(* q8ImrC.�'^
Demo for program"RP Fiber Power": thulium-doped fiber laser, �ht�P|�3�B
pumped at 790 nm. Across-relaxation process allows for efficient oVCm�I"��'
population of theupper laser level. *V(Fn-��6(
*) !(* *)注释语句 �(Vg}Hh?p
(c���v!Y=]
diagram shown: 1,2,3,4,5 !指定输出图表 yg]�2e��rR
; 1: "Powersvs. Position" !分号是注释;光纤长度对功率的影响 s=�Q(�C[%I
; 2:"Variation of the Pump Power" !泵浦光功率变化对信号输出功率的影响 E��2�B>b[
; 3:"Variation of the Fiber Length"!信号输出功率vs 光纤长度的变化,仿真最佳光纤长度 @�/%{1�5s.
; 4:"Transverse Profiles" !横向分布,横坐标为半径位置 R�.s|���j=
; 5:"Transition Cross-sections" !不同波长的跃迁横截面,横坐标波长,纵坐标为横截面 �5�.�tv�B�
<�Q<�+4Y{R
include"Units.inc" !读取“Units.inc”文件中内容 Ri>?KrQ�F%
�$\AEWF��B
include"Tm-silicate.inc" !读取光谱数据 A>.2�OC��+
@��tRMe6�4
; Basic fiberparameters: !定义基本光纤参数 #pd�UJ2)yM
L_f := 4 { fiberlength } !光纤长度 Ml>(� tec�
No_z_steps := 50 {no steps along the fiber } !光纤步长,大括号{ }是注释,相当于备注 7m5Co>NkuK
r_co := 6 um { coreradius } !纤芯半径 NN
0Q`r,8}
N_Tm := 100e24 { Tmdoping concentration } !纤芯Tm离子掺杂浓度 �x �O7IzqY
\.e4.[%[2-
; Parameters of thechannels: !定义光信道 ��#ZiT�-��
l_p := 790 nm {pump wavelength } !泵浦光波长790nm 7� gB{I�n0
dir_p := forward {pump direction (forward or backward) } !前向泵浦 �V��SOz.g>
P_pump_in := 5 {input pump power } !输入泵浦功率5W q;AT>" =�)
w_p := 50 um {radius of pump cladding } !包层泵浦相应的半径 50um *��Dr5O�9Y
I_p(r) := (r <=w_p) { pump intensity profile } !泵浦光强度分布 "�M��mf6hu
loss_p := 0 {parasitic losses of pump wave } !泵浦光寄生损耗为0 VanB>|p��6
�#l�1Q��e`
l_s := 1940 nm {signal wavelength } !信号光波长1940nm ZE�bL��L4n
w_s := 7 um !信号光的半径 b�~7drf���
I_s(r) := exp(-2 *(r / w_s)^2) !信号光的高斯强度分布 N�<�z`y�V�
loss_s := 0 !信号光寄生损耗为0 @L�LTB(@wR
��&�S7�4mV
R_oc := 0.70 {output coupler reflectivity (right side) } !输出耦合反射率 A~l�Ia$U$b
klWY�uStZ�
; Function for defining themodel: !定义模型函数,一定要有calc命令,否则函数只会被定义,但不会被执行 %c^ m��\�E
calc �x�k�~Nmb}
begin -p�TI���?�
global allow all; !声明全局变量 #�WE]`z�d�
set_fiber(L_f, No_z_steps, ''); !光纤参数 8
|h9sn;P
add_ring(r_co, N_Tm); S��T8!i`Q$
def_ionsystem(); !光谱数据函数 :���cp ���
pump := addinputchannel(P_pump_in, l_p,'I_p', loss_p, dir_p); !泵浦光信道 dY�OF2si~%
signal_fw := addinputchannel(0, l_s, 'I_s',loss_s, forward); !前向信号光信道 g�8pm�2o@S
signal_bw := addinputchannel(0, l_s, 'I_s',loss_s, backward); !后向信号光信道 2Eh@e([PMs
set_R(signal_fw, 1, R_oc); !设置反射率函数 :,*eX�' fH
finish_fiber(); HW�7FP]NH�
end; a}�.Y!O�&�
jOtX
6�0;�
; Display someoutputs in the Output window (on the right side): !在Output aera区域显示输出 sM\&�.��<B
show "Outputpowers:" !输出字符串Output powers: S-E++f9D~�
show"pump: ", P_out(pump):d3:"W" !输出字符串pump:和计算值(格式为3个有效数字,单位W) ]jM^Z.m�I+
show"signal: ",P_out(signal_fw):d3:"W" !输出字符串signal:和计算值(格式为3个有效数字,单位W) 9]_GN�k�-D
n�b�vk�P�
W��7G9Kx1Y
; ------------- 2D�MrMmLI�
diagram 1: !输出图表1 J l7z|Q�S�
�& QZV��q"
"Powers vs.Position" !图表名称 �@e�Qld\h'
w;�`m- 9<Y
x: 0, L_f !命令x: 定义x坐标范围 h�H+bt!aH�
"position infiber (m)", @x !x轴标签;@x 指示这些字符串沿坐标轴放置 �q/6�UK =�
y: 0, 15 !命令y: 定义y坐标范围 @Y'�I,e��
y2: 0, 100 !命令y2: 定义第二个y坐标范围 �fCEz-TMW
frame !frame改变坐标系的设置 + Oo�b�b-v
legpos 600, 500 !图行在图表窗口中的位置(相对于左上角而言) "xwM+���AC
hx !平行于x方向网格 ~o�i�_r8�K
hy !平行于y方向网格 +��*E�KR��
h$h]%��y��
f: P(pump, x), !命令f: 定义函数图;P(pump, x)函数是计算x位置处的泵浦光功率 a[O���6YgO
color = red, !图形颜色 g_D-(J`IK,
width = 3, !width线条宽度 $�@�87?Ab�
"pump" !相应的文本字符串标签 -ID!pT��vW
f: P(signal_fw, x), !P(signal_fw ,x) 函数是计算x位置处的前向信号光功率 d�m�^H5D/A
color = blue, !�7�`� [�i
width = 3, �I($,9|9�F
"fw signal" $N.`�)�S<�
f: P(signal_bw, x), !P(signal_bw ,x) 函数是计算x位置处的后向信号光功率 ujx-jI�hT_
color = blue, �{
R*Y�=Ie
style = fdashed, �3&��J&^�O
width = 3, ;m�JkqbVol
"bw signal" )}�|mDN&P
Q#rt<S�1zW
f: 100 * n(x, 2), !n(x ,2) 函数是计算x位置处激活粒子数在能级2上的占比 H�h�f72�IX
yscale = 2, !第二个y轴的缩放比例 BRtXf�0~&p
color = magenta, Kx]�> fHK
width = 3, dM|g`r�r
E
style = fdashed, 2YIF=YWO},
"n2 (%, right scale)" F��X� 1C
e
�
�<q�n,��
f: 100 * n(x, 3), !n(x ,3) 函数是计算x位置处激活粒子数在能级3上的占比 mmN|F�$;�r
yscale = 2, tP�]�q�4i�
color = red, |a(Q4 �e/,
width = 3, <���P �pYl
style = fdashed, OW�V/kz5'H
"n3 (%, right scale)" �8�?Wgawx
9�}n��,@@�
h3t$>vs2F"
; ------------- |�LFUzq>j�
diagram 2: !输出图表2 ��oWrE2U;�
k.>6nho`TV
"Variation ofthe Pump Power" z+�6QZ��Qk
5���vGi�oO
x: 0, 10 =L16h�Dk o
"pump inputpower (W)", @x C@)��pmS�Q
y: 0, 10 8|vld3;���
y2: 0, 100 !c_u-&��b)
frame y1Z�1=U*!
hx '{^�8_k\}B
hy #[,= 1Od(q
legpos 150, 150 �:�tlE`BIp
k1wr/G�'H[
f: (set_P_in(pump, x);P_out(signal_fw)), !set_P_in(pump,x)改变泵浦信道功率;P_out(signal_fw)输出前向信号光 �r�:�#Q9EA
step = 5, 3�*2I$e!Jt
color = blue, x�.G"�D(��
width = 3, ��4[_L=�zD
"signal output power (W, leftscale)", !相应的文本字符串标签 r+��TK5|ke
finish set_P_in(pump, P_pump_in) e7's)�C>/'
_y-B";Vmm
f: (set_P_in(pump,x); 100 * n_av(2)), !改变泵浦信号功率对能级2上激活粒子占比的影响 ~%KM��3Vap
yscale = 2, �EJ�8I��[(
step = 5, rV �U:VL`2
color = magenta, \L�
�%q�[
width = 3, ky���K�'��
"population of level 2 (%, rightscale)", O�T�%V�{hD
finish set_P_in(pump, P_pump_in) �,$PFI(Whk
'oC�m.~;�_
f: (set_P_in(pump,x); 100 * n_av(3)), !改变泵浦信号功率对能级3上激活粒子占比的影响 @j��KDj�]\
yscale = 2, A8mlw#`E8b
step = 5, R�C�Cv>�o�
color = red, ��c G*(C��
width = 3, 4D� GY6PS
"population of level 3 (%, rightscale)", fo�;6hu�z
finish set_P_in(pump, P_pump_in) t,�1in�4sN
�zw<�
4G[u
�[t�O�uNj:
; ------------- jF4�c�sO=E
diagram 3: !输出图表3 |��""=)-5N
�>kZ6f�4�
"Variation ofthe Fiber Length" ��hX�Po�cP
�Y[�h#h�Z
x: 0.1, 5 J2'�W =r_#
"fiber length(m)", @x htV#5�SUx&
y: 0, 10 ��W?=$V>)�
"opticalpowers (W)", @y FQ0KU��b}0
frame PaxK^���*�
hx 0�K/G&c?;=
hy b h���*^�{
@~��s~�/[
f: (set_L(x);P_out(signal_fw)), !改变光纤长度对信号光输出功率的影响 / �=-6�:L�
step = 20, U>in2u��9
color = blue, |G)�Y8 #D�
width = 3, 64h_�1,��U
"signal output" !��e&r�VoA
rAM�*\�=�
;f: (set_L(x);P_out(pump)), !改变光纤长度对泵浦信号输出功率的影响 �}��'DC
�Q
step = 20, color = red, width = 3,"residual pump" �_Q)�d+F�l
�u�0s'�6�=
! set_L(L_f) {restore the original fiber length } @81-kd�T�x
#U�BB
l�E#
G �l�_\�Vy
; ------------- B�>sCP"/uV
diagram 4: !输出图表4 �W=UqX{-j)
�� oHO��W5
"TransverseProfiles" B;S�z�uCW�
�DCt\��E/�
I_max :=maxr(I(pump, -1, 0, 0), I(signal_fw, -1, 0, 0)) T<f2\q8Uo=
�8�~.iuFp
x: 0, 1.4 * r_co /um ]7v�8�1G5E
"radialposition (µm)", @x �Wx}M1&d/J
y: 0, 1.2 * I_max *cm^2 L{Q4=p,�A�
"intensity (W/ cm²)", @y O�%fUm0O d
y2: 0, 1.3 * N_Tm l6V%"L�o/)
frame ] �xb]8�]�
hx v�c )9�Re$
hy K*HCFqr�U"
i�D�.0J��/
f: N_dop(1, x * um,0), !掺杂浓度的径向分布 ��ax<g0=^R
yscale = 2, *�e%�Dg�{_
color = gray, 3T"��#T&eL
width = 3, �1$);V,DK!
maxconnect = 1, ��'Bq�rJfv
"N_dop (right scale)" aF,j�J}�On
jo<>H�c{g>
f: I(pump, -1, x *um, 0) * cm^2, !泵浦光沿光纤径向的强度分布 `<�S/�?I�8
color = red, �9!5b2!J�L
maxconnect = 1, !限制图形区域高度,修正为100%的高度 -E�6J��f$�
width = 3, �N� )'8o}E
"pump" ?hxK/%�)��
�6
M*�b�6�
f: I(signal_fw, -1,x * um, 0) * cm^2, !信号光沿光纤径向的强度分布 CKx�\V�+\O
color = blue, :-$c�dZ3E
maxconnect = 1, /z��/��hUa
width = 3, '&�N�: �S-
"signal" K���m[]^;6
?�UxG�/]",
GEh�dk]<a7
; ------------- )\um�"l*\c
diagram 5: !输出图表5 \�k|_&�h�G
h~,x7]�w6�
"TransitionCross-sections" B1x'�5S;Bq
Z"l`e0��{�
I_max :=maxr(I(pump, -1, 0, 0), I(signal_fw, -1, 0, 0)) �Z��~duJsH
$|>6��z_3%
x: 1450, 2050 UVc�>i�9,0
"wavelength(nm)", @x ��Q��e7"�Z
y: 0, 0.6 *d^�9,GGn-
"cross-sections(1e-24 m²)", @y !8wZw68"��
frame imo'��(j�7
hx X=fPGy��hZ
hy �`DI�{wqV9
)�3k)�2X�F
f: s12_Tm(x * nm) /1e-24, !Tm3+吸收截面与波长的关系 �JOA%Y;`<#
color = red, \�%w7D6dEZ
width = 3, @uQ�%o%Ru6
"absorption" w;lx:j!Vp$
f: s21_Tm(x * nm) /1e-24, !Tm3+发射截面与波长的关系 +�#|�'|}�j
color = blue, ��on]\�J
width = 3, &�T��f=~6�
"emission" L@C >�-F|p
N5:D8oWWXR
