Download PDF
A New Start for an Old Town
Technology Category
- Analytics & Modeling - Predictive Analytics
- Application Infrastructure & Middleware - Data Visualization
- Functional Applications - Remote Monitoring & Control Systems
Applicable Industries
- Cities & Municipalities
- Construction & Infrastructure
Applicable Functions
- Facility Management
- Quality Assurance
Use Cases
- Building Automation & Control
- Building Energy Management
- Smart City Operations
- Predictive Maintenance
Services
- System Integration
- Software Design & Engineering Services
- Training
The Challenge
Newhall, California, once a bustling trading center and popular backdrop for western films, experienced a dramatic decline as the suburbs of Los Angeles expanded. This led to struggling businesses and high vacancy rates. The City Council aimed to revitalize the area by re-envisioning the central corridor of Main Street. They diverted traffic to a nearby roadway and added a roundabout to improve traffic flow. However, local businesses were concerned that ongoing construction would hurt their already-sinking bottom lines, and commuters were worried about potential delays caused by the roundabout.
About The Customer
Newhall, California, is a historic town that was once a bustling trading center for the Tataviam Native American tribe and later became a popular backdrop for western films in the early 20th century. Over time, the area experienced a decline as the suburbs of Los Angeles expanded, leading to struggling businesses and high vacancy rates. The City Council, in collaboration with PCLD, aimed to revitalize the area by re-envisioning the central corridor of Main Street. PCLD, a design team known for their expertise in public works projects, worked closely with the community to incorporate elements from the town's historical past while ensuring modern functionality and sustainability.
The Solution
PCLD's design for Newhall's Main Street incorporated historical elements to create a classic ambiance while balancing the flow of pedestrians, cyclists, and commuters. Streetlights resembling old gas lamps, wide brick sidewalks, and themed amenities like benches and trash receptacles accentuated the old town motif. The design also included sustainable features, such as permeable brick pavers and decomposed granite paving, to manage water efficiently. PCLD utilized Vectorworks Landmark design software for water budget calculations and Building Information Modeling (BIM) capabilities to create a single source of information for the project. This allowed for up-to-date quantity calculations and state-mandated water use estimates. The landscape plan included native and regionally adapted plants, water-pervious sidewalk spaces, and root watering devices to ensure water efficiency and drought resilience.
Operational Impact
Quantitative Benefit
Related Case Studies.
Case Study
Turning A Stadium Into A Smart Building
Honeywell created what it called the “intelligent system” for the National Stadium in Beijing, China, turning the venue for the opening and closing events at the 2008 Summer Olympics into a “smart building.” Designed by highly controversial artist Ai Weiwei, the “Bird’s Nest” remains one of the most impressive feats of stadium architecture in the world. The 250,000 square meter structure housed more than 100,000 athletes and spectators at a time. To accommodate such capacity, China turned to Honeywell’s EBI Integrated Building Management System to create an integrated “intelligent system” for improved building security, safety and energy efficiency.
Case Study
Smart Street Light Network (Copenhagen)
Key stakeholders are taking a comprehensive approach to rethinking smart city innovation. City leaders have collaborated through partnerships involving government, research institutions and solution providers. The Copenhagen Solutions Lab is one of the leading organizations at the forefront of this movement. By bringing together manufacturers with municipal buyers, the Copenhagen Solutions Lab has catalyzed the development and deployment of next-generation smart city innovations. Copenhagen is leveraging this unique approach to accelerate the implementation of smart city solutions. One of the primary focus areas is LED street lighting.
Case Study
IoT System for Tunnel Construction
The Zenitaka Corporation ('Zenitaka') has two major business areas: its architectural business focuses on structures such as government buildings, office buildings, and commercial facilities, while its civil engineering business is targeted at structures such as tunnels, bridges and dams. Within these areas, there presented two issues that have always persisted in regard to the construction of mountain tunnels. These issues are 'improving safety" and "reducing energy consumption". Mountain tunnels construction requires a massive amount of electricity. This is because there are many kinds of electrical equipment being used day and night, including construction machinery, construction lighting, and ventilating fan. Despite this, the amount of power consumption is generally not tightly managed. In many cases, the exact amount of power consumption is only ascertained when the bill from the power company becomes available. Sometimes, corporations install demand-monitoring equipment to help curb the maximum power demanded. However, even in these cases, the devices only allow the total volume of power consumption to be ascertained, or they may issue warnings to prevent the contracted volume of power from being exceeded. In order to tackle the issue of reducing power consumption, it was first necessary to obtain an accurate breakdown of how much power was being used in each particular area. In other words, we needed to be able to visualize the amount of power being consumed. Safety, was also not being managed very rigorously. Even now, tunnel construction sites often use a 'name label' system for managing entry into the work site. Specifically, red labels with white reverse sides that bear the workers' names on both sides are displayed at the tunnel work site entrance. The workers themselves then flip the name label to the appropriate side when entering or exiting from the work site to indicate whether or not they are working inside the tunnel at any given time. If a worker forgets to flip his or her name label when entering or exiting from the tunnel, management cannot be performed effectively. In order to tackle the challenges mentioned above, Zenitaka decided to build a system that could improve the safety of tunnel construction as well as reduce the amount of power consumed. In other words, this new system would facilitate a clear picture of which workers were working in each location at the mountain tunnel construction site, as well as which processes were being carried out at those respective locations at any given time. The system would maintain the safety of all workers while also carefully controlling the electrical equipment to reduce unnecessary power consumption. Having decided on the concept, our next concern was whether there existed any kind of robust hardware that would not break down at the construction work site, that could move freely in response to changes in the working environment, and that could accurately detect workers and vehicles using radio frequency identification (RFID). Given that this system would involve many components that were new to Zenitaka, we decided to enlist the cooperation of E.I.Sol Co., Ltd. ('E.I.Sol') as our joint development partner, as they had provided us with a highly practical proposal.
Case Study
Buoy Status Monitoring with LoRa
The Netherlands are well-known for their inland waterways, canals, sluices and of course port activities. The Dutch Ministry of Infrastructure indicates that there are thousands of buoys and fixed items in and near water environments that would profit from IoT monitoring. One of the problems with buoys for example, is that they get hit by ships and the anchor cable breaks. Without connectivity, it takes quite some time to find out that something has happened with that buoy. Not to mention the costs of renting a boat to go to the buoy to fix it. Another important issue, is that there is no real-time monitoring of the buoys at this moment. Only by physically visiting the object on the water, one gains insight in its status.
Case Study
China Mobile Smart Parking
Smart Parking, powered by NB-IoT technology, is making it easier for drivers to find free parking spots. Cities can better manage their parking assets and maximize the revenue available to them as a result. Drivers searching for parking create congestion and pollution by circling and hunting for available parking. Smart Parking services are able to significantly ease these problems by guiding a driver directly to a parking space.