AB1171,2,54 1. Be conducted with the boats described in subd. 4. on representative inland
5lake bodies of water in this state.

AB1171,2,76 2. Be conducted with the best available technology, including sensors,
7underwater cameras, and overhead video shot with drones.

AB1171,2,178 3. Study and measure wave energy from representative wakeboats engaged in
9wake surfing and wake boarding activities in typical wake enhanced mode, both with
10maximum ballast and wake shaping equipment and without ballast. The study and
11measure of wave energy under this subdivision shall incorporate a test of at least two
12different 2023-year or later wakeboat models, one of which shall be a typical boat
13with engines with, at minimum, 400 horsepower and a total boat weight of 10,000
14pounds or more, including the weight owing to ballast, and one of which shall be a
15boat with engines with, at minimum, 600 horsepower and that represents the
16maximum size wakeboat sold for use on inland waters in this state as measured by
17the boat's total weight, including the weight owing to full ballast.

AB1171,3,218 4. Study wave energy of the enhanced wake from wakeboats measured against
19other non-wake-enhanced boats commonly used on inland lakes in this state,
20including in the study a representative ski boat, a representative pontoon boat, a
2120-foot or longer representative fishing boat with minimum 200 horsepower
22outboard motor, and if available, a cabin boat with inboard engine and length of 27
23feet or longer. The goal of the study shall be comparing wave size and energy from
24wake-enhanced boats to similar sized boats on lakes and rivers in this state that are

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1used for recreation, fishing and pleasure boating. The study of wave energy under
2this paragraph shall also do all of the following:

AB1171,3,73 a. Measure the energy and height of waves generated by the boats described
4this subdivision at distances of 100, 200, 500, 700 and 1,000 feet from shorelines. The
5study shall determine at what distances a wake-enhanced boat must be from shore
6for both the energy and wave height to equal the same energy and wave height as
7non-wake-enhanced boats at 200 foot distances from shore.

AB1171,3,128 b. Include an analysis of the impact of wake-enhanced waves at distances of
9100, 200, and 500 feet from other boaters, kayakers, paddleboarders, fishing boats,
10sailboats, and other water users, with the goal of understanding whether
11wake-enhanced waves present additional safety challenges to lake users compared
12to other non-wake-enhanced boats.

AB1171,3,1613 5. Study the impact of enhanced wakes on lake bottoms, fish nesting, aquatic
14vegetation, and sediment disruption, and measure energy and video comparisons of
15wake-enhanced versus non-wake-enhanced boats in water depths of 10, 15, and 20
16feet. The study of lake bottoms shall include all of the following:

AB1171,3,18 17a. Measure of downward prop wash created by a boat in wake surf mode
18compared to other boats.

AB1171,3,1919 b. Measure of divergent wave impact on lake bottom.

AB1171,3,2120 c. Analysis of the impacts, if any, to lake littoral zones resulting from wave
21energy as wake-enhanced waves reach the shoreline.

AB1171,3,2422 d. Determination of the amount of energy a typical lake bottom in this state
23absorbs as waves move from deep to shallow waters over distances of 500 and 700
24feet.

AB1171,4,5

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1e. An element regarding sediment resuspension, including an inquiry into
2whether bottom sediment disruption by enhanced wakes include resuspension of
3toxic elements like Polychlorinated biphenyls and arsenic, and an inquiry into
4whether any sediment resuspension settles on the leaves of aquatic vegetation and
5inhibits the aquatic vegetation's growth.

AB1171,4,86 f. An assessment of wave energy and its impacts on both steep and gradual lake
7bottom drop-offs to the shoreline, and whether steep lake bottoms demonstrate a
8significantly higher shoreline impact compared to gradual lake bottoms.

AB1171,4,139 6. Assess the wave energy of waves generated by winds and storms compared
10to the energy of waves generated by enhanced wakes, considering the impacts of
11fetch analysis of wind correlation on small lakes compared to large lakes. In order
12to provide context, this assessment shall include a review of historical sustained
13wind measurements on lakes in this state.

AB1171,4,1514 7. Assess the potential impact of wake enhanced wave energy on shorelines as
15that impact relates to shoreline erosion.