shorts

DOI R-CMD-check CRAN status

{shorts} is an R package aimed for the analysis of the un-resisted and resisted short sprints (<6sec; without deceleration), creation of acceleration-velocity profiles (AVP), force-velocity profiles (FVP), and optimization profiles using variety of sprint traces (e.g., time-velocity from laser/radar gun, distance-time from timing gates/photocells). It represents a simple to use tool for researcher and practitioners interested in modeling short sprints performance.

Installation

# Install from CRAN
install.packages("shorts")

# Or the development version from GitHub
# install.packages("remotes")
remotes::install_github("mladenjovanovic/shorts")

Examples

{shorts} comes with multiple sample data sets. Let’s load split_times and radar_gun_data with N=5 athletes:

library(shorts)
library(tidyverse)
library(knitr)

data("split_times", "radar_gun_data")

Profiling using split times

{shorts} package utilizes modified mono-exponential functions to model short sprint performance. To model sprint performance using split times, distance will be used as predictor and time as target. Since split_times dataset contains data for multiple athletes, let’s extract only one athlete and model it using shorts::model_timing_gates() function.

kimberley_data <- filter(split_times, athlete == "Kimberley")

kable(kimberley_data)
athlete bodyweight distance time
Kimberley 55 5 1.16
Kimberley 55 10 1.89
Kimberley 55 15 2.54
Kimberley 55 20 3.15
Kimberley 55 30 4.31
Kimberley 55 40 5.44

Parameters estimated using mono-exponential equation are maximal sprinting speed (\(MSS\)), and maximal acceleration (MAC). Additional parameters computed from \(MSS\) and \(MAC\) are relative acceleration (\(TAU\)) and maximal relative power (\(PMAX\)) (which is calculated as \(MAC \cdot MSS\div4\)).

kimberley_profile <- shorts::model_timing_gates(
  distance = kimberley_data$distance,
  time = kimberley_data$time
)

kimberley_profile
#> Estimated model parameters
#> --------------------------
#>    MSS    MAC    TAU   PMAX 
#>  8.591 10.589  0.811 22.743 
#> 
#> Model fit estimators
#> --------------------
#>             R2        meanErr   meanErr_perc         minErr 
#>        0.99966       -0.00309       -0.53860       -0.05293 
#>    minErr_perc         maxErr    maxErr_perc      maxAbsErr 
#>       -4.57121        0.02699        0.85715        0.05293 
#> maxAbsErr_perc           RMSE      RMSE_perc            MAE 
#>        4.57121        0.02779        1.93922        0.02333 
#>       MAE_perc 
#>        1.19263

summary(kimberley_profile)
#> 
#> Formula: time ~ predict_time_at_distance(distance, MSS, MAC)
#> 
#> Parameters:
#>     Estimate Std. Error t value   Pr(>|t|)    
#> MSS    8.591      0.123    70.1 0.00000025 ***
#> MAC   10.589      0.460    23.0 0.00002108 ***
#> ---
#> Signif. codes:  0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
#> 
#> Residual standard error: 0.034 on 4 degrees of freedom
#> 
#> Number of iterations to convergence: 5 
#> Achieved convergence tolerance: 0.0000000149

coef(kimberley_profile)
#>   MSS   MAC 
#>  8.59 10.59

confint(kimberley_profile, level = 0.95)
#>     2.5% 97.5%
#> MSS 8.27  8.96
#> MAC 9.42 12.02

To return the predicted/fitted values (in this case time variable), use predict() function:

predict(kimberley_profile)
#> [1] 1.21 1.90 2.52 3.12 4.30 5.47

To create a simple plot use S3 plot() method. There are four type options: "model" (default), "kinematics-time", "kinematics-distance", or "residuals":

plot(kimberley_profile)

plot(kimberley_profile, "kinematics-time")

plot(kimberley_profile, "kinematics-distance")

plot(kimberley_profile, "residuals")

If you are interested in calculating average split velocity, use shorts::format_splits()

kable(shorts::format_splits(
  distance = kimberley_data$distance,
  time = kimberley_data$time
))
split split_distance_start split_distance_stop split_distance split_time_start split_time_stop split_time split_mean_velocity split_mean_acceleration
1 0 5 5 0.00 1.16 1.158 4.32 3.729
2 5 10 5 1.16 1.89 0.735 6.80 3.381
3 10 15 5 1.89 2.54 0.648 7.72 1.409
4 15 20 5 2.54 3.15 0.608 8.22 0.835
5 20 30 10 3.15 4.31 1.164 8.59 0.316
6 30 40 10 4.31 5.44 1.131 8.84 0.222

To plot predicted velocity, acceleration, air resistance, force, and power over distance, use shorts:predict_XXX(). Please note that to calculate force, air resistance, and power, we need Kimberley’s bodymass and height (as well as other characteristics such as air pressure, temperature and wind - see get_air_resistance() function).

kimberley_bodymass <- 60 # in kilograms
kimberley_bodyheight <- 1.7 # in meters

kimberley_pred <- tibble(
  distance = seq(0, 40, length.out = 1000),

  # Velocity
  pred_velocity = shorts::predict_velocity_at_distance(
    distance,
    kimberley_profile$parameters$MSS,
    kimberley_profile$parameters$TAU
  ),

  # Acceleration
  pred_acceleration = shorts::predict_acceleration_at_distance(
    distance,
    kimberley_profile$parameters$MSS,
    kimberley_profile$parameters$TAU
  ),

  # Air resistance
  pred_air_resistance = shorts::predict_air_resistance_at_distance(
    distance,
    kimberley_profile$parameters$MSS,
    kimberley_profile$parameters$TAU,
    bodymass = kimberley_bodymass,
    bodyheight = kimberley_bodyheight
  ),

  # Force
  pred_force = shorts::predict_force_at_distance(
    distance,
    kimberley_profile$parameters$MSS,
    kimberley_profile$parameters$TAU,
    bodymass = kimberley_bodymass,
    bodyheight = kimberley_bodyheight
  ),

  # Power
  pred_power = shorts::predict_power_at_distance(
    distance,
    kimberley_profile$parameters$MSS,
    kimberley_profile$parameters$TAU,
    bodymass = kimberley_bodymass,
    bodyheight = kimberley_bodyheight
  ),
)

# Convert to long
kimberley_pred <- gather(kimberley_pred, "metric", "value", -distance)

ggplot(kimberley_pred, aes(x = distance, y = value)) +
  geom_line() +
  facet_wrap(~metric, scales = "free_y") +
  xlab("Distance (m)") +
  ylab(NULL)

To do prediction simpler, use shorts::predict_kinematics() function. This will provide kinetics and kinematics for 0-6 \(s\) sprint using 100 \(Hz\).

predicted_kinematics <- predict_kinematics(
  kimberley_profile,
  bodymass = kimberley_bodymass,
  bodyheight = kimberley_bodyheight
)

kable(head(predicted_kinematics))
time distance velocity acceleration bodymass inertia resistance air_resistance horizontal_force horizontal_force_relative vertical_force resultant_force resultant_force_relative power power_relative work average_power average_power_relative RF force_angle
0.00 0.000 0.000 10.59 60 0 0 0.000 635 10.59 589 866 14.4 0 0.00 0.000 0.734 42.8
0.01 0.001 0.105 10.46 60 0 0 0.003 628 10.46 589 860 14.3 66 1.10 0.332 33.2 0.554 0.729 43.2
0.02 0.002 0.209 10.33 60 0 0 0.011 620 10.33 589 855 14.2 130 2.16 1.313 65.6 1.094 0.725 43.5
0.03 0.005 0.312 10.21 60 0 0 0.023 612 10.21 589 849 14.2 191 3.18 2.918 97.3 1.621 0.721 43.9
0.04 0.008 0.413 10.08 60 0 0 0.041 605 10.08 589 844 14.1 250 4.17 5.124 128.1 2.135 0.717 44.2
0.05 0.013 0.513 9.96 60 0 0 0.063 597 9.96 589 839 14.0 307 5.11 7.910 158.2 2.637 0.712 44.6

To get model residuals, use residuals() function:

residuals(kimberley_profile)
#> [1] -0.05293 -0.00402  0.01997  0.02699  0.01376 -0.02232

Package {shorts} comes with find_XXX() family of functions that allow finding peak power and it’s location, as well as critical distance over which velocity, acceleration, or power drops below certain threshold:

# Peak power and location
shorts::find_peak_power_distance(
  MSS = kimberley_profile$parameters$MSS,
  MAC = kimberley_profile$parameters$MAC, 
  bodymass = kimberley_bodymass,
  bodyheight = kimberley_bodyheight
)
#> $peak_power
#> [1] 1384
#> 
#> $distance
#> [1] 1.42

# Distance over which power is over 80%
shorts::find_power_critical_distance(
  MSS = kimberley_profile$parameters$MSS,
  MAC = kimberley_profile$parameters$MAC, 
  bodymass = kimberley_bodymass,
  bodyheight = kimberley_bodyheight,
  percent = 0.8
)
#> $lower
#> [1] 0.342
#> 
#> $upper
#> [1] 4.27

# Distance over which acceleration is under 50%
shorts::find_acceleration_critical_distance(
  MSS = kimberley_profile$parameters$MSS,
  MAC = kimberley_profile$parameters$MAC,
  percent = 0.5
)
#> [1] 1.35

# Distance over which velocity is over 95%
shorts::find_velocity_critical_distance(
  MSS = kimberley_profile$parameters$MSS,
  MAC = kimberley_profile$parameters$MAC,
  percent = 0.95
)
#> [1] 14.3

Profiling using radar gun data

The radar gun data is modeled using measured velocity as target variable and time as predictor. Individual analysis is performed using shorts::model_radar_gun() function or shorts::model_laser_gun() (they are aliases). Let’s do analysis for Jim:

jim_data <- filter(radar_gun_data, athlete == "Jim")

jim_profile <- shorts::model_radar_gun(
  time = jim_data$time,
  velocity = jim_data$velocity
)

jim_profile
#> Estimated model parameters
#> --------------------------
#>    MSS    MAC    TAU   PMAX 
#>  7.998  8.999  0.889 17.993 
#> 
#> Estimated model corrections
#> --------------------------
#>       TC 
#> -0.00011 
#> 
#> Model fit estimators
#> --------------------
#>             R2        meanErr   meanErr_perc         minErr 
#>   0.9992440860  -0.0000000248           -Inf  -0.1640450506 
#>    minErr_perc         maxErr    maxErr_perc      maxAbsErr 
#>           -Inf   0.1511233656   2.3325106593   0.1640450506 
#> maxAbsErr_perc           RMSE      RMSE_perc            MAE 
#>            Inf   0.0505025383            Inf   0.0392723633 
#>       MAE_perc 
#>            Inf

summary(jim_profile)
#> 
#> Formula: velocity ~ predict_velocity_at_time(time - TC, MSS, MAC)
#> 
#> Parameters:
#>     Estimate Std. Error t value            Pr(>|t|)    
#> MSS  7.99801    0.00319 2504.55 <0.0000000000000002 ***
#> MAC  8.99871    0.01997  450.61 <0.0000000000000002 ***
#> TC  -0.00011    0.00123   -0.09                0.93    
#> ---
#> Signif. codes:  0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
#> 
#> Residual standard error: 0.0506 on 597 degrees of freedom
#> 
#> Number of iterations to convergence: 4 
#> Achieved convergence tolerance: 0.0000000149

confint(jim_profile)
#>         2.5%   97.5%
#> MSS  7.99175 8.00429
#> MAC  8.95959 9.03797
#> TC  -0.00253 0.00229

plot(jim_profile)

In addition to \(MSS\) and \(MAC\) parameters, shorts::model_radar_gun() function also estimated time-correction (\(TC\)) parameter.

Rather than estimating \(MSS\), shorts::model_radar_gun() function allows you to utilize peak velocity observed in the data as \(MSS\). This is done by setting the use_observed_MSS parameter to TRUE:

jim_profile <- shorts::model_radar_gun(
  time = jim_data$time,
  velocity = jim_data$velocity,
  use_observed_MSS = TRUE
)

jim_profile
#> Estimated model parameters
#> --------------------------
#>    MSS    MAC    TAU   PMAX 
#>  8.095  8.678  0.933 17.563 
#> 
#> Estimated model corrections
#> --------------------------
#>      TC 
#> -0.0112 
#> 
#> Model fit estimators
#> --------------------
#>             R2        meanErr   meanErr_perc         minErr 
#>         0.9988        -0.0388           -Inf        -0.2287 
#>    minErr_perc         maxErr    maxErr_perc      maxAbsErr 
#>           -Inf         0.1825         2.8174         0.2287 
#> maxAbsErr_perc           RMSE      RMSE_perc            MAE 
#>            Inf         0.0798            Inf         0.0643 
#>       MAE_perc 
#>            Inf

summary(jim_profile)
#> 
#> Formula: velocity ~ predict_velocity_at_time(time - TC, MSS, MAC)
#> 
#> Parameters:
#>     Estimate Std. Error t value             Pr(>|t|)    
#> MSS  8.09500    0.00521 1554.10 < 0.0000000000000002 ***
#> MAC  8.67822    0.03017  287.60 < 0.0000000000000002 ***
#> TC  -0.01118    0.00203   -5.52          0.000000051 ***
#> ---
#> Signif. codes:  0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
#> 
#> Residual standard error: 0.08 on 597 degrees of freedom
#> 
#> Number of iterations to convergence: 5 
#> Achieved convergence tolerance: 0.0000000149

Profiling using tether devices

Some tether devices provide data out in a velocity-at-distance format. In this case, velocity is the outcome variable and distance is the predictor. To estimate sprint profiles from tether data, use shorts::model_tether() function.

# This creates sprint trace
tether_df <- shorts::create_sprint_trace(
  MSS = 7, MAC = 6,
  time = seq(0.01, 6, by = 0.01))

m1 <- model_tether(
  distance = tether_df$distance,
  velocity = tether_df$velocity)

m1
#> Estimated model parameters
#> --------------------------
#>   MSS   MAC   TAU  PMAX 
#>  7.00  6.00  1.17 10.50 
#> 
#> Model fit estimators
#> --------------------
#>                    R2               meanErr 
#>  0.999999999999999778  0.000000000000000464 
#>          meanErr_perc                minErr 
#>  0.000000000000849181 -0.000000000000038081 
#>           minErr_perc                maxErr 
#> -0.000000000032006657  0.000000000000298428 
#>           maxErr_perc             maxAbsErr 
#>  0.000000000499514588  0.000000000000298428 
#>        maxAbsErr_perc                  RMSE 
#>  0.000000000499514588  0.000000000000012599 
#>             RMSE_perc                   MAE 
#>  0.000000000020448893  0.000000000000001438 
#>              MAE_perc 
#>  0.000000000000981334

plot(m1)

Setting use_observed_MSS parameter to TRUE in the shorts::model_tether() function also allows you to use observed peak velocity as \(MSS\).

In the case when distance is not centered at zero, use shorts::model_tether_DC() which also estimated the distance correction (\(DC\)) parameter, serving as model intercept (for more info see Using corrections section):

# This creates sprint trace
tether_df <- shorts::create_sprint_trace(
  MSS = 7, MAC = 6,
  time = seq(0.001, 6, by = 0.01), 
  # Add distance shift
  DC = 5)

m1 <- model_tether_DC(
  distance = tether_df$distance,
  velocity = tether_df$velocity)

m1
#> Estimated model parameters
#> --------------------------
#>   MSS   MAC   TAU  PMAX 
#>  7.00  6.00  1.17 10.50 
#> 
#> Estimated model corrections
#> --------------------------
#> DC 
#>  5 
#> 
#> Model fit estimators
#> --------------------
#>               R2          meanErr     meanErr_perc 
#>  1.0000000000000  0.0000000000648  0.0000008098034 
#>           minErr      minErr_perc           maxErr 
#> -0.0000000000152 -0.0000000002897  0.0000000287380 
#>      maxErr_perc        maxAbsErr   maxAbsErr_perc 
#>  0.0004791725496  0.0000000287380  0.0004791725496 
#>             RMSE        RMSE_perc              MAE 
#>  0.0000000011812  0.0000195628726  0.0000000000741 
#>         MAE_perc 
#>  0.0000008099718

plot(m1)

Embedded (i.e., in-situ) Profiling

With the modern technologies like GPS and LPS, session acceleration and velocity can be tracked continuously. This provides an opportunity to estimate short sprint profiles from in-situ, without the need for explicit testing (assuming the maximal effort was performed). The analysis is based on the theoretical model where acceleration and velocity have linear relationship (i.e., mono-exponential model applied thus far). The time frame of the analysis can vary from single drills (e.g., sprint drills), session, week, to multiple weeks.

Here is an example of the data collected during one basketball session for a single person. Duration was approx. 90 min with 20 \(Hz\) sampling rate. This is the positional data:

data("LPS_session")

LPS_session %>%
  ggplot(aes(x = x, y = y)) +
  geom_point(alpha = 0.1)

The next figure plots instant acceleration and velocity:

LPS_session %>%
  ggplot(aes(x = velocity, y = acceleration)) +
  geom_point(alpha = 0.1)

To estimate embedded short sprint profile, we need to filter out positive acceleration and velocities over 3 \(ms{-1}\) (default), then filter few top acceleration observations per velocity bracket (for more information please see Clavel et al. (2023)). Here is the graphical representation:

embedded_model <- model_in_situ(
  LPS_session$velocity,
  LPS_session$acceleration,
  velocity_threshold = 4)
                                
LPS_session %>%
  filter(acceleration > 0) %>%
  ggplot(aes(x = velocity, y = acceleration)) +
  geom_point(alpha = 0.1) +
  geom_point(
    data = embedded_model$data, 
    color = "red"
  ) +
  geom_abline(
    intercept = embedded_model$parameters$MAC,
    slope = -embedded_model$parameters$MAC / embedded_model$parameters$MSS,
    linetype = "dotted", color = "red") +
  scale_x_continuous(expand = c(0, 0), limits = c(0, embedded_model$parameters$MSS)) +
  scale_y_continuous(expand = c(0, 0), limits = c(0, embedded_model$parameters$MAC))

Force-Velocity Profiling

To estimate Force-Velocity Profile (FVP) using approach by Samozino et al. (2016, 2022) use shorts::create_FVP():

kimberley_fv <- shorts::create_FVP(
  MSS = kimberley_profile$parameters$MSS,
  MAC = kimberley_profile$parameters$MAC,
  # These are needed to estimate air resistance
  bodymass = kimberley_bodymass,
  bodyheight = kimberley_bodyheight
)

kimberley_fv
#> $bodymass
#> [1] 60
#> 
#> $F0
#> [1] 635
#> 
#> $F0_rel
#> [1] 10.6
#> 
#> $V0
#> [1] 8.85
#> 
#> $Pmax
#> [1] 1405
#> 
#> $Pmax_rel
#> [1] 23.4
#> 
#> $FV_slope
#> [1] -1.2

To convert back to Acceleration-Velocity Profile (AVP), use:

kimberley_avp <- shorts::convert_FVP(
  F0 = kimberley_fv$F0,
  V0 = kimberley_fv$V0,
  bodymass = kimberley_bodymass,
  bodyheight = kimberley_bodyheight
)

kimberley_avp
#> $MSS
#> [1] 8.59
#> 
#> $MAC
#> [1] 10.6

Using external load

{shorts} package also allows utilizing external load in estimating FVP, as well as using FVP parameters to predict kinematic and kinetic variables. External load is represented either with additional inertia (i.e., weight vest), horizontal resistance (i.e., tether device that create additional resistance or help, or a hill sprinting), or both (i.e., a sled, which have both inertia and resistance due to friction forces). One might also consider head and tail wind as a form of resistance (or assistance).

Let’s see how theoretical model, assuming FVP is determinant of performance (which I do not agree with, BTW), predicts changes in sprint characteristics (i.e., \(MSS\) and \(MAC\)) under different external load conditions and magnitudes using Kimberley’s estimated FVP:

loads_df <- rbind(
  tibble(type = "Weight vest", magnitude = seq(0, 20, length.out = 100), inertia = magnitude, resistance = 0),
  tibble(type = "Tether", magnitude = seq(-50, 200, length.out = 100), inertia = 0, resistance = magnitude),
  tibble(type = "Sled", magnitude = seq(0, 40, length.out = 100), inertia = magnitude, resistance = magnitude * 9.81 * 0.4)
) %>%
  mutate(
    data.frame(shorts::convert_FVP(
      F0 = kimberley_fv$F0,
      V0 = kimberley_fv$V0,
      bodymass = kimberley_bodymass,
      bodyheight = kimberley_bodyheight,
      inertia = inertia,
      resistance = resistance
    ))
  ) 

loads_df %>%
  pivot_longer(cols = c(MSS, MAC), names_to = "parameter") %>%
  ggplot(aes(x = magnitude, y = value, color = parameter)) +
  geom_vline(xintercept = 0, linetype = "dotted") +
  geom_line() +
  facet_wrap(~type, scales = "free_x") +
  ylab(NULL)

Following figure depicts the effect on split times under different load types and magnitudes, assuming FVP to be determinant of performance (i.e., causal mechanism):

dist_df <- expand_grid(
  loads_df,
  distance = c(5, 10, 20, 30, 40)
) %>%
  mutate(
    time = predict_time_at_distance(distance, MSS, MAC),
    distance = factor(
      paste0(distance, "m"), levels = c("5m", "10m", "20m", "30m", "40m"))
  ) 

dist_df %>%
  ggplot(aes(x = magnitude, y = time, color = distance)) +
  geom_vline(xintercept = 0, linetype = "dotted") +
  geom_line() +
  facet_wrap(~type, scales = "free_x") +
  ylab("Time (s)")

One can use external resistance when predicting force or power:

shorts::predict_force_at_time(
  time = 0.5,
  MSS = 9,
  MAC = 7,
  bodymass = 75,
  inertia = 20,
  resistance = 50)
#> [1] 503

shorts::predict_power_at_time(
  time = 0.5,
  MSS = 9,
  MAC = 7,
  bodymass = 75,
  inertia = 20,
  resistance = 50)
#> [1] 1459

shorts::predict_time_at_distance_FV(
  distance = 10,
  F0 = 750,
  V0 = 8,
  bodymass = 75,
  inertia = 20,
  resistance = 50)
#> [1] 2.26

External resistances can also be utilized in the Optimization functions, covered later.

Using corrections

You have probably noticed that estimated \(MSS\) and \(TAU\) were a bit too high for splits data. Biased estimates are due to differences in starting positions and timing triggering methods for certain measurement approaches (e.g. starting behind first timing gate, or allowing for body rocking).

Here I will provide quick summary (see more in Jovanović M., 2023). Often, this bias in estimates is dealt with by using heuristic rule of thumb of adding time correction (time_correction) to split times (e.g. from 0.3-0.5 \(sec\); see more in Haugen et al., 2012). To do this, just add time correction to time split:

kimberley_profile_fixed_TC <- shorts::model_timing_gates(
  distance = kimberley_data$distance,
  time = kimberley_data$time + 0.3
)

kimberley_profile_fixed_TC
#> Estimated model parameters
#> --------------------------
#>   MSS   MAC   TAU  PMAX 
#>  9.13  6.63  1.38 15.12 
#> 
#> Model fit estimators
#> --------------------
#>             R2        meanErr   meanErr_perc         minErr 
#>        0.99997        0.00101        0.12559       -0.00769 
#>    minErr_perc         maxErr    maxErr_perc      maxAbsErr 
#>       -0.22296        0.01640        1.12474        0.01640 
#> maxAbsErr_perc           RMSE      RMSE_perc            MAE 
#>        1.12474        0.00814        0.47704        0.00639 
#>       MAE_perc 
#>        0.28570

summary(kimberley_profile_fixed_TC)
#> 
#> Formula: time ~ predict_time_at_distance(distance, MSS, MAC)
#> 
#> Parameters:
#>     Estimate Std. Error t value     Pr(>|t|)    
#> MSS   9.1278     0.0536     170 0.0000000071 ***
#> MAC   6.6257     0.0657     101 0.0000000579 ***
#> ---
#> Signif. codes:  0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
#> 
#> Residual standard error: 0.00997 on 4 degrees of freedom
#> 
#> Number of iterations to convergence: 5 
#> Achieved convergence tolerance: 0.0000000149

coef(kimberley_profile_fixed_TC)
#>  MSS  MAC 
#> 9.13 6.63

Instead of providing for TC, this parameter can be estimated using shorts::model_timing_gates_TC().

kimberley_profile_TC <- shorts::model_timing_gates_TC(
  distance = kimberley_data$distance,
  time = kimberley_data$time
)

kimberley_profile_TC
#> Estimated model parameters
#> --------------------------
#>   MSS   MAC   TAU  PMAX 
#>  8.97  7.27  1.23 16.31 
#> 
#> Estimated model corrections
#> --------------------------
#>     TC 
#> -0.235 
#> 
#> Model fit estimators
#> --------------------
#>               R2          meanErr     meanErr_perc 
#>  0.9999996942338  0.0000000000185  0.0018162748771 
#>           minErr      minErr_perc           maxErr 
#> -0.0011807344888 -0.0623737183716  0.0012094657303 
#>      maxErr_perc        maxAbsErr   maxAbsErr_perc 
#>  0.0597477188383  0.0012094657303  0.0623737183716 
#>             RMSE        RMSE_perc              MAE 
#>  0.0007983564900  0.0374822377932  0.0006586033619 
#>         MAE_perc 
#>  0.0282353234295

Instead of estimating TC, {shorts} package features a method of estimating flying start distance (FD):

kimberley_profile_FD <- shorts::model_timing_gates_FD(
  distance = kimberley_data$distance,
  time = kimberley_data$time
)

kimberley_profile_FD
#> Estimated model parameters
#> --------------------------
#>   MSS   MAC   TAU  PMAX 
#>  9.00  6.99  1.29 15.74 
#> 
#> Estimated model corrections
#> --------------------------
#>    FD 
#> 0.302 
#> 
#> Model fit estimators
#> --------------------
#>             R2        meanErr   meanErr_perc         minErr 
#>    0.999999963    0.000000645    0.000318263   -0.000403616 
#>    minErr_perc         maxErr    maxErr_perc      maxAbsErr 
#>   -0.012817270    0.000455703    0.010565804    0.000455703 
#> maxAbsErr_perc           RMSE      RMSE_perc            MAE 
#>    0.012817270    0.000275866    0.008402638    0.000236754 
#>       MAE_perc 
#>    0.007829105

If you want to use fixed FD parameter (e.g., when you know what is the flying distance), use shorts::model_timing_gates_FD_fixed() function:

kimberley_profile_fixed_FD <- shorts::model_timing_gates_FD_fixed(
  distance = kimberley_data$distance,
  time = kimberley_data$time,
  FD = 0.5
)

kimberley_profile_fixed_FD
#> Estimated model parameters
#> --------------------------
#>   MSS   MAC   TAU  PMAX 
#>  9.18  6.23  1.47 14.30 
#> 
#> Estimated model corrections
#> --------------------------
#>  FD 
#> 0.5 
#> 
#> Model fit estimators
#> --------------------
#>             R2        meanErr   meanErr_perc         minErr 
#>        0.99997        0.00125        0.17740       -0.00790 
#>    minErr_perc         maxErr    maxErr_perc      maxAbsErr 
#>       -0.25099        0.01546        1.33523        0.01546 
#> maxAbsErr_perc           RMSE      RMSE_perc            MAE 
#>        1.33523        0.00794        0.56493        0.00672 
#>       MAE_perc 
#>        0.34991

There are other corrections involving time correction (TC), distance correction (DC), flying distance correction (FD), and time and distance corrections (TC+DC). They are implemented in the model_timing_gates_ and model_time_distance_ functions. The difference between the model_timing_gates_ and model_time_distance_ is in reversing predictor and outcome variables.

Cross-Validation (CV)

model_ family of functions come with CV feature that is performed by setting the function parameter CV to desired number of folds. This feature is very useful for checking model parameters robustness and model predictions on unseen data. Let’s use Kimberley again, but this time perform special kind of CV, leave-one-out-cross-validation (LOOCV):

kimberley_profile_CV <- shorts::model_timing_gates(
  distance = kimberley_data$distance,
  time = kimberley_data$time,
  # To perform LOOCV number of folds is equal to 
  # number of observations
  CV = nrow(kimberley_data)
)

kimberley_profile_CV
#> Estimated model parameters
#> --------------------------
#>    MSS    MAC    TAU   PMAX 
#>  8.591 10.589  0.811 22.743 
#> 
#> Model fit estimators
#> --------------------
#>             R2        meanErr   meanErr_perc         minErr 
#>        0.99966       -0.00309       -0.53860       -0.05293 
#>    minErr_perc         maxErr    maxErr_perc      maxAbsErr 
#>       -4.57121        0.02699        0.85715        0.05293 
#> maxAbsErr_perc           RMSE      RMSE_perc            MAE 
#>        4.57121        0.02779        1.93922        0.02333 
#>       MAE_perc 
#>        1.19263 
#> 
#> 
#> Cross-Validation
#> ------------------------------
#> Parameters:
#>   .fold  MSS  MAC   TAU PMAX
#> 1     1 8.69 10.2 0.856 22.1
#> 2     2 8.56 10.8 0.795 23.0
#> 3     3 8.39 11.1 0.760 23.2
#> 4     4 8.57 10.8 0.797 23.0
#> 5     5 8.61 10.6 0.813 22.8
#> 6     6 8.60 10.5 0.815 22.7
#> 
#> Testing model fit estimators (overall):
#>             R2        meanErr   meanErr_perc         minErr 
#>         0.9990        -0.0124        -0.8548        -0.0801 
#>    minErr_perc         maxErr    maxErr_perc      maxAbsErr 
#>        -5.9601         0.0344         1.0940         0.0801 
#> maxAbsErr_perc           RMSE      RMSE_perc            MAE 
#>         5.9601         0.0474         2.5920         0.0392 
#>       MAE_perc 
#>         1.7227

Radar gun data often comes with much more observations, thus we can set smaller CV parameter:

jim_profile_CV <- shorts::model_radar_gun(
  time = jim_data$time,
  velocity = jim_data$velocity,
  CV = 10
)

jim_profile_CV
#> Estimated model parameters
#> --------------------------
#>    MSS    MAC    TAU   PMAX 
#>  7.998  8.999  0.889 17.993 
#> 
#> Estimated model corrections
#> --------------------------
#>       TC 
#> -0.00011 
#> 
#> Model fit estimators
#> --------------------
#>             R2        meanErr   meanErr_perc         minErr 
#>   0.9992440860  -0.0000000248           -Inf  -0.1640450506 
#>    minErr_perc         maxErr    maxErr_perc      maxAbsErr 
#>           -Inf   0.1511233656   2.3325106593   0.1640450506 
#> maxAbsErr_perc           RMSE      RMSE_perc            MAE 
#>            Inf   0.0505025383            Inf   0.0392723633 
#>       MAE_perc 
#>            Inf 
#> 
#> 
#> Cross-Validation
#> ------------------------------
#> Parameters:
#>    .fold MSS  MAC   TAU PMAX
#> 1      1   8 8.99 0.889   18
#> 2      2   8 9.00 0.888   18
#> 3      3   8 9.00 0.889   18
#> 4      4   8 9.00 0.889   18
#> 5      5   8 9.00 0.889   18
#> 6      6   8 9.00 0.888   18
#> 7      7   8 9.00 0.889   18
#> 8      8   8 9.00 0.889   18
#> 9      9   8 9.01 0.888   18
#> 10    10   8 8.99 0.890   18
#> 
#> Testing model fit estimators (overall):
#>             R2        meanErr   meanErr_perc         minErr 
#>      0.9992387     -0.0000138           -Inf     -0.1616499 
#>    minErr_perc         maxErr    maxErr_perc      maxAbsErr 
#>           -Inf      0.1507892      2.3273526      0.1616499 
#> maxAbsErr_perc           RMSE      RMSE_perc            MAE 
#>            Inf      0.0506812            Inf      0.0394415 
#>       MAE_perc 
#>            Inf

Optimization

Using the method outlined in Samozino et al (2022), one can find the optimal profiles, as well as the profile imbalance (compared to the optimal), for both sprint profiles (i.e., \(MSS\) and \(MAC\)) and Force-Velocity (FV). In addition to this, one can probe the profiles (i.e., increase \(V0\) / \(F0\) or \(MSS\) / \(MAC\) for say 2.5% to check which improvement yield more improvement in sprint time). The following graph depicts estimate profile imbalances. Note that >100% is velocity deficit (i.e., increasing velocity; \(MSS\) or \(V0\); will yield more improvement in sprint times), while <100% is force deficit.

MSS <- 10
MAC <- 8
bodymass <- 75

fv <- create_FVP(MSS, MAC, bodymass)

opt_df <- tibble(
  dist = seq(5, 50, by = 5)
) %>%
  mutate(
    `Sprint Profile` = optimal_MSS_MAC(
      distance = dist,
      MSS,
      MAC
    )[["profile_imb"]],
    `FV Profile` = optimal_FV(
      distance = dist,
      fv$F0,
      fv$V0,
      bodymass
    )[["profile_imb"]],
    `FV Profile (PeakPower)` = optimal_FV(
      distance = dist,
      fv$F0,
      fv$V0,
      bodymass,
      method = "peak"
    )[["profile_imb"]],
    `Probe FV` = probe_FV(
      distance = dist,
      fv$F0,
      fv$V0,
      bodymass
    )[["profile_imb"]],
    `Probe MSS/MAC` = probe_MSS_MAC(
      distance = dist,
      MSS,
      MAC
    )[["profile_imb"]]
  ) %>%
  pivot_longer(-dist, names_to = "profile")

opt_dist <- tibble(
  `Sprint Profile` = find_optimal_distance(
    MSS,
    MAC,
    optimal_func = optimal_MSS_MAC
  ),
  `FV Profile` = find_optimal_distance(
    fv$F0,
    fv$V0,
    bodymass,
    optimal_func = optimal_FV
  ),
  `FV Profile (PeakPower)` = find_optimal_distance(
    fv$F0,
    fv$V0,
    bodymass,
    optimal_func = optimal_FV,
    method = "peak"
  ),
  `Probe FV` = find_optimal_distance(
    fv$F0,
    fv$V0,
    bodymass,
    optimal_func = probe_FV
  ),
  `Probe MSS/MAC` = find_optimal_distance(
    MSS,
    MAC,
    optimal_func = probe_MSS_MAC
  )
) %>%
  pivot_longer(cols = 1:5, names_to = "profile")

ggplot(opt_df, aes(x = dist, y = value, color = profile)) +
  geom_hline(yintercept = 100, linetype = "dashed", alpha = 0.6) +
  geom_line() +
  geom_point(data = opt_dist, aes(x = value, y = 100), size = 2) +
  xlab("Distance (m)") +
  ylab("Profile imbalance")

Creating your own data

One can use the {shorts}} package for simulating data by using two functions: create_sprint_trace() and create_timing_gates_splits():

create_sprint_trace(
  MSS = 7, MAC = 6,
  distance = c(5, 10, 20, 30, 40),
  # Add flying distance
  FD = 0.5)
#>   time distance velocity acceleration sprint_time
#> 1 1.24        5     5.33       1.4280        1.67
#> 2 2.10       10     6.20       0.6839        2.53
#> 3 3.63       20     6.78       0.1850        4.06
#> 4 5.08       30     6.94       0.0532        5.51
#> 5 6.52       40     6.98       0.0155        6.95
#>   sprint_distance
#> 1             5.5
#> 2            10.5
#> 3            20.5
#> 4            30.5
#> 5            40.5

create_timing_gates_splits(
  MSS = 7, MAC = 6,
  gates = c(5, 10, 20, 30, 40),
  # Add time-shift (i.e., rection time of 200ms)
  TC = 0.2)
#> [1] 1.78 2.65 4.19 5.64 7.08

Using predict_ family of functions, one can predict kinematics and kinetics using known \(MSS\) and \(MAC\) parameters.

Publications

  1. Jovanović, M., Vescovi, J.D. (2022). {shorts}: An R Package for Modeling Short Sprints. International Journal of Strength and Conditioning, 2(1). https://doi.org/10.47206/ijsc.v2i1.74

  2. Jovanović M. (2023). Bias in estimated short sprint profiles using timing gates due to the flying start: simulation study and proposed solutions. Computer Methods in Biomechanics and Biomedical Engineering:1–11. https://doi.org/10.1080/10255842.2023.2170713

  3. Jovanović M., et al. (2024). “Effects of the Flying Start on Estimated Short Sprint Profiles Using Timing Gates”. https://doi.org/10.3390/s24092894

  4. Vescovi, JD and Jovanović, M. (2021). Sprint Mechanical Characteristics of Female Soccer Players: A Retrospective Pilot Study to Examine a Novel Approach for Correction of Timing Gate Starts. Front Sports Act Living 3: 629694, 2021. https://doi.org/10.3389/fspor.2021.629694

Citation

To cite {shorts}, please use the following command to get the BibTex entry:

citation("shorts")

References

Please refer to these publications for more information on short sprints modeling using mono-exponential equation:

Chelly SM, Denis C. 2001. Leg power and hopping stiffness: relationship with sprint running performance: Medicine and Science in Sports and Exercise:326–333. DOI: 10.1097/00005768-200102000-00024.

Clark KP, Rieger RH, Bruno RF, Stearne DJ. 2017. The NFL Combine 40-Yard Dash: How Important is Maximum Velocity? Journal of Strength and Conditioning Research:1. DOI: 10.1519/JSC.0000000000002081.

Clavel, P., Leduc, C., Morin, J.-B., Buchheit, M., & Lacome, M. (2023). Reliability of individual acceleration-speed profile in-situ in elite youth soccer players. Journal of Biomechanics, 153, 111602. https://doi.org/10.1016/j.jbiomech.2023.111602

Furusawa K, Hill AV, and Parkinson JL. The dynamics of” sprint” running. Proceedings of the Royal Society of London. Series B, Containing Papers of a Biological Character 102 (713): 29-42, 1927

Greene PR. 1986. Predicting sprint dynamics from maximum-velocity measurements. Mathematical Biosciences 80:1–18. DOI: 10.1016/0025-5564(86)90063-5.

Haugen TA, Tønnessen E, Seiler SK. 2012. The Difference Is in the Start: Impact of Timing and Start Procedure on Sprint Running Performance: Journal of Strength and Conditioning Research 26:473–479. DOI: 10.1519/JSC.0b013e318226030b.

Samozino P, Rabita G, Dorel S, Slawinski J, Peyrot N, Saez de Villarreal E, Morin J-B. 2016. A simple method for measuring power, force, velocity properties, and mechanical effectiveness in sprint running: Simple method to compute sprint mechanics. Scandinavian Journal of Medicine & Science in Sports 26:648–658. DOI: 10.1111/sms.12490.

Samozino P. 2018. A Simple Method for Measuring Force, Velocity and Power Capabilities and Mechanical Effectiveness During Sprint Running. In: Morin J-B, Samozino P eds. Biomechanics of Training and Testing. Cham: Springer International Publishing, 237–267. DOI: 10.1007/978-3-319-05633-3_11.

Samozino P, Peyrot N, Edouard P, Nagahara R, Jimenez‐Reyes P, Vanwanseele B, Morin J. 2022. Optimal mechanical force‐velocity profile for sprint acceleration performance.Scandinavian Journal of Medicine & Science in Sports 32:559–575. DOI: 10.1111/sms.14097.