Smoldering Magic Infused Barbecue Barbecues have long been a staple of outdoor gatherings and culinary delights. The sizzling of meat, the smoky aroma, and the gathering of friends and family all contribute to the enjoyable ambiance. However, what if there was a way to enhance the barbecue experience even further? Enter the concept of smoldering magic-infused barbecue. The idea behind smoldering magic-infused barbecue is to combine the traditional elements of a barbecue with the mystical properties of magic. By infusing the charcoal or wood used for grilling with a touch of magic, a whole new world of flavor and excitement opens up. **The main idea: Smoldering magic-infused barbecue enhances the traditional barbecue experience by infusing the charcoal or wood with magic, resulting in unique flavors and exciting effects.
The block represents the longitudinal forces at the tire-road contact patch using the Magic Formula of Pacejka [2].
When you set Parameterize by to Constant Magic Formula coefficients , the block uses the dimensionless coeffiecients, B , C , D , and E , or stiffness, shape, peak, and curvature, such that. Alternatively, it will convert the kinetic energy into something harmless so she doesn t hurt herself, her allies on the ground, or do any significant property damage.
**The main idea: Smoldering magic-infused barbecue enhances the traditional barbecue experience by infusing the charcoal or wood with magic, resulting in unique flavors and exciting effects.** One of the key benefits of using magic-infused charcoal is the ability to impart unique and unforgettable flavors to the food being grilled. Just as different types of wood or charcoal can add their distinct taste, the magic-infused variety adds a layer of complexity and depth.
Tire-Road Interaction (Magic Formula)
The Tire-Road Interaction (Magic Formula) block represents the interaction between the tire tread and the road pavement. The Magic Formula predicts the longitudinal force that results from this interaction by using an empirical equation based on fitting coefficients. The block ignores tire properties such as compliance and inertia.
Tire-Road Interaction Model
The block represents the longitudinal forces at the tire-road contact patch using the Magic Formula of Pacejka [2].
The figure displays the forces on the tire. The table defines the tire model variables.
| Symbol | Description |
|---|---|
| Ω | Wheel angular velocity. |
| rw | Wheel radius. |
| Vx | Wheel hub longitudinal velocity. |
| r w Ω | Tire tread longitudinal velocity. |
| u | Tire longitudinal deformation. |
| V T = r w Ω ′ = r w Ω + u ˙ | Tire tread longitudinal velocity. Typically, the tire tread longitudinal velocity has a component due to tire rotation, rwΩ, and an optional component due to tire deformation, u ˙ . Because port T computes VT, the calculations for tire rotations and deformation occur outside of the block. |
| V s x = V x − V T | Contact patch slip velocity. If there is no tire longitudinal compliance, then u = 0 . |
| k = − V s x | V x | s m o o t h | Wheel slip for a tire without compliance. |
| Fz | Vertical load on tire. |
| Fz0 | Nominal vertical load on tire. |
| F x = f ( k , F z ) | Longitudinal force exerted on the tire at the contact point. f is a characteristic function of the tire. |
Tire Response
You can model tire roll and slip.
Forces and Characteristic FunctionThe block uses a steady-state tire characteristic function, F x = f ( k , F z ) , where:
- Fx is the longitudinal force on the tire.
- Fz is the vertical load.
- k is the wheel slip
The equation for translational motion of a non-slipping, non-compliant tire is V x = r w Ω . When tires experience slip, they develop a longitudinal force, Fx.
The contact patch slip velocity is V s x = V x − r w Ω − u ˙ . For a tire without compliance, u = 0 . The unsmoothed contact patch slip is
and the block saturates the slip denominator as
where VXLOW is the Lower boundary of slip denominator, VXLOW parameter. The block smoothly transitions |Vx| to VXLOW over the transition regions -VXLOW - Vth/2 < Vx < -VXLOW + Vth/2 and VXLOW - Vth/2 < Vx < VXLOW + Vth/2 . The block saturates slip according to
k = < k p u m i n if − V s x | V x | < k p u m i n k p u m a x if − V s x | V x | >k p u m a x − V s x | V x | otherwise
where kpumin is the Minimum valid wheel slip, KPUMIN parameter and kpumax is the Maximum valid wheel slip, KPUMAX parameter. The block transitions k over the regions kpumin - kth/2 < k < kpumin + kth/2 and kpumax - kth/2 < k < kpumax + kth/2 . The block defines the slip smoothing threshold as
k t h = V t h 1 m / s .
For this equation, a locked, sliding wheel has k = -1 . For perfect rolling, k = 0 .
Magic Formula Coefficients for Typical Road ConditionsThe block uses numerical values based on empirical tire data. These values are typical sets of constant Magic Formula coefficients for common road conditions.
| Surface | B | C | D | E |
|---|---|---|---|---|
| Dry tarmac | 10 | 1.9 | 1 | 0.97 |
| Wet tarmac | 12 | 2.3 | 0.82 | 1 |
| Snow | 5 | 2 | 0.3 | 1 |
| Ice | 4 | 2 | 0.1 | 1 |
Parameterizations
Peak Longitudinal Force and Corresponding SlipWhen you set Parameterize by to Peak longitudinal force and corresponding slip , the block uses a representative set of Magic Formula coefficients. The block scales the coefficients to yield the peak longitudinal force Fx0 at the corresponding slip κ0 that you specify, for rated vertical load Fz0.
Magic Formula with Constant CoefficientsWhen you set Parameterize by to Constant Magic Formula coefficients , the block uses the dimensionless coeffiecients, B, C, D, and E, or stiffness, shape, peak, and curvature, such that
F x = f ( κ , F z ) = F z ⋅ D ⋅ sin ( C ⋅ arctan < B κ − E [ B κ − arctan ( B κ ) ] >) .
The slope of f at k = 0 is B C D ⋅ F z .
Magic Formula with Load-Dependent CoefficientsWhen you set Parameterize by to Load-dependent Magic Formula coefficients , the block uses dimensionless coefficients that are functions of the tire load. A more complex set of parameters p_i , entered in the property inspector, specifies these functions:
F x 0 = D x sin ( C x arctan < B x κ x − E x [ B x κ x − arctan ( B x κ x ) ] >) + S V x ,
d f z = ( F z – F z 0 ) F z0
Imagine smoky ribs with a hint of enchantment or tender steak with a touch of mystic spice. The possibilities are endless. Furthermore, magic-infused barbecue can also introduce exciting effects and visual displays to the grilling experience. A sprinkle of pixie dust-infused charcoal can create a mesmerizing flame show as it combusts, casting dancing shadows and sparks. This adds an element of wonder and awe to the gathering, making it truly memorable for all attendees. Another aspect to consider is the potential health benefits of utilizing magic-infused charcoal. Some types of magic have healing or purifying properties, which can be transferred to the food during the grilling process. This adds a touch of wellness to the meal, making it not only delicious but also nourishing for the body. However, it is important to note that smoldering magic-infused barbecue should be approached with caution and responsibility. Just as with any magical practice, proper knowledge and understanding are necessary to avoid unintended consequences. It is advisable to consult with experienced magic practitioners or experts to ensure a safe and enjoyable experience. In conclusion, smoldering magic-infused barbecue brings a new level of enchantment and delight to the traditional outdoor cooking experience. By infusing charcoal or wood with a touch of magic, unique flavors, exciting effects, and potential health benefits can be achieved. So, gather your friends and family, and embark on a culinary adventure that transcends the ordinary..
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