3 PIX Moving
4.3.1 Profile
4.3.2 Skateboard Chassis
4.3.3 Chassis Matrix
4.3.3 Chassis Parameters
4.3.4 Perception Configuration of Mobile Space Hardware
4.3.5 Mobile Space Extends to Mobile New Retail
4.3.6 Autonomous Smart Beverage Retail Vehicles
4.3.7 Partners
4.4 Haomo.AI
4.4.1 Profile
4.4.2 Development History
4.4.3 Main Business
4.4.4 Core Competence
4.4.5 Low-speed Autonomous Logistics Vehicles
4.4.6 Chassis-by-Wire of Low-speed Autonomous Vehicles
4.4.7 Autonomous Retail Vehicles
4.4.8 L4 Low-speed Autonomous Vehicle Manufacturing Bases
4.5 MOVE-X
4.5.1 Profile
4.5.2 Development History
4.5.3 Autonomous Vehicles
4.5.4 Parameters of RC ONE Autonomous Vehicle
4.5.5 L4 Autonomous Vehicle Manufacturing and Testing Bases

Companies Mentioned

  • WeDrive.Al
  • Go Further AI
  • Yours
  • Neolix
  • Unity Drive
  • Go Further AI
  • UISEE
  • CYBER-AI
  • Hangzhou Skywilling
  • Hunan Apollo Intelligent Transportation
  • In-driving Tech
  • Jushi Technology
  • Elife
  • Wuling
  • White Rhino
  • Ecar Tech
  • Teemo
  • PIX Moving
  • Haomo.AI
  • MOVE-X

Methodology

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