| adj_perc_1RM {STMr} | R Documentation |
Family of functions to adjust %1RM
Description
Family of functions to adjust %1RM
Usage
adj_perc_1RM_RIR(
reps,
adjustment = 0,
mfactor = 1,
max_perc_1RM_func = max_perc_1RM_epley,
...
)
adj_perc_1RM_DI(
reps,
adjustment = 0,
mfactor = 1,
max_perc_1RM_func = max_perc_1RM_epley,
...
)
adj_perc_1RM_rel_int(
reps,
adjustment = 1,
mfactor = 1,
max_perc_1RM_func = max_perc_1RM_epley,
...
)
adj_perc_1RM_perc_MR(
reps,
adjustment = 1,
mfactor = 1,
max_perc_1RM_func = max_perc_1RM_epley,
...
)
Arguments
reps |
Numeric vector. Number of repetition to be performed |
adjustment |
Numeric vector. Adjustment to be implemented |
mfactor |
Numeric vector. Default is 1 (i.e., no adjustment).
Use |
max_perc_1RM_func |
Max %1RM function to be used. Default is |
... |
Forwarded to |
Value
Numeric vector. Predicted perc 1RM
Functions
-
adj_perc_1RM_RIR(): Adjust max %1RM using the Reps In Reserve (RIR) approach -
adj_perc_1RM_DI(): Adjust max %1RM using the Deducted Intensity (DI) approach. This approach simple deductsadjustmentfrom estimated %1RM -
adj_perc_1RM_rel_int(): Adjust max perc 1RM using the Relative Intensity (RelInt) approach. This approach simple multiplies estimated perc 1RM withadjustment -
adj_perc_1RM_perc_MR(): Adjust max perc 1RM using the %Max Reps (%MR) approach. This approach simple divides target reps withadjustment
Examples
# ------------------------------------------
# Adjustment using Reps In Reserve (RIR)
adj_perc_1RM_RIR(5)
# Use ballistic adjustment (this implies doing half the reps)
adj_perc_1RM_RIR(5, mfactor = 2)
# Use 2 reps in reserve
adj_perc_1RM_RIR(5, adjustment = 2)
# Use Linear model
adj_perc_1RM_RIR(5, max_perc_1RM_func = max_perc_1RM_linear, adjustment = 2)
# Use Modifed Epley's equation with a custom parameter values
adj_perc_1RM_RIR(
5,
max_perc_1RM_func = max_perc_1RM_modified_epley,
adjustment = 2,
kmod = 0.06
)
# ------------------------------------------
# Adjustment using Deducted Intensity (DI)
adj_perc_1RM_DI(5)
# Use ballistic adjustment (this implies doing half the reps)
adj_perc_1RM_DI(5, mfactor = 2)
# Use 10 perc deducted intensity
adj_perc_1RM_DI(5, adjustment = -0.1)
# Use Linear model
adj_perc_1RM_DI(5, max_perc_1RM_func = max_perc_1RM_linear, adjustment = -0.1)
# Use Modifed Epley's equation with a custom parameter values
adj_perc_1RM_DI(
5,
max_perc_1RM_func = max_perc_1RM_modified_epley,
adjustment = -0.1,
kmod = 0.06
)
# ------------------------------------------
# Adjustment using Relative Intensity (RelInt)
adj_perc_1RM_rel_int(5)
# Use ballistic adjustment (this implies doing half the reps)
adj_perc_1RM_rel_int(5, mfactor = 2)
# Use 90 perc relative intensity
adj_perc_1RM_rel_int(5, adjustment = 0.9)
# Use Linear model
adj_perc_1RM_rel_int(5, max_perc_1RM_func = max_perc_1RM_linear, adjustment = 0.9)
# Use Modifed Epley's equation with a custom parameter values
adj_perc_1RM_rel_int(
5,
max_perc_1RM_func = max_perc_1RM_modified_epley,
adjustment = 0.9,
kmod = 0.06
)
# ------------------------------------------
# Adjustment using % max reps (%MR)
adj_perc_1RM_perc_MR(5)
# Use ballistic adjustment (this implies doing half the reps)
adj_perc_1RM_perc_MR(5, mfactor = 2)
# Use 70 perc max reps
adj_perc_1RM_perc_MR(5, adjustment = 0.7)
# Use Linear model
adj_perc_1RM_perc_MR(5, max_perc_1RM_func = max_perc_1RM_linear, adjustment = 0.7)
# Use Modifed Epley's equation with a custom parameter values
adj_perc_1RM_perc_MR(
5,
max_perc_1RM_func = max_perc_1RM_modified_epley,
adjustment = 0.7,
kmod = 0.06
)