Literature Reviews

Below, users can build custom reports that include multiple individual research synthesis by selecting one or more mobility technologies or business models and one or more impact areas.

Each individual research synthesis can also be accessed via a matrix view.


Select Transportation Tech.

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On-Demand Delivery Services Definition

Full Page ›

Delivery services, also known as on-demand delivery services, food delivery services or crowdshipping, are a real-time local delivery solution for goods, typically prepared foods, groceries, or other consumer staples. Due to the rapid growth of online shopping, development of emerging technologies, and innovative forms of delivery services, have become more capable of handling a wide range of delivery needs, from small parcels to large-scale freight, with a level of precision and efficiency that was previously unattainable [1].

On demand delivery service businesses use platform technology to connect three parties in a marketplace: 1) a supplier of goods, often a restaurant, and 2) independent contractors or gig workers who can collect, transport, and deliver the goods to 3) a consumer who has ordered the goods.

New technologies such as crowdsourcing, location-based services, electric bikes and scooters, and advanced algorithms have empowered the courier services providers to offer faster, more environmentally friendly, and personalized delivery options to their customers. At the same time, to satisfy customers’ increasing and various demand of delivery services, new service forms are introduced, such as crowdsourced delivery (i.e., distributing delivery services to personal deliver instead of company staff) [2] and cross shipping (i.e., sending parcels to customers through an intermediate point instead of directly) [3].

Delivery services are popular globally, with top markets in China, the United States, and India [4]. Top companies in the United States are UberEats, and DoorDash [5].

A new trend in on-demand delivery service is to use robotic delivery services. The demand for robotic delivery services has increased quickly due to the technology development, challenges from traditional human delivery, and rising requests for contactless deliveries during COVID-19 [6]. As of 2021, cities located in 18 states in the US [7] had launched their robotic delivery pilot programs, such as Los Angeles, CA [8], Pittsburgh, Pennsylvania [9], and Redwood City, California [10]. The governments collaborate with emerging tech companies, including Uber, Starship, Kiwibot, Cruise, and so on. However, most of the programs are operating in small areas, indicating the experimental phase of these initiatives and the challenges in scaling up to wider service areas. When these systems are deployed at scale, several scenarios of concern and necessary considerations arise. Firstly, robotic delivery units could congest sidewalks, reducing accessibility for pedestrians and other users. This might require new urban planning strategies and dedicated pathways to ensure safe coexistence. Secondly, their widespread use could alter urban form and infrastructure, prompting cities to redesign pedestrian zones and potentially repurpose existing spaces.

References

  1. A. Rutter, D. Bierling, D. Lee, C. Morgan, and J. Warner, “How Will E-commerce Growth Impact Our Transportation Network,” PRC 17-79 F. Accessed: May 13, 2024. [Online]. Available: https://static.tti.tamu.edu/tti.tamu.edu/documents/PRC-17-79-F.pdf

  2. A. Alnaggar, F. Gzara, and J. H. Bookbinder, “Crowdsourced delivery: A review of platforms and academic literature,” Omega, vol. 98, p. 102139, Jan. 2021, doi: 10.1016/j.omega.2019.102139.

  3. A. I. Nikolopoulou, P. P. Repoussis, C. D. Tarantilis, and E. E. Zachariadis, “Moving products between location pairs: Cross-docking versus direct-shipping,” Eur. J. Oper. Res., vol. 256, no. 3, pp. 803–819, Feb. 2017, doi: 10.1016/j.ejor.2016.06.053.

  4. C. Li, M. Mirosa, and P. Bremer, “Review of Online Food Delivery Platforms and their Impacts on Sustainability,” Sustainability, vol. 12, no. 14, Art. no. 14, Jan. 2020, doi: 10.3390/su12145528.

  5. M. Kaczmarski, “Which company is winning the restaurant food delivery war?,” Bloomberg Second Measure. Accessed: Apr. 02, 2024. [Online]. Available: https://secondmeasure.com/datapoints/food-delivery-services-grubhub-uber-eats-doordash-postmates/

  6. S. Srinivas, S. Ramachandiran, and S. Rajendran, “Autonomous robot-driven deliveries: A review of recent developments and future directions,” Transp. Res. Part E Logist. Transp. Rev., vol. 165, p. 102834, Sep. 2022, doi: 10.1016/j.tre.2022.102834.

  7. Minnesota department of Transportation, “Personal Delivery Devices.” Accessed: May 13, 2024. [Online]. Available: https://dot.state.mn.us/automated/docs/personal-delivery-device-white-paper.pdf

  8. J. Fantozzi, “Uber launches delivery robot pilot program; adds Google voice ordering,” Nation’s Restaurant News. Accessed: May 13, 2024. [Online]. Available: https://www.nrn.com/technology/uber-launches-delivery-robot-pilot-program-adds-google-voice-ordering

  9. City of Pittsburgh Mobility and Infrastructure, “2021 Personal Delivery Device Final Pilot Evaluation.” Accessed: May 13, 2024. [Online]. Available: https://hdp-us-prod-app-pgh-engage-files.s3.us-west 2.amazonaws.com/9616/5540/2948/PDD_Final_Pilot_Evaluation_v2.pdf

  10. Staff, “Redwood City council renews pilot program for autonomous robot deliveries,” Climate Online. Accessed: May 13, 2024. [Online]. Available: https://climaterwc.com/2019/05/13/autonomous-robot-deliveries-returning-to-redwood-city-as-pilot-project/

How On-Demand Delivery Services affects Land Use

Full Page ›

The expansion of on-demand delivery services has been made possible by ghost kitchens and dark stores – grocery fulfillment centers which are located near consumers but are not open to customers [1]. These fulfillment centers have created new real estate opportunities. Several major ghost kitchen operators are known for building large portfolios out of warehouses, empty strip malls, or other storefronts near areas with growing on-demand food-delivery markets [1]. Restaurants are dispersing away from ground-floor locations in popular retail districts as ghost kitchens increase their urban real estate [1], [2].

One emerging area of study is the impact of on-demand delivery services on restaurant formation and viability. The services charge participating restaurants delivery fees as high as 30 percent of order value, though some cities have imposed caps of 15 percent [3].

How On-Demand Delivery Services affects Health

Full Page ›

A scoping review of public health impacts from on demand food and alcohol delivery published in SSM Population Health found that on-demand delivery services increase geographical access to food but tend to market unhealthy and discretionary foods, and are likely increasing existing health issues and inequities [1]. The review also highlighted concerns over poor age verification processes potentially allowing minors to access alcohol more easily [1].

How On-Demand Delivery Services affects Energy and Environment

Full Page ›

A shift from dining in to at-home consumption can produce additional food packaging waste [1]. On-demand meal delivery may also affect travel activity, potentially increasing emissions. A study of delivery data in London, United Kingdom found that meal delivery by vehicle is “highly energy inefficient, producing 11 times more GHG [greenhouse gas emissions] per meal delivered by vehicle than by bicycle” [2]. However, this study did not identify if any travel activity was displaced by the substitution of meal delivery services; future research could explore if customers order from locations further away or substitute meal delivery for home cooking, activities that would increase energy consumption and resultant emissions. Policies to support bicycle use for delivery services can mitigate these increases [3], [4].

For robotic delivery services, the literature shows that the energy consumption and emissions of robotic delivery services do not necessarily outperform traditional ones, and are related to delivery distance, electrification, and operation [1], [5], [6].

How On-Demand Delivery Services affects Municipal Budgets

Full Page ›

While delivery service may impact wages and establishment creation, a review of the literature found no studies that considered impacts to municipal revenue through effects on municipal expenses, tax revenue, or nearby businesses.

No references found

How On-Demand Delivery Services affects Transportation Systems Operations (and Efficiency)

Full Page ›

On-demand delivery services have been shown to have a significant impact on transportation systems, both positively and negatively [1]. On the positive side, modern delivery services could reduce shopping trips to physical stores and related energy consumption [2] and greenhouse gas emissions [3]. Emissions from delivery services vary based on delivery scheduling [4], service coverage area [5], engine type (e.g., combustion or electric), and efficiency of cooling equipment [6]. On the negative side, the increasing number of delivery vehicles adds to crash risk in the transportation system, particularly for road users [7]. In addition, the delivery vehicles compete for limited curbside space in the urban area [8], [9].

Research on the impact of robotic delivery services on transportation systems is predominantly theoretical, due to scarce empirical evidence. The City of Pittsburgh [10] operated a six-month pilot program with Kiwibot and deployed a limited number of devices (less than 10 at any time) to deliver packages. Different from package delivery robots, which mostly operate on sidewalks and have a limited influence on the road traffic, future autonomous delivery vehicles could exert a huge impact on the traffic systems. Studies showed mixed results about the effects of autonomous vehicles on traffic flow efficiency, both positive and negative, depending on their modeling conditions [11].

  1. J. Visser, T. Nemoto, and M. Browne, “Home Delivery and the Impacts on Urban Freight Transport: A Review,” Procedia – Soc. Behav. Sci., vol. 125, pp. 15–27, Mar. 2014, doi: 10.1016/j.sbspro.2014.01.1452.

  2. M. Stinson, A. Enam, A. Moore, and J. Auld, “Citywide Impacts of E-Commerce: Does Parcel Delivery Travel Outweigh Household Shopping Travel Reductions?,” in Proceedings of the 2nd ACM/EIGSCC Symposium on Smart Cities and Communities, Portland OR USA: ACM, Sep. 2019, pp. 1–7. doi: 10.1145/3357492.3358633.

  3. H. Siikavirta, M. Punakivi, M. Kärkkäinen, and L. Linnanen, “Effects of E‐Commerce on Greenhouse Gas Emissions: A Case Study of Grocery Home Delivery in Finland,” J. Ind. Ecol., vol. 6, no. 2, pp. 83–97, Apr. 2002, doi: 10.1162/108819802763471807.

  4. Y. Yu, J. Tang, J. Li, W. Sun, and J. Wang, “Reducing carbon emission of pickup and delivery using integrated scheduling,” Transp. Res. Part Transp. Environ., vol. 47, pp. 237–250, Aug. 2016, doi: 10.1016/j.trd.2016.05.011.

  5. J. C. Velázquez-Martínez, J. C. Fransoo, E. E. Blanco, and K. B. Valenzuela-Ocaña, “A new statistical method of assigning vehicles to delivery areas for CO2 emissions reduction,” Transp. Res. Part Transp. Environ., vol. 43, pp. 133–144, Mar. 2016, doi: 10.1016/j.trd.2015.12.009.

  6. C. Siragusa, A. Tumino, R. Mangiaracina, and A. Perego, “Electric vehicles performing last-mile delivery in B2C e-commerce: An economic and environmental assessment,” Int. J. Sustain. Transp., vol. 16, no. 1, pp. 22–33, Jan. 2022, doi: 10.1080/15568318.2020.1847367.

  7. Y. He, C. Sun, and F. Chang, “The road safety and risky behavior analysis of delivery vehicle drivers in China,” Accid. Anal. Prev., vol. 184, p. 107013, May 2023, doi: 10.1016/j.aap.2023.107013.

  8. J. Liu, W. Ma, and S. Qian, “Optimal curbside pricing for managing ride-hailing pick-ups and drop-offs,” Transp. Res. Part C Emerg. Technol., vol. 146, p. 103960, Jan. 2023, doi: 10.1016/j.trc.2022.103960.

  9. X. Liu, S. Qian, H.-H. Teo, and W. Ma, “Estimating and Mitigating the Congestion Effect of Curbside Pick-ups and Drop-offs: A Causal Inference Approach,” 2022, doi: 10.48550/ARXIV.2206.02164.

  10. City of Pittsburgh Mobility and Infrastructure, “2021 Personal Delivery Device Final Pilot Evaluation.” Accessed: May 13, 2024. [Online]. Available: https://hdp-us-prod-app-pgh-engage-files.s3.us-west-2.amazonaws.com/9616/5540/2948/PDD_Final_Pilot_Evaluation_v2.pdf

  11. S. Narayanan, E. Chaniotakis, and C. Antoniou, “Chapter One – Factors affecting traffic flow efficiency implications of connected and autonomous vehicles: A review and policy recommendations,” in Advances in Transport Policy and Planning, vol. 5, D. Milakis, N. Thomopoulos, and B. van Wee, Eds., in Policy Implications of Autonomous Vehicles, vol. 5. , Academic Press, 2020, pp. 1–50. doi: 10.1016/bs.atpp.2020.02.004.

How On-Demand Delivery Services affects Education and Workforce

Full Page ›

Ghost kitchens, or restaurants without dining space that focus on online food orders, can reduce overhead costs from front-of-house staff and single-facility expenses [1]). This may affect the demand for hospitality workers and food service establishments in a jurisdiction.

One workforce-related concern for gig economy workers, who are independent contractors, is that they will be exploited if they become overly-dependent on a single platform [2] . Delivery service workers can increase their revenues by strategically switching between services (known as multihoming) and repositioning their locations to areas of high demand [3].

On-Demand Delivery Services can provide ride hail drivers with an alternative platform for gig work, and ride hail and delivery platforms must compete for workers, as Liu and Li [4] illustrate below:

How On-Demand Delivery Services affects Social Equity

Full Page ›

A review of the literature yielded no social equity concerns that were independent of workforce-related issues. Those issues are covered under the heading “Education and Workforce.”

No references found

How On-Demand Delivery Services affects Safety

Full Page ›

On-demand delivery services can lead to an increase in demand for curb space, leading to congestion and double parking which can pose safety risks to pedestrians and other curb users [1], [2]. Existing research primarily considers the impacts of ride-hail/transportation network companies (TNCs) on demand for curb space and associated safety impacts [2]. Common TNC traffic violations that impact safety include not yielding to pedestrians or obstructing public transit lanes and driveways, which can cause other drivers or travelers to move into less safe areas [2]. Study on the safety impacts unique to on-demand delivery service may not be needed.

From limited observations of robotic delivery services in the City of Pittsburgh, there were only 17 incidents involving vehicles or pedestrians reported throughout the program. However, the limited number of devices deployed makes it challenging to ensure their safety at larger scales [3].

Note: Mobility COE research partners conducted this literature review in Spring of 2024 based on research available at the time. Unless otherwise noted, this content has not been updated to reflect newer research.

On-Demand Delivery Services Definition

Full Page ›

Delivery services, also known as on-demand delivery services, food delivery services or crowdshipping, are a real-time local delivery solution for goods, typically prepared foods, groceries, or other consumer staples. Due to the rapid growth of online shopping, development of emerging technologies, and innovative forms of delivery services, have become more capable of handling a wide range of delivery needs, from small parcels to large-scale freight, with a level of precision and efficiency that was previously unattainable [1].

On demand delivery service businesses use platform technology to connect three parties in a marketplace: 1) a supplier of goods, often a restaurant, and 2) independent contractors or gig workers who can collect, transport, and deliver the goods to 3) a consumer who has ordered the goods.

New technologies such as crowdsourcing, location-based services, electric bikes and scooters, and advanced algorithms have empowered the courier services providers to offer faster, more environmentally friendly, and personalized delivery options to their customers. At the same time, to satisfy customers’ increasing and various demand of delivery services, new service forms are introduced, such as crowdsourced delivery (i.e., distributing delivery services to personal deliver instead of company staff) [2] and cross shipping (i.e., sending parcels to customers through an intermediate point instead of directly) [3].

Delivery services are popular globally, with top markets in China, the United States, and India [4]. Top companies in the United States are UberEats, and DoorDash [5].

A new trend in on-demand delivery service is to use robotic delivery services. The demand for robotic delivery services has increased quickly due to the technology development, challenges from traditional human delivery, and rising requests for contactless deliveries during COVID-19 [6]. As of 2021, cities located in 18 states in the US [7] had launched their robotic delivery pilot programs, such as Los Angeles, CA [8], Pittsburgh, Pennsylvania [9], and Redwood City, California [10]. The governments collaborate with emerging tech companies, including Uber, Starship, Kiwibot, Cruise, and so on. However, most of the programs are operating in small areas, indicating the experimental phase of these initiatives and the challenges in scaling up to wider service areas. When these systems are deployed at scale, several scenarios of concern and necessary considerations arise. Firstly, robotic delivery units could congest sidewalks, reducing accessibility for pedestrians and other users. This might require new urban planning strategies and dedicated pathways to ensure safe coexistence. Secondly, their widespread use could alter urban form and infrastructure, prompting cities to redesign pedestrian zones and potentially repurpose existing spaces.

References

  1. A. Rutter, D. Bierling, D. Lee, C. Morgan, and J. Warner, “How Will E-commerce Growth Impact Our Transportation Network,” PRC 17-79 F. Accessed: May 13, 2024. [Online]. Available: https://static.tti.tamu.edu/tti.tamu.edu/documents/PRC-17-79-F.pdf

  2. A. Alnaggar, F. Gzara, and J. H. Bookbinder, “Crowdsourced delivery: A review of platforms and academic literature,” Omega, vol. 98, p. 102139, Jan. 2021, doi: 10.1016/j.omega.2019.102139.

  3. A. I. Nikolopoulou, P. P. Repoussis, C. D. Tarantilis, and E. E. Zachariadis, “Moving products between location pairs: Cross-docking versus direct-shipping,” Eur. J. Oper. Res., vol. 256, no. 3, pp. 803–819, Feb. 2017, doi: 10.1016/j.ejor.2016.06.053.

  4. C. Li, M. Mirosa, and P. Bremer, “Review of Online Food Delivery Platforms and their Impacts on Sustainability,” Sustainability, vol. 12, no. 14, Art. no. 14, Jan. 2020, doi: 10.3390/su12145528.

  5. M. Kaczmarski, “Which company is winning the restaurant food delivery war?,” Bloomberg Second Measure. Accessed: Apr. 02, 2024. [Online]. Available: https://secondmeasure.com/datapoints/food-delivery-services-grubhub-uber-eats-doordash-postmates/

  6. S. Srinivas, S. Ramachandiran, and S. Rajendran, “Autonomous robot-driven deliveries: A review of recent developments and future directions,” Transp. Res. Part E Logist. Transp. Rev., vol. 165, p. 102834, Sep. 2022, doi: 10.1016/j.tre.2022.102834.

  7. Minnesota department of Transportation, “Personal Delivery Devices.” Accessed: May 13, 2024. [Online]. Available: https://dot.state.mn.us/automated/docs/personal-delivery-device-white-paper.pdf

  8. J. Fantozzi, “Uber launches delivery robot pilot program; adds Google voice ordering,” Nation’s Restaurant News. Accessed: May 13, 2024. [Online]. Available: https://www.nrn.com/technology/uber-launches-delivery-robot-pilot-program-adds-google-voice-ordering

  9. City of Pittsburgh Mobility and Infrastructure, “2021 Personal Delivery Device Final Pilot Evaluation.” Accessed: May 13, 2024. [Online]. Available: https://hdp-us-prod-app-pgh-engage-files.s3.us-west 2.amazonaws.com/9616/5540/2948/PDD_Final_Pilot_Evaluation_v2.pdf

  10. Staff, “Redwood City council renews pilot program for autonomous robot deliveries,” Climate Online. Accessed: May 13, 2024. [Online]. Available: https://climaterwc.com/2019/05/13/autonomous-robot-deliveries-returning-to-redwood-city-as-pilot-project/

How On-Demand Delivery Services affects Land Use

Full Page ›

The expansion of on-demand delivery services has been made possible by ghost kitchens and dark stores – grocery fulfillment centers which are located near consumers but are not open to customers [1]. These fulfillment centers have created new real estate opportunities. Several major ghost kitchen operators are known for building large portfolios out of warehouses, empty strip malls, or other storefronts near areas with growing on-demand food-delivery markets [1]. Restaurants are dispersing away from ground-floor locations in popular retail districts as ghost kitchens increase their urban real estate [1], [2].

One emerging area of study is the impact of on-demand delivery services on restaurant formation and viability. The services charge participating restaurants delivery fees as high as 30 percent of order value, though some cities have imposed caps of 15 percent [3].

How On-Demand Delivery Services affects Health

Full Page ›

A scoping review of public health impacts from on demand food and alcohol delivery published in SSM Population Health found that on-demand delivery services increase geographical access to food but tend to market unhealthy and discretionary foods, and are likely increasing existing health issues and inequities [1]. The review also highlighted concerns over poor age verification processes potentially allowing minors to access alcohol more easily [1].

How On-Demand Delivery Services affects Energy and Environment

Full Page ›

A shift from dining in to at-home consumption can produce additional food packaging waste [1]. On-demand meal delivery may also affect travel activity, potentially increasing emissions. A study of delivery data in London, United Kingdom found that meal delivery by vehicle is “highly energy inefficient, producing 11 times more GHG [greenhouse gas emissions] per meal delivered by vehicle than by bicycle” [2]. However, this study did not identify if any travel activity was displaced by the substitution of meal delivery services; future research could explore if customers order from locations further away or substitute meal delivery for home cooking, activities that would increase energy consumption and resultant emissions. Policies to support bicycle use for delivery services can mitigate these increases [3], [4].

For robotic delivery services, the literature shows that the energy consumption and emissions of robotic delivery services do not necessarily outperform traditional ones, and are related to delivery distance, electrification, and operation [1], [5], [6].

How On-Demand Delivery Services affects Municipal Budgets

Full Page ›

While delivery service may impact wages and establishment creation, a review of the literature found no studies that considered impacts to municipal revenue through effects on municipal expenses, tax revenue, or nearby businesses.

No references found

How On-Demand Delivery Services affects Transportation Systems Operations (and Efficiency)

Full Page ›

On-demand delivery services have been shown to have a significant impact on transportation systems, both positively and negatively [1]. On the positive side, modern delivery services could reduce shopping trips to physical stores and related energy consumption [2] and greenhouse gas emissions [3]. Emissions from delivery services vary based on delivery scheduling [4], service coverage area [5], engine type (e.g., combustion or electric), and efficiency of cooling equipment [6]. On the negative side, the increasing number of delivery vehicles adds to crash risk in the transportation system, particularly for road users [7]. In addition, the delivery vehicles compete for limited curbside space in the urban area [8], [9].

Research on the impact of robotic delivery services on transportation systems is predominantly theoretical, due to scarce empirical evidence. The City of Pittsburgh [10] operated a six-month pilot program with Kiwibot and deployed a limited number of devices (less than 10 at any time) to deliver packages. Different from package delivery robots, which mostly operate on sidewalks and have a limited influence on the road traffic, future autonomous delivery vehicles could exert a huge impact on the traffic systems. Studies showed mixed results about the effects of autonomous vehicles on traffic flow efficiency, both positive and negative, depending on their modeling conditions [11].

  1. J. Visser, T. Nemoto, and M. Browne, “Home Delivery and the Impacts on Urban Freight Transport: A Review,” Procedia – Soc. Behav. Sci., vol. 125, pp. 15–27, Mar. 2014, doi: 10.1016/j.sbspro.2014.01.1452.

  2. M. Stinson, A. Enam, A. Moore, and J. Auld, “Citywide Impacts of E-Commerce: Does Parcel Delivery Travel Outweigh Household Shopping Travel Reductions?,” in Proceedings of the 2nd ACM/EIGSCC Symposium on Smart Cities and Communities, Portland OR USA: ACM, Sep. 2019, pp. 1–7. doi: 10.1145/3357492.3358633.

  3. H. Siikavirta, M. Punakivi, M. Kärkkäinen, and L. Linnanen, “Effects of E‐Commerce on Greenhouse Gas Emissions: A Case Study of Grocery Home Delivery in Finland,” J. Ind. Ecol., vol. 6, no. 2, pp. 83–97, Apr. 2002, doi: 10.1162/108819802763471807.

  4. Y. Yu, J. Tang, J. Li, W. Sun, and J. Wang, “Reducing carbon emission of pickup and delivery using integrated scheduling,” Transp. Res. Part Transp. Environ., vol. 47, pp. 237–250, Aug. 2016, doi: 10.1016/j.trd.2016.05.011.

  5. J. C. Velázquez-Martínez, J. C. Fransoo, E. E. Blanco, and K. B. Valenzuela-Ocaña, “A new statistical method of assigning vehicles to delivery areas for CO2 emissions reduction,” Transp. Res. Part Transp. Environ., vol. 43, pp. 133–144, Mar. 2016, doi: 10.1016/j.trd.2015.12.009.

  6. C. Siragusa, A. Tumino, R. Mangiaracina, and A. Perego, “Electric vehicles performing last-mile delivery in B2C e-commerce: An economic and environmental assessment,” Int. J. Sustain. Transp., vol. 16, no. 1, pp. 22–33, Jan. 2022, doi: 10.1080/15568318.2020.1847367.

  7. Y. He, C. Sun, and F. Chang, “The road safety and risky behavior analysis of delivery vehicle drivers in China,” Accid. Anal. Prev., vol. 184, p. 107013, May 2023, doi: 10.1016/j.aap.2023.107013.

  8. J. Liu, W. Ma, and S. Qian, “Optimal curbside pricing for managing ride-hailing pick-ups and drop-offs,” Transp. Res. Part C Emerg. Technol., vol. 146, p. 103960, Jan. 2023, doi: 10.1016/j.trc.2022.103960.

  9. X. Liu, S. Qian, H.-H. Teo, and W. Ma, “Estimating and Mitigating the Congestion Effect of Curbside Pick-ups and Drop-offs: A Causal Inference Approach,” 2022, doi: 10.48550/ARXIV.2206.02164.

  10. City of Pittsburgh Mobility and Infrastructure, “2021 Personal Delivery Device Final Pilot Evaluation.” Accessed: May 13, 2024. [Online]. Available: https://hdp-us-prod-app-pgh-engage-files.s3.us-west-2.amazonaws.com/9616/5540/2948/PDD_Final_Pilot_Evaluation_v2.pdf

  11. S. Narayanan, E. Chaniotakis, and C. Antoniou, “Chapter One – Factors affecting traffic flow efficiency implications of connected and autonomous vehicles: A review and policy recommendations,” in Advances in Transport Policy and Planning, vol. 5, D. Milakis, N. Thomopoulos, and B. van Wee, Eds., in Policy Implications of Autonomous Vehicles, vol. 5. , Academic Press, 2020, pp. 1–50. doi: 10.1016/bs.atpp.2020.02.004.

How On-Demand Delivery Services affects Education and Workforce

Full Page ›

Ghost kitchens, or restaurants without dining space that focus on online food orders, can reduce overhead costs from front-of-house staff and single-facility expenses [1]). This may affect the demand for hospitality workers and food service establishments in a jurisdiction.

One workforce-related concern for gig economy workers, who are independent contractors, is that they will be exploited if they become overly-dependent on a single platform [2] . Delivery service workers can increase their revenues by strategically switching between services (known as multihoming) and repositioning their locations to areas of high demand [3].

On-Demand Delivery Services can provide ride hail drivers with an alternative platform for gig work, and ride hail and delivery platforms must compete for workers, as Liu and Li [4] illustrate below:

How On-Demand Delivery Services affects Social Equity

Full Page ›

A review of the literature yielded no social equity concerns that were independent of workforce-related issues. Those issues are covered under the heading “Education and Workforce.”

No references found

How On-Demand Delivery Services affects Safety

Full Page ›

On-demand delivery services can lead to an increase in demand for curb space, leading to congestion and double parking which can pose safety risks to pedestrians and other curb users [1], [2]. Existing research primarily considers the impacts of ride-hail/transportation network companies (TNCs) on demand for curb space and associated safety impacts [2]. Common TNC traffic violations that impact safety include not yielding to pedestrians or obstructing public transit lanes and driveways, which can cause other drivers or travelers to move into less safe areas [2]. Study on the safety impacts unique to on-demand delivery service may not be needed.

From limited observations of robotic delivery services in the City of Pittsburgh, there were only 17 incidents involving vehicles or pedestrians reported throughout the program. However, the limited number of devices deployed makes it challenging to ensure their safety at larger scales [3].

Note: Mobility COE research partners conducted this literature review in Spring of 2024 based on research available at the time. Unless otherwise noted, this content has not been updated to reflect newer research.