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Video Surveillance Solution for Education School


Release time:

2026-07-17

The National Health Commission, Ministry of Public Security and other four ministries and commissions jointly issued the Notice on Strengthening Hospital Safety and Order Management. The new national standard GB/T 31458-2026 Security Requirements for Hospitals will be officially implemented in August 2026, mandating hospitals to establish an all-scenario security system integrating manpower, physical facilities and technical prevention. The system shall focus on five major risks: violent assaults against medical staff, medical disputes and scalping of registration tickets, theft of narcotic and toxic pharmaceuticals, fire hazards, and unregulated ward visiting.

 

Chapter 1 System Overview

 

1.1 Project Background

 

1.1.1 Industrial & Policy Background

 

The National Health Commission, Ministry of Public Security and other four ministries and commissions jointly issued the Notice on Strengthening Hospital Safety and Order Management. The new national standard GB/T 31458-2026 Security Requirements for Hospitals will be officially implemented in August 2026, mandating hospitals to establish an all-scenario security system integrating manpower, physical facilities and technical prevention. The system shall focus on five major risks: violent assaults against medical staff, medical disputes and scalping of registration tickets, theft of narcotic and toxic pharmaceuticals, fire hazards, and unregulated ward visiting.
Meanwhile, national initiatives including the County Hospital Improvement Program, Regional Medical Center construction, Smart Hospital 3.0 and Electronic Medical Record Grading Assessment are being rolled out. Hospitals are required to interconnect data from in-hospital security, logistics and clinical departments to realize unified dispatching and visualized management. Relevant policies stipulate that hospitals failing to complete intelligent security upgrading will be penalized in hospital grading assessment and financial performance evaluation.

 

1.1.2 Core Existing Pain Points of Hospitals

 

Difficult access control amid complex personnel structure

 

Outpatients, accompanying family members, attendants, medical scalpers and unauthorized loiterers intermingle freely, with unrestricted access to inpatient wards, leading to frequent theft and doctor-patient conflicts. Key areas including neonatal wards, pharmacies and operating rooms lack graded access authority control, posing severe hidden dangers to patient privacy and pharmaceutical safety.

Low efficiency in emergency response

 

In incidents such as fights, patient falls, fires and missing persons, security personnel must manually retrieve footage from multiple surveillance cameras without automatic linkage alarms, resulting in delayed response and escalated risks.

Severe siloed independent systems

 

Surveillance, access control, parking, fire protection and alarm systems are supplied by different manufacturers with no cross-system linkage. Maintaining multiple independent platforms incurs heavy labor costs.

Conventional security only supports post-incident traceability

 

Lacking AI-based pre-incident early warning, security management relies entirely on manual patrols, with extensive blind zones in corridors, perimeter walls and elevators.

Compliance risks regarding patient privacy

 

Surveillance footage from consultation rooms, obstetric wards and neonatal units lacks encryption and desensitization mechanisms, exposing risks of video leakage and failing to comply with Classified Protection of Cybersecurity Version 2.0 and medical data confidentiality regulations.

Extensive logistics management

 

Ward visiting management, staff attendance, asset inventory and canteen supervision still depend on manual work without unified data statistics, leaving hospital administrators without a comprehensive data cockpit for decision-making support.

 

1.1.3 Technical Development Trends

 

Full HD full-color surveillance

 

4-megapixel or higher ultra-starlight cameras are deployed hospital-wide to deliver clear images in low-light environments such as basements and corridors at night, effectively mitigating interference from backlighting and vehicle headlight glare.

Edge-side AI intelligence

 

Cameras locally execute analysis of facial features, vehicles and risky behaviors to reduce server computing load, with real-time alarm push delivered within seconds.

Convergence of all-scenario IoT devices

 

Video monitoring, radar, access control, fire detection, temperature sensors and charging piles are uniformly connected to the UMS integrated platform, enabling centralized management of all IoT terminals across the hospital via one single system.

In-depth empowerment by large AI models

 

Functions including voice-based video retrieval, person search via image upload, automatic event analysis and intelligent emergency plan generation are supported, realizing integrated searching, control and analysis of all connected devices and events.

 

1.2 Overall Construction Objectives

 

Based on Uniview UMS intelligent IoT integrated platform, a digital smart hospital featuring safety, convenience, cost reduction and regulatory compliance will be built, with seven core construction objectives as follows:

Unified hospital-wide management via one integrated platform

 

Over 20 subsystems are consolidated to eliminate data silos, realizing centralized presentation of all equipment, alarms, personnel and vehicle data.

Four-layer in-depth full-perimeter protection system
  • First line of defense: Hospital perimeter walls and external entrances (radar-video integrated perimeter protection, blacklist interception, human & vehicle snapshot capture)
  • Second line of defense: Internal main roads, parking lots and plazas (early warnings for illegal parking, crowd aggregation and speeding)
  • Third line of defense: Facial recognition speed gates at entrances of outpatient, inpatient and administrative buildings with graded authorized access
  • Fourth line of defense: Encrypted indoor access control for consultation rooms, ICUs, pharmacies, finance offices and computer rooms, with dual-person verification enforced for critical zones

Proactive pre-incident early warning powered by AI

 

The system automatically identifies fights, patient falls, electric bikes entering elevators, high-rise littering, wall climbing, open flames, and troublemakers with real-time pop-up alarm notifications.

Full closed-loop handling of safety incidents

 

Digital records cover the entire workflow: alarm notification → on-site video verification → remote dispatching → on-site disposal → filing and post-event review.

Refined intelligent management of personnel, vehicles and assets

 

Classified management for medical staff, patients, visitors and blacklisted personnel; priority passage for ambulances; RFID traceability for ventilators, narcotic and toxic pharmaceuticals.

AR digital twin visualized command system

 

A full-hospital real-scene unified map enables one-click positioning of emergencies, PTZ camera tracking and linkage with public address broadcast for on-site announcements.

Full regulatory compliance and improved cost efficiency

 

The system meets requirements for Grade A Hospital Assessment, the new national security standard, fire acceptance and Level-3 Classified Protection of Cybersecurity, cutting the manual workload of security and logistics staff by 30%.

 

1.3 Design Principles

 

Compliance & Rationality

 

The design strictly complies with GB/T 31458-2026, GB/T 28181-2022, Classified Protection of Cybersecurity Version 2.0 and General Hospital Construction Standards. It supports compatibility with the hospital’s existing HIS/LIS systems and renovation & reuse of original surveillance and fire-fighting equipment to control project investment.

Advanced & Mature Technology

 

Cutting-edge proven technologies are adopted, including ultra-starlight imaging, radar-video fusion, end-to-end video encryption, large AI models and CD distributed cloud storage. The architecture supports system capacity expansion for the next 5–10 years.

Practical & User-Friendly Operation

 

Lightweight interfaces are customized for security guards, nurses and administrative staff, with support for PC client, mobile APP and mini-program to ensure easy operation and quick learning.

High Reliability & Stability

 

Dual hot standby deployment is applied to core servers, storage devices and core switches. Video footage is cached locally in case of network disconnection without data loss, supporting 7×24-hour uninterrupted equipment operation.

Flexible & Scalable Architecture

 

Modular platform design allows seamless addition of subsequent modules such as building automation, intelligent nursing and dedicated fever ward management.

Data Security & Confidentiality

 

Graded account authority management with permanent audit trails for all operation logs; automatic blurring and desensitization of surveillance footage from obstetric wards, neonatal units and consultation rooms to strictly protect patient privacy.

 

1.4 Design Basis

 

  1. GB/T 31458-2026 Security Requirements for Hospitals
  2. GB/T 28181-2022 Technical Requirements for Information Transmission, Exchange and Control of Public Security Video Surveillance Networking Systems
  3. GB 50348-2018 Technical Code for Security Engineering
  4. GB 50016 Code for Fire Protection Design of Buildings
  5. Information Security Technology – Basic Requirements for Classified Protection of Cybersecurity Version 2.0
  6. Standard for Construction of General Hospitals (Construction Standard No. 110-2008)
  7. Code of Practice for Safety and Order Management of Medical Institutions jointly issued by the Ministry of Public Security and National Health Commission
  8. GB 50395 Code for Design of Video Security Monitoring System Engineering

 

Chapter 2 Project Demand Analysis

 

2.1 Regulatory Compliance Requirements

 

National initiatives including the County Hospital Improvement Program and Regional Medical Center construction mandate smart security upgrading for hospitals. Regular inspections conducted by public security and health authorities require full implementation of the following measures:
  1. Dynamic monitoring of high-risk individuals (real-time early warning for medical troublemakers and registration scalpers on blacklists)
  2. One-touch emergency alarm systems at consultation rooms and nurses’ stations connected to municipal public security and health authorities’ platforms
  3. Integrated linkage of security and fire protection systems, with automatic dispatching triggered by fire alarms
  4. Full audio and video evidence retention for doctor-patient disputes
  5. Level-3 Classified Protection of Cybersecurity for medical data and surveillance videos
Hospitals failing to meet the above requirements will face restrictions on hospital grading evaluation and cuts in fiscal funding.

 

2.2 Hospital Business Management Requirements

 

Lack of digital control for complex premises

 

High foot traffic in outpatient areas and unregulated ward visiting allow unrestricted access to inpatient wards by outsiders. Critical zones including pharmacies, finance offices and hazardous chemical storage rooms lack intelligent protection, with manual management unable to fully mitigate theft risks.

Slow emergency response to unexpected incidents

 

No automatic alarm linkage is available for conflicts, fires or missing persons; security staff spend over 10 minutes manually retrieving multi-channel surveillance footage, which may amplify safety hazards.

Low intelligence and isolated information systems

 

Surveillance, access control, parking and fire protection systems operate independently without a unified dispatching platform, resulting in heavy maintenance workloads and a lack of visualized data dashboards to support hospital administrators’ decision-making.

Inadequate functional command center

 

Traditional surveillance systems only support video playback, lacking an integrated large-screen dashboard integrating AR real-scene mapping, passenger & vehicle flow statistics, alarm information and asset data, making it impossible to grasp the hospital’s overall operational status at a glance.

 

Chapter 3 Overall System Design

 

3.1 Overall Design Concept

 

Taking video AI perception as the foundational layer and the UMS integrated platform as the core, this system design centers on smart hospital business scenarios. It integrates full-range businesses covering personnel, vehicles, fire protection, alarms, assets, ward management and logistics to construct a complete four-tier architecture of "Perception – Transmission – Platform – Application". The system realizes integrated pre-incident early warning, real-time on-site dispatching and post-incident traceability for smart hospital operation.

 

3.2 Four-Tier System Architecture

Perception Layer

 

Ultra-starlight cameras, radar-video integrated all-in-one devices, facial recognition speed gates, visitor management terminals, one-touch alarm boxes, vehicle barrier gates, elevator AI cameras, thermal imaging cameras, human detection radars, RFID asset tags, smoke sensors and fire alarm control panels, information display screens, and patrol checkpoints.

Network Transmission Layer

 

An independent dedicated security private network is deployed for the hospital, physically isolated from the clinical HIS intranet. A three-tier gigabit fiber network architecture consisting of core, aggregation and access layers is adopted. Services are isolated via VLAN zoning with redundant link backup, and the transmission latency is controlled within 400ms.

Platform Service Layer (Uniview UMS Intelligent IoT Integrated Platform)

 

Serving as the unified core hub, this layer integrates nine core services: video management, facial recognition, vehicle control, AI analysis, AR real-scene mapping, security-fire linkage, cloud storage, operation & maintenance, and large AI model engine. It provides unified interfaces for external docking with health commission platforms and the hospital’s HIS system.

Application Terminal Layer

 

LED/LCD large display screens in the command center, PC management workstations, mobile APPs for security staff and nurses, ward visiting mini-programs, hospital guidance display screens, and interface ports for higher-level supervision authorities.

 

3.3 Full-Network Deployment Architecture

A dedicated independent local area network for security business is constructed across the whole hospital. Access switches are installed in the weak current room of each building, while a three-layer core switch is deployed in the central computer room.

 

Front-end IP cameras, access control devices and alarm terminals are aggregated hierarchically to the server cluster in the machine room via optical fibers. Decoding and splicing control output signals to the command center large screen, supporting both on-site local access and remote mobile terminal access.

 

 

3.4 Twenty Core Construction Modules

 

  1. High-Definition AI Video Surveillance System
  2. Facial Recognition Personnel Management System (medical staff attendance + ward visiting & accompanying personnel management + blacklist monitoring)
  3. Intelligent Parking Lot Vehicle Management System
  4. Intelligent Radar-Video Perimeter Early Warning System
  5. One-Touch Emergency Alarm System for Medical Staff
  6. AR Real-Scene Digital Twin Command System
  7. Integrated Security & Fire Protection Linkage Platform
  8. Video AI Intelligent Behavior Analysis System
  9. Electronic Patrol + Remote Video Inspection System
  10. Intelligent Supervision System for Open Kitchen Visibility Project
  11. Digital Radar Ward Monitoring System
  12. Medical RFID Asset Management System
  13. End-to-End Video Encryption Protection System
  14. Network Security Access Control System
  15. Integrated Operation & Maintenance Management Platform
  16. Hospital Information Release & Guidance System
  17. CDS Medical Cloud Storage System
  18. Large-Screen Display & Control System for Command Center
  19. Large AI Model Intelligent Application System
  20. UMS Integrated Management Platform

 

3.5 Core Advantages of the Solution

 

Full-stack self-developed integrated hardware & software

 

All products including cameras, servers, storage devices, platform software and large AI models are independently developed by Uniview. There are no compatibility issues with third-party products, and unified after-sales and maintenance services are available.

Integration of 20 subsystems on one unified platform

 

Eliminate the need for separate procurement of multiple independent software systems. A single set of accounts manages personnel, vehicles, assets, fire protection and alarms, greatly cutting procurement and operation & maintenance costs.

Hospital-scenario exclusive AI algorithms

 

Optimized algorithms targeting typical hospital risks such as assaults on medical staff, electric bikes carried into elevators, patient falls, high-rise littering and irregular ward visits, which significantly reduce false alarm rates.

Comprehensive medical privacy protection system

 

End-to-end encryption covering the whole lifecycle of video data including collection, transmission, storage and preview. Automatic video desensitization is applied to obstetric wards and NICUs, fully complying with medical privacy regulations.

Strong compatibility with existing equipment

 

Supports access to mainstream third-party surveillance cameras and fire alarm control panels available on the market. Complete replacement of old equipment is unnecessary, saving renovation budgets.

Empowered by large AI models

 

Supports voice-based person retrieval, image traceability and intelligent monitoring, boosting the efficiency of searching for people and assets by 90%.

Full-dimensional compliance support

 

One-stop solution that meets all inspection requirements including Grade A Hospital Reassessment, national security standard GB/T 31458-2026, fire control, food and drug supervision, and classified cybersecurity protection.

Cost reduction & efficiency improvement

 

Automated business processes replace massive manual patrols, registration and asset inventory work, cutting substantial annual labor expenses for logistics teams.

 

Chapter 4 High-Definition AI Video Surveillance System

 

4.1 System Overview

 

Video surveillance serves as the foundation of hospital-wide security protection, covering all scenarios including hospital perimeters, entrances and exits, outpatient areas, inpatient wards, pharmacies, ICUs, elevators, canteens and underground parking lots. Equipped with multiple types of dedicated cameras such as ultra-starlight, thermal imaging, panoramic, explosion-proof and corridor-specific cameras, the system integrates AI intelligent analysis to realize 24/7 all-weather visualized supervision. All video recordings are stored in structured format to support daily management and incident evidence collection.

4.2 Scenario-Oriented Design of Front-End Camera Points

 

4.2.1 Hospital Perimeters and External Entrances

 

Radar-video dual-light alert cameras are installed along perimeter walls to filter interference from trees and birds. The system will trigger audible-visual alarms, voice broadcasting and white light fill light automatically once wall-climbing personnel are detected.

 

Explosion-proof thermal imaging cameras are deployed at liquid oxygen stations and hazardous waste warehouses to detect high-temperature fire hazards in zero-light environments.

Multi-lens panoramic PTZ hybrid cameras are adopted at main hospital gates. The panoramic lens provides full coverage of hospital entrances and automatically captures facial features and license plates, while the PTZ camera locks onto and tracks suspicious targets autonomously.

 

4.2 Scenario-Oriented Design of Front-End Camera Points

 

4.2.2 Public Areas Inside the Hospital

 

180° panoramic stitching cameras are deployed in outpatient halls to count passenger flow synchronously; strong light suppression bullet cameras are installed on main roads to eliminate glare from vehicle headlights; 32MP variable-focus PTZ cameras are mounted on high points across the campus for full-site cruise monitoring; thermal imaging cameras are arranged in non-motor vehicle sheds to detect spontaneous combustion risks during charging.

 

4.2.3 Indoor Building Scenarios

  1. Corridors: Cameras supporting Corridor Mode, with vertical 9:16 image stretching to cut down the number of required camera points.
  2. Elevators: Miniature turret AI cameras with built-in electric bicycle recognition function. The system will trigger door-locking alarms once electric bikes are detected entering elevators.
  3. Consultation Rooms & Cashier Windows: Wide dynamic dome cameras with built-in audio pickup, fully recording doctor-patient communications for evidence retention.
  4. Pharmacies & Finance Offices: Encrypted cameras that automatically blur video frames for unauthorized accounts.
  5. Obstetric Wards & NICUs: End-to-end encrypted cameras with graded viewing access authority.
  6. Exterior Walls of Inpatient Buildings: Special cameras for detecting objects thrown from heights, which automatically lock the floor where the falling object originates.

 

4.2.4 Special Explosion-Proof Scenarios

 

304 stainless steel explosion-proof cameras are installed in oxygen cylinder storage rooms and hazardous chemical warehouses. The products comply with the explosion-proof standard ExdⅡC T6 to eliminate the risk of equipment spontaneous combustion.

4.3 Transmission Network Planning

A three-tier gigabit fiber network architecture consisting of core, aggregation and access layers is adopted. Independent VLANs are divided for each building to realize physical isolation of different service streams.

 

Bandwidth Standards: Single-channel bandwidth for 4MP cameras ≥ 20 Mbps; end-to-end transmission latency ≤ 400 ms; packet loss rate less than 0.1%.

 

Key switches adopt 1+1 redundancy for power supplies and main control boards, with link aggregation for backup. Cameras cache video footage locally when network disconnection occurs.

 

4.4 Core Platform Functions

  1. Graded Authority Management:Independent accounts are assigned to hospital directors, security staff, nurses and logistics personnel; access permissions for video streams of ICUs and pharmacies are isolated from other users.
  2. Real-Time Multi-Split Preview:Supports 1/4/9/16/25 split screen modes; PTZ camera functions include box zoom-in and preset position cruise patrol.
  3. Intelligent Video Playback:Sub-second retrieval by time, human face, vehicle and alarm events; video clips support download and archiving.
  4. Electronic Map Linkage:Alarm points automatically pop up with red frame prompts on the electronic map, enabling one-click jump to live video streams.
  5. Equipment O&M Diagnosis:Active alarms are triggered for blurry images, offline devices and hard disk failures, with maintenance work orders generated automatically.

 

4.5 Storage System Design

Two optional storage solutions are provided: CDS Cloud Defined Storage and professional IPSAN disk arrays.
  1. Video Retention Duration
  • 30 days for ordinary areas;
  • 90 days for key zones including pharmacies, emergency departments, entrances & exits and ICUs;
  • Face and vehicle snapshot images stored for 180 days.
  1. Block Direct Storage technology eliminates file fragments and delivers millisecond-level retrieval speed.
  2. RAID 5/6 disk protection with hot spare disk redundancy ensures no video data loss even if a hard disk fails.
  3. Supports batch video export and case archiving to meet evidence collection requirements of public security authorities.

 

4.6 Large-Screen Display & Control System

The command center supports either LCD splicing screens or fine-pitch LED screens, matched with distributed decoding & splicing controllers. It enables window roaming, overlay, scaling and red-frame pop-up alarms, while synchronously displaying multi-service data on the wall.

 

4.7 System Advantages

  1. Full-scenario camera selection tailored to the hospital’s complex lighting, explosion-proof and privacy protection requirements.
  2. Stable and reliable full links covering network, storage and platform to guarantee zero loss of video recordings.
  3. In-depth integration of AI intelligence, upgrading the system from post-incident review to proactive pre-warning.
  4. Compliant with open national standard protocols, fully compatible with the hospital’s existing surveillance equipment to preserve previous investment.

 

Chapter 5 Facial Recognition Personnel Management System

 

5.1 System Overview

Built upon deep learning-based facial structuring algorithms, this system conducts unified management of medical staff, inpatients, accompanying caregivers, visitors and blacklisted individuals within the hospital. It integrates functions of entrance speed gates, ward access control, staff attendance, online ward visiting, passenger flow statistics and personnel trajectory analysis, so as to realize graded, time-based and zone-divided personnel access control.

 

5.2 Core Business Functions

 

5.2.1 Graded Access Control

 

  1. Speed gates at main hospital entrances: Medical staff on the whitelist are granted 24-hour access; inpatients and accompanying personnel receive time-limited facial access credentials issued against their hospitalization records; visitors complete registration by scanning QR codes at the reception to obtain temporary access codes; real-time audible and visual alarms will be triggered when blacklisted persons approach.
  2. Turnstiles for inpatient wards: Access is restricted to designated visiting hours, and permissions will automatically expire once the time limit is exceeded. Only authorized family members with permits and attending physicians are allowed entry to ICUs and neonatal wards.
  3. Pharmacies and archives: Dual-person verification combining facial recognition and password input is required for access.

 

5.2.2 Dynamic Monitoring of Blacklisted Personnel

 

A blacklist database is established for medical troublemakers, registration scalpers and thieves. All facial snapshot cameras across the hospital perform real-time comparison against the database. If such persons loiter repeatedly, alerts will be automatically pushed to the security staff’s mobile APP, and their movement trajectories will be marked on the electronic map.

5.2.3 Structured Retrieval & Image-Based Person Search

 

Personnel filtering is supported by attributes including age, gender, clothing, mask and glasses. Users may upload a photo to retrieve the target’s full-day movement trajectories across the entire campus, enabling fast location of missing elderly patients and suspects involved in medical disputes.

 

5.2.4 Intelligent Attendance for Medical Staff

Compatible with day shifts, night shifts and emergency overtime schedules. The system supports online leave application, make-up clock-in and overtime statistics, automatically generates monthly attendance reports, and enables direct docking with the hospital’s human resources system.

 

5.2.5 Digital Ward Visiting Management

Family members make visiting reservations online via WeChat Mini Program, and the system automatically issues temporary facial access permissions. The background system counts real-time visiting passenger flow of each ward and generates monthly reports automatically to prevent unauthorized overnight stays of irrelevant personnel.

 

5.2.6 Outpatient Passenger Flow Analysis

Cameras installed in halls count inbound and outbound visitors in real time. Early warnings will be triggered when crowd density exceeds the threshold, assisting the hospital to open additional triage windows and divert crowds during peak consultation hours.

 

5.3 System Value

The system realizes closed-loop management of all personnel in the hospital and reduces manual workload for registration and ward rounds. Trajectory tracing can be quickly performed for doctor-patient conflicts and missing persons, significantly lowering security risks within the hospital compound.

 

Chapter 6 Intelligent Vehicle Management System

 

6.1 System Overview

 

This system implements full-process management covering ambulances, private vehicles of medical staff, outpatient visitors and new energy electric vehicles. It integrates entrance and exit barrier gates, underground parking space guidance, illegal parking & speed detection, fire prevention for new energy vehicles and vehicle blacklist monitoring functions to deliver barrier-free quick passage, resolving congestion during morning and evening peak hours at the hospital.

 

6.2 Core Functions

1.Classified Vehicle Release

The barrier arm automatically lifts with priority upon ambulance identification; monthly-parking vehicles for medical staff enjoy contactless passage; temporary visitor vehicles enter via license plate recognition and complete contactless payment by scanning QR codes; blacklisted vehicles are prohibited from entering the hospital. Tidal lanes are supported to divert traffic during morning and evening rush hours.

2.Intra-Hospital Road Control

Radar-video integrated devices detect speeding and fire lane occupation, trigger linkage with LED display screens to remind vehicle owners to move away, and automatically capture and archive snapshots as evidence.

3.Parking Lot Guidance & Reverse Car Search

Large entrance screens display real-time available parking spaces; drivers can quickly locate their vehicles by inputting license plate numbers via on-site query terminals inside the parking lot.

4.New Energy Parking Space Management

Thermal imaging equipment is deployed in charging zones to monitor battery overheating and fire risks, enabling early warning to eliminate fire hazards.

Vehicle Trajectory Traceability

By inputting a license plate number, users can query all access and road passage records across the hospital, supporting trace investigation for vehicle scratches and hit-and-run incidents.

 

Chapter 7 Intelligent Radar-Video Perimeter Early Warning System

 

 

  1. Dual-mode integration of radar and video filters interferences from swaying branches, birds and light shadows, cutting false alarm rate by 95%.
  2. Instant white light flashing and voice expulsion alerts are triggered automatically when personnel climb over the perimeter wall or break into liquid oxygen / hazardous chemical zones.
  3. Alarms link nearby PTZ cameras for zoom tracking automatically, with synchronous video recording for evidence storage.
  4. Three deployment options are available: standard dual-light cameras, thermal imaging cameras and radar-PTZ linkage, adapting to various wall perimeter scenarios.

 

Chapter 8 One-Touch Emergency Alarm System for Medical Staff

 

 

  1. Full terminal coverage: Built-in alarm boxes installed in consultation rooms and nurse stations; rainproof outdoor alarm poles arranged in corridors and parking lots.
  2. Multi-level alarm receiving mechanism: Alarms are simultaneously pushed to the central large screen and security staff’s mobile phones; calls will be automatically transferred to the general duty staff if unanswered.
  3. Automatic linkage with surrounding cameras for pop-up live view, emergency broadcast and unlocking of nearby access control upon alarm activation.
  4. Full-duplex two-way audio intercom with audio and video recording throughout the incident, completely retaining evidence materials for doctor-patient disputes.
  5. Flashing warning lights at night serve as a deterrent to reduce risks of violent assaults on medical workers.

 

Chapter 9 AI Intelligent Behavior Analysis System

 

Edge AI algorithms are embedded in front-end cameras to identify and issue real-time early warnings for all hospital safety hazards, including: doctor-patient fights, personnel falls, crowd gathering, wall climbing, high-rise littering, electric bicycles entering elevators, indoor smoking, open flames, obstructions piled in fire lanes, unauthorized loitering in pharmacies, and staff being absent from post.

 

Chapter 10 Electronic Patrol + Remote Video Inspection System

 

  1. Electronic patrol: Checkpoint tags are deployed across the hospital with pre-planned patrol routes. Automatic alarms will be generated for missed scheduled patrols, and complete patrol logs can be exported.
  2. Remote video inspection: Customizable PTZ cruise routes enable automatic cyclic monitoring of key hospital areas to replace manual foot patrols.

 

Chapter 11 Video Content Encryption & Protection System

 

  1. End-to-end video encryption covering the whole lifecycle of data collection, transmission, storage and live preview.
  2. Automatic image desensitization and blurring for video feeds from obstetric wards, neonatal units and consultation rooms when accessed by unauthorized accounts.
  3. Multi-level key management mechanism and permanent audit trails for all operations to prevent video leakage and unauthorized copying.

 

Chapter 12 Network Security Access Control & Protection System

 

 

  1. The dedicated security private network is physically isolated from the hospital’s clinical HIS intranet.
  2. Access whitelist management is applied to front-end cameras and background servers, blocking all unauthorized devices from network access.
  3. Terminal control restricts unauthorized copying of video data via external USB flash drives, fully meeting all security specifications for Class-3 Cybersecurity Classified Protection.

 

Chapter 13 Integrated Operation & Maintenance Management Platform

 

The platform automatically monitors all networked devices: proactive alarms are pushed for offline cameras, image failures, faulty storage hard disks and abnormal bandwidth. It auto-generates maintenance work orders and implements full-lifecycle management with one-file-per-device archives. Automatic O&M report statistics drastically cut manpower costs for routine equipment inspections.
 

Chapter 14 Hospital Information Release & Guidance System

LED guidance screens are installed in outpatient halls, inpatient lobbies and elevators:
  1. Daily push of physician schedules, hospital visit guidelines and health science popularization content;
  2. One-click full-screen evacuation notifications for emergencies;
  3. Real-time dynamic display of available parking spaces and waiting patient counts.

 

Chapter 15 Intelligent Supervision System for Transparent Kitchen Project

Cameras cover the entire kitchen back-of-house area. AI algorithms identify chefs without masks and irregular operational behaviors. Video streams are synchronously accessible on the hospital internal platform and market supervision authority terminals, enabling full transparent supervision over food safety.

 

Chapter 16 Digital Radar Ward Monitoring System

Contactless human detection radars are adopted without facial data collection to safeguard patient privacy:
  1. Real-time detection of patient falls, with instant alarms sent to nurse stations;
  2. Monitoring of dwell duration inside wards to identify risks of unauthorized patient wandering;
  3. Automatic reminders for medical staff to conduct rounds when bedridden patients are left unattended for long periods.

 

Chapter 17 Medical CDS Cloud Storage System

Built on a distributed cloud storage architecture, the system supports mass data storage for medical imaging, surveillance footage and electronic medical records. It features elastic capacity expansion, multi-data replica fault tolerance and second-level retrieval performance to satisfy long-term hospital data archiving demands.

 

Chapter 18 AR Real-Scene Digital Twin Command System

Based on high-position panoramic PTZ cameras across the campus, the real-scene map is overlaid with tag markers for all surveillance, access control, alarm and fire-fighting points:
  1. Linkage between wide overview and close-up views; clicking tags pops up corresponding live video feeds instantly;
  2. Flashing red dots mark alarm locations on the map, supporting one-click jump to live scene footage;
  3. Aggregation of passenger flow, vehicle flow, alarm and hospital bed data to form a comprehensive situation dashboard for hospital directors.

 

Chapter 19 Integrated Security & Fire Protection Linkage Platform

Bidirectional interconnection is established between the security platform and the hospital fire alarm control panel to realize two-way linkage:
  1. Smoke and electrical fire alarms automatically pop up live surveillance videos of the affected zones;
  2. Auto-unlock access control gates on fire escape routes, lift vehicle barriers and activate campus-wide evacuation broadcast;
  3. Online electronic fire patrol function auto-generates fire inspection ledgers to support official fire supervision audits.

 

Chapter 20 Intelligent Applications Powered by Large AI Models

  1. Universal Search: Retrieve personnel or vehicles via voice, text or uploaded photos, with automatic aggregation of complete movement trajectories. Ideal for locating missing patients, suspicious individuals and tracing lost medical assets.
  2. Universal Control: Rapidly create customized AI monitoring rules through natural language, supporting personalized early warnings targeting drug scalpers, road occupation and medical troublemakers.
  3. Digital Assistant: Voice control for large screen operation, video playback and alarm record query, simplifying command center operations.

 

Chapter 21 Overall Construction of Command Center

 

21.1 Large-Screen Display & Control System

Fine-pitch LED / LCD splicing screens are matched with distributed decoding controllers, supporting multi-window roaming, highlighted red alarm frames and split-screen display of multi-service data.

 

21.2 Digital Twin Situation Dashboard

Six visualized data modules: General Security Alarm Overview, Outpatient Passenger Flow, Inpatient Visiting Statistics, Intra-Hospital Vehicle Data, Equipment O&M Status, On-Duty Medical Staff Metrics.

 

21.3 Supporting Console Equipment

Management workstations, professional control keyboards, emergency broadcast hosts and storage arrays are deployed to support collaborative disposal by multiple security staff, with remote access available via mobile terminals.

 

Chapter 22 UMS Integrated Management Platform

Serving as the unified core management hub for the whole solution, it realizes unified access, single sign-on, centralized data management and consistent alarm notification for all subsystems. It provides open external APIs for docking with health commission platforms and the hospital’s HIS/LIS systems, alongside standardized secondary development interfaces to achieve cross-department hospital-wide data interconnection and sharing.

 

Chapter 23 Implementation Value of the Solution

 

23.1 Safety Value

The four-layer in-depth defense system enables pre-incident early warning, rapid on-site disposal and complete post-event evidence collection, drastically reducing incidents including violent assaults on medical staff, pharmaceutical theft, fires, missing persons and high-rise littering. Full audio-video records of doctor-patient disputes help the hospital avoid legal compensation liabilities.

 

23.2 Operation & Management Value

Full automation of ward visiting management, staff attendance, parking control and asset inventory cuts manual workload by 30%. Visualized data on energy consumption, equipment status and pedestrian flow enables refined management and lower operational costs.

 

23.3 Patient Service Value

Separated pedestrian and vehicle flow, online visiting reservation and intelligent outpatient crowd diversion reduce queuing and congestion. Remote video visiting for isolation wards greatly improves satisfaction of patients and their families.

 

23.4 Emergency Disposal Value

Full linkage covering security-fire systems, personnel, vehicles and video surveillance shortens emergency response time to within 1 minute. Priority passage is guaranteed for ambulances and fire engines, meeting dispatching requirements during major public health emergencies.

 

23.5 Compliance & Rating Value

One-stop compliance with Grade A Hospital Reassessment, the new national hospital security standard, fire control regulations, food & drug supervision rules and network classified protection requirements. It eliminates risks of penalty points during official inspections and facilitates acceptance for Smart Hospital 3.0 and County Hospital Improvement Program projects.

 

Chapter 24 Applicable Implementation Scenarios

  1. Large Grade A General Hospitals & Regional Medical Centers: Full deployment of all 20 subsystems.
  2. Grade B General / Traditional Chinese Medicine Hospitals: Streamlined configuration excluding large AI model and digital ward modules.
  3. Maternal & Child / Children’s Hospitals: Enhanced encrypted video management for obstetric and neonatal wards.
  4. County People’s Hospitals & Township Health Centers: Lightweight basic solution including video surveillance, emergency alarms and parking management.
  5. Infectious Disease / Fever Designated Hospitals: Specialized independent encrypted subnets for isolated wards.

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