Exemple #1
0
def plot_SS(X,T, title = 'State Space'):

	fig, ax = plt.subplots()
	plt.axis('equal')

	# plot agents
	for i in range(param.get('ni')):
		P_i = np.dot( \
			util.get_p_i(i), np.transpose(X)).transpose()
		
		if i < param.get('na'):
			color = param.get('FreeAgentColor')
		else:
			color = param.get('ControlAgentColor')
		# plot trajectory
		ax.plot( P_i[:,0], P_i[:,1], color = color)
		ax.scatter( P_i[0,0], P_i[0,1], color = color, 
			marker = param.get('start_marker'))
		ax.scatter( P_i[-1,0], P_i[-1,1], color = color, 
			marker = param.get('stop_marker'))

	# plot desired
	ax.plot( param.get('pd')[:,0], param.get('pd')[:,1], 
		color = param.get('DesiredTrajectoryColor'))

	# plot centroid
	P_bar = util.get_P_bar( X,T)
	ax.plot( P_bar[:,0], P_bar[:,1], color = param.get('CentroidColor'))
	ax.plot( P_bar[0,0], P_bar[0,1], color = param.get('CentroidColor'),
		marker = param.get('start_marker'))
	ax.plot( P_bar[-1,0], P_bar[-1,1], color = param.get('CentroidColor'),
		marker = param.get('stop_marker'))
	
	plt.title(title)
Exemple #2
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def reynolds( x, i):
	A   = util.get_A(x)
	p_i = np.dot( util.get_p_i(i), x)
	v_i = np.dot( util.get_v_i(i), x)
	a_i = np.zeros((param.get('nd'),1))
	for j in range(param.get('ni')):
		if i is not j:
			p_j = np.dot( util.get_p_i(j), x)
			v_j = np.dot( util.get_v_i(j), x)

			r_ij = p_j - p_i
			dist = np.linalg.norm(r_ij)

			a_i = a_i + A[i,j]*( \
                param.get('kv')*(v_j - v_i) + \
                param.get('kx')*r_ij*(1 - param.get('R_des')/dist) 
                )
	return a_i 
Exemple #3
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def plot_SS(X,T, title = None, fig = None, ax = None):

	if fig is None:
		fig, ax = plt.subplots()
		plt.axis('equal')

	if title is not None:
		plt.title(title)		

	# plot agents
	for i in range(param.get('na')):
		P_i = np.dot( \
			util.get_p_i(i), X).transpose()
		
		# plot trajectory
		ax.plot( P_i[:,0], P_i[:,1], color = param.get('AgentColor'))
		ax.scatter( P_i[0,0], P_i[0,1], color = param.get('AgentColor'), 
			marker = param.get('start_marker'))
		ax.scatter( P_i[-1,0], P_i[-1,1], color = param.get('AgentColor'), 
			marker = param.get('stop_marker'))
Exemple #4
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def plot_ss(x,t, title = None, fig = None, ax = None):

	if fig is None:
		fig, ax = plt.subplots()
		plt.axis('equal')

	if title is not None:
		plt.title(title)		

	# plot agents
	for i in range(param.get('na')):
		p_i = np.dot( \
			util.get_p_i(i), x)
		
		# plot trajectory
		ax.scatter( p_i[0], p_i[1], color = param.get('AgentColor'), 
			marker = param.get('stop_marker'))		

	p_i = dynamics.get_xl(x,t)[0:param.get('nd')]
	ax.scatter( p_i[0], p_i[1], color = param.get('LeaderColor'), 
		marker = param.get('stop_marker'))
	p_i = dynamics.get_xb(x,t)[0:param.get('nd')]
	ax.scatter( p_i[0], p_i[1], color = param.get('BasisColor'), 
		marker = param.get('stop_marker'))
def get_cij(x, t):
    # euclidean distance heuristic
    pl = dynamics.get_xl(x, t)[0:param.get('nd')]
    pb = dynamics.get_xb(x, t)[0:param.get('nd')]
    T = dynamics.get_T(x, t)
    c = np.zeros((param.get('ni'), param.get('ni')))
    for i in range(param.get('ni')):
        # agent positions
        pi = np.dot(util.get_p_i(i), x)

        for j in range(param.get('ni')):
            # extract configuration
            my_1 = np.zeros((param.get('ni'), 1))
            my_1[j] = 1
            my_1 = np.kron(my_1, np.eye(param.get('nd')))
            Tj = np.dot(np.dot(my_1.T, T), my_1)

            # desired positions
            pj = pl + \
             np.dot(Tj,pb)

            c[j, i] = np.linalg.norm(pi - pj)

    return c
Exemple #6
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def plot_scp_iteration_state( Xnl, tX, tX_prev, T, title = None):
	fig, ax = plt.subplots() 
	plt.axis('equal')

	color_na_nl = 'b'
	color_nb_nl = 'g'

	color_na_txt = 'r'
	color_nb_txt = 'c'

	color_na_txtm1 = 'm'
	color_nb_txtm1 = 'y'

	for i in range(param.get('ni')):

		P_i = np.squeeze(np.dot( \
			util.get_p_i(i), Xnl)).transpose()

		if i < param.get('na'):
			color = color_na_nl
		else:
			color = color_nb_nl
		# plot trajectory
		ax.plot( P_i[:,0], P_i[:,1], color = color)
		ax.scatter( P_i[0,0], P_i[0,1], color = color, 
			marker = param.get('start_marker'))
		ax.scatter( P_i[-1,0], P_i[-1,1], color = color, 
			marker = param.get('stop_marker'))
	ax.plot( np.nan, np.nan, color = color_na_nl, label = 'Nonlinear X Free')
	ax.plot( np.nan, np.nan, color = color_nb_nl, label = 'Nonlinear X Control')		

	for i in range(param.get('ni')):
		
		P_i = np.squeeze(np.dot( \
			util.get_p_i(i), tX)).transpose()

		if i < param.get('na'):
			color = color_na_txt
		else:
			color = color_nb_txt
		# plot trajectory
		ax.plot( P_i[:,0], P_i[:,1], color = color)
		ax.scatter( P_i[0,0], P_i[0,1], color = color, 
			marker = param.get('start_marker'))
		ax.scatter( P_i[-1,0], P_i[-1,1], color = color, 
			marker = param.get('stop_marker'))
	ax.plot( np.nan, np.nan, color = color_na_txt, label = 'Linear X Free')
	ax.plot( np.nan, np.nan, color = color_nb_txt, label = 'Linear X Control')		

	for i in range(param.get('ni')):

		P_i = np.squeeze(np.dot( \
			util.get_p_i(i), tX_prev)).transpose()

		if i < param.get('na'):
			color = color_na_txtm1
		else:
			color = color_nb_txtm1
		# plot trajectory
		ax.plot( P_i[:,0], P_i[:,1], color = color)		
		ax.scatter( P_i[0,0], P_i[0,1], color = color, 
			marker = param.get('start_marker'))
		ax.scatter( P_i[-1,0], P_i[-1,1], color = color, 
			marker = param.get('stop_marker'))
	ax.plot( np.nan, np.nan, color = color_na_txtm1, label = 'Prev X Free')
	ax.plot( np.nan, np.nan, color = color_nb_txtm1, label = 'Prev X Control')


	plt.legend()
	plt.title( title)