RESEARCH QUESTIONS

The Covid-19 pandemic has rekindled interest in teleworking as a potentially promising work arrangement. A preferred protective option as long as the virus cannot be contained (Baert et al. 2020), teleworking can also serve in the long term as a viable strategy for Transportation Demand Management (TDM) and specifically for Commuting Trip Reduction (CTR) (Hook et al. 2020). While the effects of CTR on transportation efficiency and environmental benefits of CTR are well known, those of working from home (WFH) on work productivity remain under-researched (Kazekami 2020; Nakrošienė, Bučiūnienė, and Goštautaitė 2019; Neufeld and Fang 2005; Ruth and Chaudhry 2008; Aboelmaged and El Subbaugh 2012; Pigini and Staffolani 2019). This study took advantage of a recent WFH policy, which acted as a natural experiment to learn about personal factors associated with “successfully” WFH. A survey administered around Seattle, Washington, aimed to identify the characteristics of people more suited to WFH so that a portion of the Covid-19 WFH population might continue to do so after Covid-19, which would contribute to TDM and CTR outcomes while maintaining workforce productivity (Organisation for Economic Co-operation and Development (OECD) 2020). Specific questions focused on:

  1. The socioeconomic characteristics (SES) and commuting patterns of the population that continued to be productive during Covid-19 WFH

  2. The lifestyle changes that helped the WFH population continue to be productive while teleworking

METHODS AND DATA

Study and Survey Design

We conducted the survey between April and June 2020 in the four counties of the central Puget Sound (Seattle) region, Washington, and asked participants about changes in their work productivity, daily routines, and mental wellbeing since WFH during Covid-19. We used convenience sampling, with a target population of adults older than 18 living in the region’s four counties. The survey was managed online and distributed through professional email lists of public agencies, non-government organizations, universities and colleges, as well as other public community groups. There was no financial incentive for participation. We obtained responses from 2174 adults from 83% of the ZIP Codes in the four counties, who had shifted from working away to WFH since Covid-19. Compared to central Puget Sound region general population, 69% of our participants had a household income higher than the region’s median; 67% were female (50% in the region) and 52% had graduate degrees or above (32% in the region) (Table 1). Detailed information on the survey was documented elsewhere (Puget Sound Regional Council 2020).

Table 1.Characteristics of participants, their SES, prior commute trip patterns, mental wellbeing status, lifestyle changes since Covid-19 (N=2174)
Outcome Education *
Variables Descriptive Statistics High school or 2yr college 251 (11.5%)
Productivity (outcome) 4yr college 777 (35.7%)
Less productive 839 (38.6%) Graduate or post graduate 1129 (51.9%)
No change 817 (37.6%) Not applicable 17 (0.8%)
More productive 518 (23.8%)
Housing status *
Domain: SES Own 1411 (64.9%)
Variables Descriptive Statistics Sig.1 Rent 715 (32.9%)
Age * Not applicable 48 (2.2%)
18 to 29 389 (17.9%)
30 to 39 538 (24.7%) Living arrangement *
40 to 49 455 (20.9%) Partner 876 (40.3%)
50 to 59 483 (22.2%) Live alone 316 (14.5%)
60 and above 306 (14.1%) Friends & relatives 308 (14.2%)
Not applicable 3 (0.1%) Children 619 (28.5%)
Not applicable 55 (2.5%)
Gender
Female 1499 (69.0%) Dog ownership
Male 646 (29.7%) Yes 756 (34.8%)
Other 29 (1.3%) No 1418 (65.2%)
 
Income * Vehicle ownership
below 40k 145 (6.7%) Yes 2029 (93.3%)
[40k-90k) 478 (22.0%) No 145 (6.7%)
[90k-150k) 757 (34.8%)
above 150k 735 (33.8%) Domain: mental wellbeing
Not applicable 59 (2.7%) Variables Descriptive Statistics Sig.
Depression measure *
Employment * Mean (SD) 1.45 (1.48)
Professional 1178 (54.2%) Median [Min, Max] 1.00 [0, 6]
Student 249 (11.5%)
Faculty 122 (5.6%) Anxiety measure *
Staff 444 (20.4%) Mean (SD) 4.02 (4.14)
Business person 131 (6.0%) Median [Min, Max] 3.00 [0, 24]
Others 50 (2.3%)
 

Note 1 – significant in univariate models.

Table 1 (continued). Characteristics of participants, their SES, prior commute trip patterns, mental wellbeing status, lifestyle changes since Covid-19 (N=2174)
Domain: lifestyle changes Domain: previous commute trip duration (one-way trip) by mode
Variables Descriptive Statistics Sig. Variables Descriptive Statistics Sig.
Sleep quality * Walking *
1-Decreased a lot 216 (9.9%) 0-do not use 1603 (73.7%)
2-Decreased somewhat 654 (30.1%) 1-<15min 235 (10.8%)
3-No change 820 (37.7%) 2-16 to 30min 179 (8.2%)
4-Increased somewhat 384 (17.7%) 3-31 to 45min 80 (3.7%)
5-Increased a lot 97 (4.5%) 4-45 to 60min 43 (2.0%)
Not applicable 3 (0.1%) 5->1hr 34 (1.6%)
Amount of food consumption Biking
1-Decreased a lot 21 (1.0%) 0-do not use 1877 (86.3%)
2-Decreased somewhat 258 (11.9%) 1-<15min 54 (2.5%)
3-No change 1060 (48.8%) 2-16 to 30min 109 (5.0%)
4-Increased somewhat 738 (33.9%) 3-31 to 45min 63 (2.9%)
5-Increased a lot 97 (4.5%) 4-45 to 60min 46 (2.1%)
Not applicable 0 (0%) 5->1hr 25 (1.1%)
Amount of exercise * Transit *
1-Decreased a lot 567 (26.1%) 0- do not use 1018 (46.8%)
2-Decreased somewhat 552 (25.4%) 1-<15min 92 (4.2%)
3-No change 297 (13.7%) 2-16 to 30min 299 (13.8%)
4-Increased somewhat 542 (24.9%) 3-31 to 45min 297 (13.7%)
5-Increased a lot 207 (9.5%) 4-45 to 60min 296 (13.6%)
Not applicable 9 (0.4%) 5->1hr 172 (7.9%)
Time on social media * Single Occupancy Vehicle (SOV) *
1-Decreased a lot 23 (1.1%) 0- do not use 946 (43.5%)
2-Decreased somewhat 76 (3.5%) 1-<15min 300 (13.8%)
3-No change 828 (38.1%) 2-16 to 30min 435 (20.0%)
4-Increased somewhat 781 (35.9%) 3-31 to 45min 278 (12.8%)
5-Increased a lot 293 (13.5%) 4-45 to 60min 146 (6.7%)
Not applicable 173 (8.0%) 5->1hr 69 (3.2%)
Time on personal hobby * High Occupancy Vehicle (HOV)
1-Decreased a lot 118 (5.4%) 0- do not use 1882 (86.6%)
2-Decreased somewhat 194 (8.9%) 1-<15min 62 (2.9%)
3-No change 862 (39.7%) 2-16 to 30min 90 (4.1%)
4-Increased somewhat 701 (32.2%) 3-31 to 45min 78 (3.6%)
5-Increased a lot 193 (8.9%) 4-45 to 60min 40 (1.8%)
Not applicable 106 (4.9%) 5->1hr 22 (1.0%)

Variables

The unit of analysis was the participant. The outcome of interest was self-reported change in productivity since WFH. Participants were given three options: no change, a decrease or an increase in productivity. Productivity was treated as an ordinal variable with decrease in productivity as the reference. Hypothesized predictors of productivity change came from four domains: socioeconomic status (SES), previous commute trip mode and duration, lifestyle changes (sleep quality, food consumption, amount of exercise, time spent on social media or personal hobby), and mental wellbeing. Mental wellbeing variables served to control for potential effects on people caused by Covid-19 circumstances. To evaluate depression, we used two questions from the Patient Health Questionnaire (PHQ-2, (Kroenke, Spitzer, and Williams 2003): how often participants felt depressed or had little interest in doing things on a 4-point Likert scale (0 = Not at all; 1 = Several days; 2 = More than half the days; 3 = Nearly every day). To evaluate anxiety, we used 6 questions from the Brief Symptom Inventory (BSI, (Derogatis and Melisaratos 1983) on a 5-point Likert scale (0=Not at all, 1=A little bit, 2=Moderately, 3=Quite a bit, 4=Extremely). Depression and anxiety measures were indexed by summing all scaled question results, with higher scores indicating higher levels of perceived depression (range = 0 to 6) or anxiety (range = 0 to 24). The details of the method can be found elsewhere and both measures have been tested for validity in previous studies (Cohen-Cline, Turkheimer, and Duncan 2015; Duncan et al. 2020). Table 1 shows how the variables were coded.

Statistical Analysis

Partial proportional odds (PPO) models, also referred to as generalized ordered logit models were used in the analysis, which relax the parallel line assumption for variables having different relations with each pair of ordinal outcome groups (Williams 2016). Brant test was used to screen the variables that did not meet the assumption. In PPO models, for variables that met the parallel assumption, one set of coefficients were estimated; while for others, two coefficients corresponding to decrease vs. no change and no change vs. increase were estimated separately. We first tested univariate models for all hypothesized predictors. A full PPO model was then estimated with all the predictors significant in univariate models. A final, reduced model included only the variables that had remained significant in the full model (Table 2, Figure 1). VIF scores showed no issue with collinearity. For each model, we used listwise deletion where only observations with complete information were included.

Table 2.Association between reported productivity, SES, mental wellbeing, previous commute trip mode and duration, and lifestyle changes (N=1846)
Reduced Model1
Dependent Variable: Productivity (decrease [ref.], no change, increase)
Domains Predictors OR 95% CI p
SES Age
•   18 to 29 0.48 0.33 – 0.69 <0.001
•   30 to 39 0.93 0.68 – 1.27 0.655
•   40 to 49 1.10 0.79 – 1.31 0.573
•   50 to 59 1.00 0.73 – 1.37 0.988
•   60 and above Reference
Employment
•   professionals Reference
•   student 0.41 0.28 – 0.59 <0.001
•   faculty 0.47 0.30 – 0.72 0.001
•   staff 0.76 0.61 – 0.95 0.017
•   business person 0.77 0.53 – 1.12 0.176
•   others 0.99 0.56 – 1.72 0.961
Education
•   high school or 2yr college 1.32 0.98 – 1.79 0.072
•   4yr college 1.36 1.11 – 1.66 0.003
•   graduate and above Reference
Living arrangement
•   partner Reference
•   live alone 0.96 0.73 – 1.25 0.756
•   friends & relatives 1.18 0.88 – 1.57 0.263
•   children 0.63 0.50 – 0.80 <0.001
 
Previous Commuting
Trip Mode and Duration 		Walking 0.90 0.83 – 0.98 0.022
SOV 1.14 1.07 – 1.22 <0.001
 
Lifestyle Changes Sleep quality 1.19 1.08 – 1.31 <0.001
Time on social media 0.84 0.75 – 0.94 0.002
Time on personal hobby2
•   (Decrease vs. No change) 1.10 0.98 – 1.22 0.074
•   (No change vs. Increase) 1.24 1.08 – 1.39 0.001
Mental Wellbeing Depression measure 0.83 0.79 – 0.91 <0.001
Anxiety measure2
•   (Decrease vs. No change) 1.00 0.97 – 1.03 0.855
•   (No change vs. Increase) 1.05 1.02 – 1.09 0.001
Log-likelihood -1825.94

Note 1 – This reduced PPO model excluded variables that were not significant in the full model (income, house ownership, transit trip duration, amount of exercise)
Note 2 – In the PPO model, variables violating the parallel line assumption (time on personal hobby and anxiety measure) were estimated with coefficients for each pair of ordinal outcome groups.

Figure 1
Figure 1.Odds ratio and 95% confidence interval of factors associated with no change or increase in productivity

FINDINGS

Change in productivity since teleworking

Of the 2147 survey respondents, 38% reported being less productive since shifting to WFH; 37.6% reported having no change; and 23.8% reported being more productive than prior to teleworking (Table 1). The WFH arrangement, which respondents worked under between April and June 2020 mandated telecommuting every workday, which is a more restricted condition than most WFH where workers may have more choices regarding the number of days and times of teleworking. All these conditions may affect the productivity of WFH.

Domains of influence on teleworking productivity

SES

After controlling for mental status, people aged 30 and above had a higher probability of reporting no change or an increase in productivity after shifting to teleworking. Respondents not living with children, and therefore less likely to experience unexpected interruptions, were more likely to report no change or increase in productivity. Those in higher education, including students, faculty, and staff, tended to report being less productive. Those with higher educational attainment (having a graduate degree and above) also tended to report being less productive. This is likely due to the nature of academic work (e.g. teaching and knowledge production), which often relies on specific equipment and facilities not available at home, as well as on in-person communications (Carlino and Kerr 2014; McFadyen and Albert A.  Cannella 2016). The population segments associated with no change or increase in productivity are potential targets for future long-term teleworking arrangements. Conversely, those who reported a decrease in productivity after shifting to WFH could benefit from additional support from family, employer, and community if continuing to WHF.

Previous commute mode and duration

Participants with longer Single Occupant Vehicle (SOV) trips before having the WFH had a higher probability of reporting no change or an increase in productivity after shifting to teleworking. In contrast, those with longer walking trips, had a higher probability of reporting a decrease in productivity. This is likely because the benefits of eliminating commuting time do not balance off the physical and mental benefits brought by walking to and from work, as suggested by prior studies (Páez and Whalen 2010; Whalen, Páez, and Carrasco 2013).

Lifestyle changes

Sleep quality has long been associated with work productivity and quality of life (Kucharczyk, Morgan, and Hall 2012). We found similar positive relationship between sleep quality and reported productivity after shifting to teleworking. More time spent on social media was linked to a decrease in productivity. This was consistent with the negative effects of the distractions, physical discomfort, and negative emotions associated with social media use as reported in previous studies of workplace and office settings (Priyadarshini et al. 2020; Vithayathil, Dadgar, and Osiri 2020). On the other hand, more time spent on personal hobbies, was linked to maintaining the same level of productivity, or to increasing productivity. This suggested that engaging in nonwork related activities helped compensate for the demands of continuous work (Eschleman et al. 2014).

ACKNOWLEDGMENTS

This work has been funded by the US Department of Transportation’s University Transportation Center program through the Pacific Northwest Regional University Transportation Center (PacTrans) and Puget Sound Regional Council (PSRC). The authors would like to thank PacTrans and PSRC for their support. Views expressed in the paper do not represent those of the sponsors and the authors are responsible for all errors that may exist.