def test_spacetime_evals(self):
"""consistency tests of the space time discretization
"""
ay = self.ay
my = self.my
zsol = np.zeros((self.Nq, self.Nts))
contimsol = self.contimsol
linspasol = self.linspasol
dms = gpu.get_dms(sdim=self.Ns, tmesh=self.tmesh, basfuntype='pl')
(msx, ms) = gpu.get_genmeasuremat(sol=zsol,
tmesh=self.tmesh,
sdim=self.Ns)
self.assertTrue(np.allclose(ms, self.ms))
contimlinspa = np.kron(contimsol, linspasol)
lintimlinspa = np.kron(self.lintimsol, linspasol)
self.assertTrue(norm(contimlinspa) > 1e-8)
self.assertTrue(np.allclose(0 * contimsol, np.dot(dms, contimsol)))
# check the dtpart to be zero for const time funcs and nonzero for lin
dtpart = spu.apply_time_space_kronprod(tvvec=contimlinspa,
smat=dms,
qmat=np.array(my.todense()))
self.assertTrue(np.allclose(0 * contimlinspa, dtpart))
dtpart = spu.apply_time_space_kronprod(tvvec=lintimlinspa,
smat=dms,
qmat=np.array(my.todense()))
self.assertTrue(norm(dtpart) > 1e-8)
# check the a-part to be zero for lin (except from the boundary)
# and nonzero for quad
lintimlinspaqua = np.kron(self.lintimsol, linspasol * linspasol)
dxxpart = spu.apply_time_space_kronprod(tvvec=lintimlinspa,
smat=ms,
qmat=np.array(ay.todense()))
innernode = np.r_[0, np.ones((self.Nq - 2, )), 0]
inds = np.tile(innernode, self.Ns).astype(bool)
self.assertTrue(np.allclose(0 * contimlinspa[inds], dxxpart[inds]))
dxxpart = spu.\
apply_time_space_kronprod(tvvec=lintimlinspaqua, smat=ms,
qmat=np.array(ay.todense()))
self.assertTrue(norm(dxxpart[1:-1]) > 1e-8)
def setUp(self):
self.Nq = 50 # dimension of the spatial discretization
self.Ns = 9 # dimension of the temporal discretization
self.Nts = 60 # number of time sampling points
self.nu = 1e-2
self.t0, self.tE = 0., 1.
self.mockUky = np.eye(self.Nq)
self.mockUks = np.eye(self.Ns)
(M, A, rhs, nfunc, femp) = dbs.\
burgers_spacedisc(N=self.Nq+1, nu=self.nu, retfemdict=True)
# +1 bc of boundary conditions that are eliminated
self.femp, self.ay, self.my = femp, A, M
self.tmesh = np.linspace(self.t0, self.tE, self.Nts)
# constructing test solutions
self.contimsol = np.ones((self.Ns, 1))
self.conspasol = np.ones((self.Nq, 1))
self.linspasol = np.linspace(0, 1, self.Nq).reshape((self.Nq, 1))
self.lintimsol = np.linspace(0, 1, self.Ns).reshape((self.Ns, 1))
self.dms = gpu.get_dms(sdim=self.Ns, tmesh=self.tmesh, basfuntype='pl')
self.ms = gpu.get_ms(sdim=self.Ns, tmesh=self.tmesh, basfuntype='pl')
def testit(Nq=None,
Nts=None,
inivtype=None,
dmndct=None,
Ns=None,
hq=None,
hs=None,
spacebasscheme=None,
nu=None,
alpha=None,
genpodstate=False,
genpodadj=False,
genpodcl=False,
plotplease=False,
tikzplease=False,
tikzprefikz='',
adjplotdict=None,
target='inival',
onlytimings=False,
**kwargs):
t0, tE = dmndct['t0'], dmndct['tE']
# to tikz or not to tikz
fullmodelv_tkzf, fullmodelL_tkzf, redoptiv_tkzf = None, None, None
redmodelL_tkzf = None
redmodelV_tkzf = None
redoptlambda_tkzf, backcheck_tkzf = None, None
if tikzplease:
fullmodelv_tkzf = tikzprefikz + 'fullmodelV'
fullmodelL_tkzf = tikzprefikz + 'fullmodelL'
redmodelL_tkzf = tikzprefikz + 'redmodelL'
redmodelV_tkzf = tikzprefikz + 'redmodelV'
# redoptiv_tkzf = tikzprefikz + 'redoptiv'
# redoptlambda_tkzf = tikzprefikz + 'redoptlambda'
backcheck_tkzf = tikzprefikz + 'backcheck'
tmesh = np.linspace(t0, tE, Nts)
snapshottmesh = np.linspace(t0, tE, Ns)
if target == 'inival':
def vstar(t):
return iniv.flatten()
elif target == 'heart' or 'invheart':
invertt = True if target == 'invheart' else False
myheartfun = get_spcheartfun(NY=Nq - 1, invertt=invertt)
def vstar(t):
return myheartfun(t).flatten()
# ### define the model
x0, xE = dmndct['x0'], dmndct['xE']
(My, A, rhs, nfunc, femp) = dbs.\
burgers_spacedisc(N=Nq, nu=nu, x0=x0, xE=xE, retfemdict=True)
# define the initial value
if inivtype == 'smooth':
xrng = np.linspace(0, 2 * np.pi, Nq - 1)
iniv = 0.5 - 0.5 * np.sin(xrng + 0.5 * np.pi)
iniv = 0.5 * iniv.reshape((Nq - 1, 1))
elif inivtype == 'step':
# iniv = np.r_[np.ones(((Nq-1)/2, 1)), np.zeros(((Nq)/2, 1))]
iniv = np.r_[np.zeros(((Nq) / 2, 1)), np.ones(((Nq - 1) / 2, 1))]
elif inivtype == 'ramp':
iniv = np.r_[np.linspace(0, 1, ((Nq - 1) / 2)).reshape(
((Nq - 1) / 2, 1)),
np.zeros(((Nq) / 2, 1))]
elif inivtype == 'zero':
iniv = np.zeros((Nq - 1, 1))
# ### compute the forward snapshots
def fwdrhs(t):
return rhs
simudict = dict(iniv=iniv, A=A, M=My, nfunc=nfunc, rhs=fwdrhs, tmesh=tmesh)
with dou.Timer('fwd'):
datastr = 'data/fwdsol_iniv' + inivtype + '_target_' + target +\
'Nq{0}Nts{1}nu{2}'.format(Nq, Nts, nu)
vv = dou.load_or_comp(filestr=datastr,
comprtn=gpu.time_int_semil,
arraytype='dense',
comprtnargs=simudict,
debug=debug)
# vv = gpu.time_int_semil(**simudict)
if plotplease:
plotmat(vv, fignum=1234, tikzfile=fullmodelv_tkzf, **dmndct)
(xms, Ms) = gpu.get_genmeasuremat(sol=vv.T, tmesh=tmesh, sdim=Ns)
# ### compute the backward snapshots
if genpodadj or genpodcl:
_vfun = interp1d(tmesh, vv, axis=0) # , fill_value='extrapolate')
def vfun(t):
if t < tmesh[0]:
return _vfun(tmesh[0])
elif t > tmesh[-1]:
return _vfun(tmesh[-1])
else:
return _vfun(t)
vdxoperator, fnctnl = dbs.\
burgers_bwd_spacedisc(V=femp['V'], ininds=femp['ininds'],
diribc=femp['diribc'])
te = tmesh[-1]
def burger_bwd_rhs(t):
# TODO: -----------------------------> here we need vstar
return -fnctnl(vfun(te - t)).flatten() + fnctnl(
vstar(te - t)).flatten()
def burger_bwd_nonl(lvec, t):
vdx = vdxoperator(vfun(te - t))
return -(vdx * lvec).flatten()
termiL = np.zeros((Nq - 1, 1))
bbwdsimudict = dict(iniv=termiL,
A=A,
M=My,
nfunc=burger_bwd_nonl,
rhs=burger_bwd_rhs,
tmesh=tmesh)
with dou.Timer('bwd'):
datastr = 'data/bwdsol_iniv' + inivtype + '_target' + target +\
'Nq{0}Nts{1}nu{2}'.format(Nq, Nts, nu)
bwdll = dou.\
load_or_comp(filestr=datastr, comprtn=gpu.time_int_semil,
arraytype='dense', comprtnargs=bbwdsimudict,
debug=debug)
# bwdll = gpu.time_int_semil(**bbwdsimudict)
ll = np.flipud(bwdll) # flip the to make it forward time
if plotplease:
if adjplotdict is None:
adjplotdict = dmndct
plotmat(ll, fignum=1235, tikzfile=fullmodelL_tkzf, **adjplotdict)
(Lms, _) = gpu.get_genmeasuremat(sol=ll.T, tmesh=tmesh, sdim=Ns)
else:
Lms = None
# ### compute the projection matrices, i.e. optimal bases
(lyitUVy, lyUVy, lsitUVs, lsUVs, lyitULy, lyULy, lsitULs,
lsULs) = stateadjspatibas(xms=xms,
lms=Lms,
Ms=Ms,
My=My,
nspacevecs=hq,
ntimevecs=hs,
spacebasscheme=spacebasscheme)
# ### the fwd projection scheme
AVk, MVk, nonl_red, rhs_red, liftcoef, projcoef =\
gpu.get_spaprjredmod(M=My, A=A, nonl=nfunc, rhs=fwdrhs,
Uk=lyitUVy, prjUk=lyUVy)
hiniv = projcoef(iniv)
Ms = sps.csc_matrix(gpu.get_ms(sdim=Ns, tmesh=tmesh))
dms = sps.csc_matrix(gpu.get_dms(sdim=Ns, tmesh=tmesh))
Vhms = np.dot(lsitUVs.T, Ms * lsitUVs)
Vhdms = np.dot(lsitUVs.T, dms * lsitUVs)
print 'assembling the reduced tensor...'
datastr = 'data/fwd_iniv' + inivtype + '_tnsr_' + spacebasscheme + \
'_target_' + target +\
'_Nts{5}Nq{0}Ns{1}hq{2}hs{3}nu{4}'.format(Nq, Ns, hq, hs, nu, Nts)
uvvdxl, htittl = bgu.\
get_burger_tensor(Uky=lyitUVy, Uks=lsitUVs, sdim=Ns, bwd=True,
Vhdms=Vhdms, Vhms=Vhms, Vhmy=MVk, Vhay=AVk,
tmesh=tmesh, datastr=datastr, debug=debug, **femp)
vres, vresprime = \
bou.setup_burger_fwdres(Vhdms=Vhdms, Vhms=Vhms, Vhmy=MVk, Vhay=AVk,
htittl=htittl, uvvdxl=uvvdxl, hiniv=hiniv)
def ndvresprime(tvvec):
ndjaco = nd.Jacobian(vres)(tvvec)
return ndjaco
# ### the bwd projection scheme
if genpodadj or genpodcl:
Lhms = np.dot(lsitULs.T, Ms * lsitULs)
Lhdms = np.dot(lsitULs.T, dms * lsitULs)
LVhms = np.dot(lsitULs.T, Ms * lsitUVs)
LVhmy = np.dot(lyitULy.T, My * lyitUVy)
Lhay, Lhmy, _, _, Lliftcoef, Lprojcoef =\
gpu.get_spaprjredmod(M=My, A=A, Uk=lyitULy, prjUk=lyULy)
print 'assembling the bwd reduced tensor...'
datastr = 'data/bwdtnsr_iniv' + inivtype + '_' + spacebasscheme +\
'_target_' + target +\
'_Nts{5}Nq{0}Ns{1}hq{2}hs{3}nu{4}'.format(Nq, Ns, hq, hs, nu, Nts)
Luvvdxl, Lhtittl = bgu.\
get_burger_tensor(Uky=lyitULy, bwd=True, Uks=lsitULs,
Ukyconv=lyitUVy, Uksconv=lsitUVs, sdim=Ns,
tmesh=tmesh, datastr=datastr, debug=debug,
**femp)
tgtst = gou.xvectoX(gou.functovec(vstar, snapshottmesh),
ns=Ns,
nq=Nq - 1)
htgst = np.dot(lyUVy.T, np.dot(tgtst, lsUVs))
htgstvec = Xtoxvec(htgst)
hcurst = np.dot(lyUVy.T, np.dot(xms, lsitUVs))
hcurstvec = Xtoxvec(hcurst)
htermiL = np.zeros((hq, 1))
lres, lresprime = bou.\
setup_burger_bwdres(Lhdms=Lhdms, Lhms=Lhms, Lhmy=Lhmy, Lhay=Lhay,
LVhms=LVhms, LVhmy=LVhmy,
Lhtittl=Lhtittl, Luvvdxl=Luvvdxl,
hiniv=hiniv, htermiL=htermiL,
tsVvec=hcurstvec[hq:, :], tsVtrgtvec=htgstvec)
# ### the optimal cont problem
VLhms = np.dot(lsitUVs.T, Ms * lsitULs)
VLhmy = np.dot(lyitUVy.T, My * lyitULy)
clres, clresprime = bou.\
setup_burger_clres(Vhdms=Vhdms, Vhms=Vhms, Vhmy=MVk, Vhay=AVk,
VLhms=VLhms, VLhmy=VLhmy, alpha=alpha,
htittl=htittl, uvvdxl=uvvdxl,
tsVtrgtvec=htgstvec,
Lhdms=Lhdms, Lhms=Lhms, Lhmy=Lhmy, Lhay=Lhay,
LVhms=LVhms, LVhmy=LVhmy,
Lhtittl=Lhtittl, Luvvdxl=Luvvdxl,
hiniv=hiniv, htermiL=htermiL)
# ### the tests
# # forward problem
if genpodstate:
optiniV = np.tile(hiniv.T, hs - 1).T
print 'solving the optimization problem (state)...'
sol = spacetimesolve(func=vres,
funcjaco=vresprime,
inival=optiniV,
message='fwd problem - analytical jacobian')
optiV = np.r_[hiniv.flatten(), sol]
optiV = optiV.reshape((hs, hq))
if plotplease:
plotmat((np.dot(lyitUVy, np.dot(optiV.T, lsitUVs.T))).T,
tikzfile=redmodelV_tkzf,
fignum=1233,
**dmndct)
if genpodadj:
optiniL = np.zeros((hq * (hs - 1), 1))
print 'solving the optimization problem (adjoint)...'
sol = spacetimesolve(func=lres,
funcjaco=lresprime,
inival=optiniL,
message='bwd problem - analytical jacobian')
optiL = np.r_[sol, htermiL.flatten()]
optiL = optiL.reshape((hs, hq))
if plotplease:
plotmat((np.dot(lyitULy, np.dot(optiL.T, lsitULs.T))).T,
fignum=124,
tikzfile=redmodelL_tkzf,
**adjplotdict)
if genpodcl:
print 'solving the optimization problem (fwdbwd)...'
fwdbwdini = True
if fwdbwdini:
hcurst = np.dot(lyUVy.T, np.dot(xms, lsitUVs))
hcurstvec = gou.Xtoxvec(hcurst)
# plotmat((np.dot(lyitUVy,
# np.dot(gou.xvectoX(hcurstvec, nq=hq, ns=hs),
# lsitUVs.T))).T, fignum=9999)
optiniL = np.zeros((hq * (hs - 1), 1))
hcuradj = np.dot(lyULy.T, np.dot(Lms, lsitULs))
hcuradjvec = gou.Xtoxvec(hcuradj)
# plotmat((np.dot(lyitULy,
# np.dot(gou.xvectoX(hcuradjvec, nq=hq, ns=hs),
# lsitULs.T))).T, fignum=9998)
optiniV = hcurstvec[hq:, :]
optiniL = hcuradjvec[:-hq, :]
else:
optiniV = np.zeros((hq * (hs - 1), 1))
optiniL = np.zeros((hq * (hs - 1), 1))
optiniVL = np.vstack([optiniV, optiniL])
sol, timingsdict = \
spacetimesolve(func=clres, funcjaco=clresprime, inival=optiniVL,
message='optcont problem - analytical jacobian',
timerecord=True)
if onlytimings:
return timingsdict
optiV = np.r_[hiniv.flatten(), sol[:hq * (hs - 1)]]
optiV = optiV.reshape((hs, hq))
optiL = np.r_[sol[-hq * (hs - 1):], htermiL.flatten()]
optiL = optiL.reshape((hs, hq))
fulloptiL = (np.dot(lyitULy, np.dot(optiL.T, lsitULs.T))).T
if plotplease:
plotmat((np.dot(lyitUVy, np.dot(optiV.T, lsitUVs.T))).T,
tikzfile=redoptiv_tkzf,
fignum=123,
**dmndct)
plotmat(1. / alpha * fulloptiL,
tikzfile=redoptlambda_tkzf,
fignum=1241,
**dmndct)
plotmat(fulloptiL,
tikzfile=redoptlambda_tkzf,
fignum=12411,
**dmndct)
# ### SECTION: fwd problem with reduced costates
redmodu = 1. / alpha * fulloptiL
redmodufun = interp1d(snapshottmesh, redmodu, axis=0)
def burger_contrl_rhs(t):
if t > tE: # the integrator may require values outside [t0, tE]
return fnctnl(redmodufun(tE)).flatten()
else:
return fnctnl(redmodufun(t)).flatten()
simudict = dict(iniv=iniv,
A=A,
M=My,
nfunc=nfunc,
rhs=burger_contrl_rhs,
tmesh=snapshottmesh)
print 'back check...'
with dou.Timer('check back'):
vv = gpu.time_int_semil(**simudict)
if plotplease:
plotmat(vv, fignum=12341, tikzfile=backcheck_tkzf, **dmndct)
vvd = vv - tgtst.T
plotmat(vvd, fignum=12342, **dmndct)
plotmat(tgtst.T,
fignum=12343,
tikzfile=tikzprefikz + 'zstar',
**dmndct)
valdict = eva_costfun(vopt=Xtoxvec(vv.T),
uopt=Xtoxvec(redmodu),
qmat=My,
rmat=alpha * My,
ms=Ms,
vstar=vstar,
tmesh=snapshottmesh)
valdict.update(dict(unormsqrd=2 * 1. / alpha * valdict['uterm']))
logger.info('Value of the cost functional: {0}'.format(
valdict['value']))
return valdict, timingsdict
else:
return None, None
# plotmat(vv)
ared, mred, nonlred, rhsred, inired, Uky = gpu.\
get_podred_model(M=M, A=A, nonl=nfunc, rhs=rhs,
sol=vv.T, tmesh=tmesh, verbose=True,
poddim=hq, sdim=Ns, plotsvs=plotsvs,
genpod=True, basfuntype='pl')
inivred = np.dot(Uky.T, iniv)
(msx, ms) = gpu.get_genmeasuremat(sol=vv.T, tmesh=tmesh, sdim=Ns)
x = lau.apply_massinv(sps.csc_matrix(ms), msx.T).T
sini = np.r_[1, np.zeros((Ns - 1, ))].reshape((Ns, 1))
xz = np.copy(x)
xz[:, 0] = 0 # zero out nu0 - the ini condition needs extra treatment
Uks = gpu.get_podmats(sol=xz.T, poddim=hs - 1, plotsvs=False, M=M)
Uks = np.hstack([sini, Uks])
dms = gpu.get_dms(sdim=Ns, tmesh=tmesh, basfuntype='pl')
hdms = np.dot(Uks.T, np.dot(dms, Uks))
hms = np.dot(Uks.T, np.dot(ms, Uks))
# nres, timespaceres = get_spacetimepodres(tvvec=hshysol, dms=hdms, ms=hms,
# my=mred, ared=None,
# nfunc=None, rhs=None)
# trsrs = timespaceres.reshape((hq, hs))
# plotmat((np.dot(Uky, np.dot(trsrs, Uks.T))).T, fignum=121)
def sollintimspasys(dms=None,
ms=None,
ay=None,
my=None,
iniv=None,
opti=False):
linsimudict = dict(iniv=iniv, A=A, M=My, nfunc=None,
rhs=rhs, tmesh=tmesh)
vvl = dou.\
load_or_comp(filestr='data/lincase_'+datastr, comprtn=gpu.time_int_semil,
comprtnargs=linsimudict, arraytype='dense', debug=True)
if plotplease:
plotmat(vvl, fignum=125)
(msxlin, Ms) = gpu.get_genmeasuremat(sol=vvl.T, tmesh=tmesh, sdim=Ns)
xlin = lau.apply_massinv(sps.csc_matrix(Ms), msxlin.T).T
if not redmodel:
Ukylin, Ukslin = np.eye(Nq-1), np.eye(Ns)
hs, hq = Ns, Nq-1
Ms = gpu.get_ms(sdim=Ns, tmesh=tmesh, basfuntype='pl')
dms = gpu.get_dms(sdim=Ns, tmesh=tmesh, basfuntype=timebasfuntype)
rbd = dict(hmy=My.todense(), hay=A.todense(), hms=Ms, hdms=dms,
inivred=iniv, hrhs=rhs, hnonl=nfunc)
else:
Ukylin, Ukslin = gpu.get_timspapar_podbas(hs=hs, hq=hq, plotsvs=plotplease,
My=My, Ms=Ms, snapsl=[xlin])
rbd = get_podredmod_burger(Uky=Uky, Uks=Uks, Nq=Nq,
nu=nu, iniv=iniv, nustr=nustr)
dmsz = rbd['hdms'][1:, :1] # part of the mass matrix related to the ini value
msz = rbd['hms'][1:, :1]
dmsI = rbd['hdms'][1:, 1:] # mass matrices w/o ini values (test and trial)
msI = rbd['hms'][1:, 1:]
def get_podredmod_burger(Uky=None,
Uks=None,
nu=None,
iniv=None,
Nq=None,
plotsvs=False,
Ns=None,
tmesh=None,
timebasfuntype=None,
datastr=None):
''' get the coeffs of the space/time reduced Burgers model
Parameters
---
Uky : (Ny, hy) np.array
containing the POD vectors in space dimension
Uks : (Ns, hs) np.array
containing the POD vectors in time dimension
nu : float
the considered viscosity
iniv : (Ny, 1) np.array
the initial value
Returns
---
redburgdict : dictionary
a dictionary with the following keys coeffs of the reduced system:
* `hmy`: space mass matrix
* `hay`: space stiffness matrix
* `hms`: time mass matrix
* `hdms`: time derivative mass matrix
* `inivred`: initial value
* `uvvdxl`: the space component of the burger nonlinearity
* `htittl`: the time component of the burger nonlinearity
* `hnonl`: f(t, v) that returns the value of the nonlinearity
* `hrhs`: right hand side
* `nonlresjacobian`: f(v) that returns the Jacobian
of the residual of the genpod burger approximation
Examples
---
redburgdict = get_podredmod_burger(Uky=x, Uks=x, Ms=x, curnu=1e-2, iniv=x)
'''
retdict = {}
# get the space full model for the considered `nu`
(M, A, rhs, nfunc, femp) = dbs.\
burgers_spacedisc(N=Nq, nu=nu, retfemdict=True)
# reducing the linear parts and the rhs
ared, mred, _, rhsred, _, _ = gpu.\
get_podred_model(M=M, A=A, rhs=rhs, Uk=Uky)
retdict.update(
dict(hay=ared, hmy=mred, inivred=np.dot(Uky.T, iniv), hrhs=rhsred))
# the time reduced model
# TODO: this should be synchronized with comp of Ms
Ms = gpu.get_ms(sdim=Ns, tmesh=tmesh, basfuntype=timebasfuntype)
dms = gpu.get_dms(sdim=Ns, tmesh=tmesh, basfuntype=timebasfuntype)
hdms = np.dot(Uks.T, np.dot(dms, Uks))
hms = np.dot(Uks.T, np.dot(Ms, Uks))
retdict.update(dict(hdms=hdms, hms=hms))
uvvdxl, htittl = get_burger_tensor(Uky=Uky,
Uks=Uks,
datastr=datastr,
sdim=Ns,
tmesh=tmesh,
**femp)
retdict.update(dict(uvvdxl=uvvdxl, htittl=htittl))
def burger_rednonl(tvvec):
return eva_burger_quadratic(tvvec=tvvec,
htittl=htittl,
uvvdxl=uvvdxl,
iniv=None,
retjacobian=False)
hdmsI = hdms[1:, 1:] # mass matrices w/o ini values (test and trial)
hmsI = hms[1:, 1:]
solmat = np.kron(hdmsI, mred) + np.kron(hmsI, ared)
def nlrprime(tsvec, curiniv=None):
if curiniv is not None:
try:
tvvecini = np.vstack([curiniv, tsvec])
except ValueError:
tvvecini = np.vstack([curiniv, tsvec.reshape((tsvec.size, 1))])
ebmat = eva_burger_quadratic(tvvec=tvvecini,
htittl=htittl,
uvvdxl=uvvdxl,
retjacobian=True)
ebmat = ebmat[curiniv.size:, curiniv.size:, ]
return solmat + ebmat
retdict.update(dict(hnonl=burger_rednonl, nonlresjacobian=nlrprime))
return retdict
from gen_pod_utils import hatfuncs, get_dms import matplotlib.pyplot as plt import numpy as np x0, xe, N = 0, 1, 100 n = 50 dhf, pts = hatfuncs(n=n, x0=x0, xe=xe, N=N, df=True) x = np.linspace(x0, xe, 4 * N + 1) dhfx = dhf(x) dmy = get_dms(sdim=10, tmesh=x) plt.plot(x, dhfx) plt.show()
