add note 20251001

code/adjoint/input_adj_mod.f

@@ -18,23 +18,23 @@
 !
 !  Module Routines:
 !  ============================================================================
-!  (1 ) READ_INPUT_ADJ_FILE   : Driver routine for reading GEOS-CHEM input file
+!  (1 ) READ_INPUT_ADJ_FILE   : Driver routine for reading GEOS-CHEM input file 读取 GC 输入文件
-!  (2 ) READ_ONE_LINE         : Reads one line at a time
+!  (2 ) READ_ONE_LINE         : Reads one line at a time 一次读取一行
-!  (3 ) SPLIT_ONE_LINE        : Splits one line into substrings (by spaces)
+!  (3 ) SPLIT_ONE_LINE        : Splits one line into substrings (by spaces) 通过空格分割文本
-!  (4 ) READ_ADJ_SIMULATION_MENU  : Reads the GEOS-Chem adjoint simulation menu
+!  (4 ) READ_ADJ_SIMULATION_MENU  : Reads the GEOS-Chem adjoint simulation menu 读取伴随设定
-!  (5 ) READ_FWD_MODEL_MENU   : Reads forward model options
+!  (5 ) READ_FWD_MODEL_MENU   : Reads forward model options 读取正向模拟选项
-!  (6 ) READ_ADJ_OPTIONS_MENU : Reads adjoint model options
+!  (6 ) READ_ADJ_OPTIONS_MENU : Reads adjoint model options 读取伴随模式选项
-!  (7 ) READ_ADJ_DIRECTORIES_MENU  : Reads the GEOS-Chem adj. directories
+!  (7 ) READ_ADJ_DIRECTORIES_MENU  : Reads the GEOS-Chem adj. directories 读取 GC 伴随路径
-!  (8 ) READ_CONTROL_VARS_MENU: Reads what are control variables
+!  (8 ) READ_CONTROL_VARS_MENU: Reads what are control variables 读取控制变量
-!  (9 ) READ_OBSERVATION_MENU : Reads vars related to observations
+!  (9 ) READ_OBSERVATION_MENU : Reads vars related to observations 读取观测相关变量
-!  (10) READ_FD_ MENU         : Reads finite difference test variables
+!  (10) READ_FD_ MENU         : Reads finite difference test variables 读取有限差分测试变量
-!  (11) READ_ADJ_DIAGNOSTICS_MENU : Reads the GEOS-Chem adj. diagnostic menu
+!  (11) READ_ADJ_DIAGNOSTICS_MENU : Reads the GEOS-Chem adj. diagnostic menu 读取伴随诊断菜单
-!  (12) VALIDATE_DIRECTORIES  : Makes sure all given directories are valid
+!  (12) VALIDATE_DIRECTORIES  : Makes sure all given directories are valid 确认给定目录有效
-!  (13) ARE_FLAGS_VALID       : Makes sure all flags are valid/not conflicting
+!  (13) ARE_FLAGS_VALID       : Makes sure all flags are valid/not conflicting 确认所有选项游戏哦啊
-!  (14) CHECK_DIRECTORY       : Checks a single directory for errors
+!  (14) CHECK_DIRECTORY       : Checks a single directory for errors 确认单个路径
-!  (15) CLEAN_FILE_DIRS       : Clean out directories
+!  (15) CLEAN_FILE_DIRS       : Clean out directories 清除路径
-!  (16) INIT_DEP_MAPS         : Make mapping arrays for dep adjoint forcing
+!  (16) INIT_DEP_MAPS         : Make mapping arrays for dep adjoint forcing 创建伴随强迫的映射数组
-!  (17) INIT_INPUT_ADJ        : Initializes directory & logical variables
+!  (17) INIT_INPUT_ADJ        : Initializes directory & logical variables 初始化路径
 !
 !  GEOS-CHEM modules referenced by "input_adj_mod.f"
 !  ============================================================================

code/adjoint/inverse_driver.f

@@ -780,7 +780,7 @@
       CALL READ_INPUT_FILE
       IF ( LPRT ) CALL DEBUG_MSG( '### INVERSE: a READ_INPUT_FILE' )
 
-      ! Read final iteration number from file
+      ! Read final iteration number from file 先读入当前的迭代情况
       OPEN(  65, file = 'ITER' )
       READ(  65,*) N_CALC_STOP
       READ ( 65,*) N_CALC_TOTAL
@@ -802,7 +802,7 @@
       IF (LADJ) CALL INIT_SETULB
 
       ! Initialize inverse modeling module
-      CALL INIT_INVERSE
+      CALL INIT_INVERSE ! 大概就是初始化了反演相关的数组
 
       ! Curent iteration
       N_CALC = 0
@@ -908,7 +908,7 @@
       ENDDO
 #endif
 
-      task   = 'START'
+      task   = 'START' ! 初始化当前过程为开始
 
       ! Mare array of scaling factors into a vector for optimization
       CALL GET_X_FROM_SF
@@ -942,7 +942,7 @@
 
             print*, ' done setulb ' , TASK
 
-            CALL SAVE_WEAK_CONSTRAINT_FIELDS
+            CALL SAVE_WEAK_CONSTRAINT_FIELDS ! 如果是弱约束，会先输出一个弱约束场
 
          ELSE
 
@@ -959,55 +959,55 @@
          ENDIF
 
          ! Force it to continue for FD tests, as cost func or gradients
-         ! may be very small or zero (dkh, 02/11/11)
+         ! may be very small or zero (dkh, 02/11/11) 如果进行有限差分测试，则强制继续进行
-         IF ( LFDTEST ) TASK(1:2) = 'FG'
+         IF ( LFDTEST ) TASK(1:2) = 'FG' ! 不对，可能是要避免迭代出结果的情况？
 
          IF ( TASK(1:2) == 'FG' ) THEN
 
-            ! Iteration diagnostics (zhe 11/28/10)
+            ! Iteration diagnostics (zhe 11/28/10) 迭代诊断的输出
             IF ( LITR ) THEN
                IF ( N_CALC .GT. 0 )  CALL ITER_CONDITION( N_CALC )
                LATF = .FALSE.
             ENDIF
 
             ! The minimization routine has returned to request the
-            ! function f and gradient g values at the current x
+            ! function f and gradient g values at the current x 相当于这里就直接让梯度为 0 了
 
-            ! Update iteration count
+            ! Update iteration count 继续增加迭代次数
             N_CALC = N_CALC + 1
 
-            ! Resent cost function for this iteration
+            ! Resent cost function for this iteration 咦，这里的代价函数值怎么直接修改了？
             COST_FUNC = 0.D0
 
-            IF ( N_CALC < N_CALC_STOP ) THEN
+            IF ( N_CALC < N_CALC_STOP ) THEN ! 如果在停止迭代之前，则从硬盘中读取相关数据
 
                WRITE(6,*)  'READING SAVED DATA for N_CALC = ', N_CALC
 
-               ! Read scaling factor values from disk
+               ! Read scaling factor values from disk 读取缩放因子
                CALL GET_SF_FROM_X
 
                CALL DISPLAY_STUFF( 1 )
 
-               ! Read gradients from disk
+               ! Read gradients from disk 读取梯度结果
                CALL READ_GDT_FILE
 
-               ! Read cost function from disk
+               ! Read cost function from disk 读取代价函数结果
                CALL READ_CFN_FILE
 
-               ! Put adjoints into GRADNT vector
+               ! Put adjoints into GRADNT vector 将伴随放到向量中
                CALL GET_GRADNT_FROM_ADJ
 
                !mkeller: read gradients with respect to forcing terms
                IF ( DO_WEAK_CONSTRAINT )  CALL READ_GDT_U_FILE
 
                !Save the current adjoint in the finite difference test cell
-               ! Initial conditions test
+               ! Initial conditions test 意思是现在不能进行同时优化初始场和排放的有限差分测试？
                IF ( LFDTEST .AND. LICS .AND. LADJ_EMS) THEN
 
                   PRINT*, 'WE HAVE A PROBLEM WITH STT_ADJ_FD when LICS &
      &                    LADJ_EMS are both TRUE'
 
-               ELSEIF ( LFDTEST .AND. LICS ) THEN
+               ELSEIF ( LFDTEST .AND. LICS ) THEN ! 剩下的部分就是从对应的数组取值，放到 STT_ADJ_FD 中
 
                   STT_ADJ_FD(N_CALC) = ICS_SF_ADJ(IFD,JFD,LFD,NFD)
 
@@ -1049,7 +1049,7 @@
 
                ! Return to beginning of loop
 
-            ELSEIF ( N_CALC == N_CALC_STOP ) THEN
+            ELSEIF ( N_CALC == N_CALC_STOP ) THEN ! 达到迭代结束次数，结束迭代
 
                ! Done if we are just estimating inverse Hessian (dkh, 01/12/12, adj32_012)
                IF ( LINVH ) THEN
@@ -1057,20 +1057,20 @@
                   STOP
                ENDIF
 
-               ! UPDATE THE INITIAL CONDITIONS
+               ! UPDATE THE INITIAL CONDITIONS 如果达到了最终迭代的条件，则更新初始条件
 
                ! If we're doing a finite difference test, reset to the orginal
                ! SF and augment by amount FD_DIFF. Don't use X in this case.
                ! old:
                !IF ( ACTIVE_VARS == 'FDTEST' .AND. N_CALC == 2 ) THEN
-               ! new: now support 2nd order FDTEST (MAKE_SAVE_FILE_2)
+               ! new: now support 2nd order FDTEST (MAKE_SAVE_FILE_2) 还有做二阶有限差分的
                IF ( LFDTEST .AND. N_CALC > 1 ) THEN
 
                   CALL SET_SF_FORFD
 
                ELSEIF ( N_CALC == 1 ) THEN
 
-                  ! don't need to call this again ??
+                  ! don't need to call this again ?? 笑死，不知道是谁写的注释，反正说明书写的是只做一次就行
                   !CALL SET_SF
 #if   defined ( LOG_OPT )
                   CALL SET_LOG_SF
@@ -1080,7 +1080,7 @@
 
                ELSE
 
-                  ! Update the scaling factors to the current X
+                  ! Update the scaling factors to the current X 更新缩放系数
                   CALL GET_SF_FROM_X
 
                ENDIF
@@ -1094,12 +1094,12 @@
                !CALL READ_SF_FILE
 
                !==============================================================
-               ! FORWARD RUN
+               ! FORWARD RUN 怎么又做了一次正向模拟
                !==============================================================
                CALL DO_GEOS_CHEM
 
                !==============================================================
-               ! ADJOINT CALCULATION
+               ! ADJOINT CALCULATION 然后又做了一次伴随
                !==============================================================
 
                ! For weak constraint 4D-Var (mkeller, 06/15)
@@ -1109,7 +1109,7 @@
 
                    CALL DO_GEOS_CHEM_ADJ
 
-               ! For finite difference test, we may or may not do adjoint
+               ! For finite difference test, we may or may not do adjoint 哈哈哈哈哈哈哈笑死，MAYBE_DO
                ELSE
 
                    CALL MAYBE_DO_GEOS_CHEM_ADJ
@@ -1117,31 +1117,31 @@
                ENDIF
 
                !==============================================================
-               ! SAVE RESULTS TO DISK and EXIT OPTIMIZATION LOOP
+               ! SAVE RESULTS TO DISK and EXIT OPTIMIZATION LOOP 将结果写到硬盘，然后退出最优化循环
                !==============================================================
 
                ! Zero the gradients of the species that we do not wish to optimize
-               ! or in places that you don't want optimized
+               ! or in places that you don't want optimized 将那些不想优化的部分设置为 0
                CALL SET_OPT_RANGE
                    ! Add to this Kumaresh's spatial filter
 
-               ! Write gradients
+               ! Write gradients 写入梯度文件
                CALL MAKE_GDT_FILE
 
-               ! Write scaling factors
+               ! Write scaling factors 写入缩放因子
                CALL MAKE_SF_FILE
 
-               ! Write cost function
+               ! Write cost function 写入代价函数
                CALL MAKE_CFN_FILE
 
-               ! For weak constraint 4D-Var (mkeller, 06/15)
+               ! For weak constraint 4D-Var (mkeller, 06/15) 写入弱约束项
                IF ( DO_WEAK_CONSTRAINT ) CALL MAKE_GDT_U_FILE
 
-               ! mkeller: create HDF5 file for satellite diagnostics output
+               ! mkeller: create HDF5 file for satellite diagnostics output 写入卫星诊断输出
                IF ( LSAT_HDF_L2 .OR. LSAT_HDF_L3 .OR. LDCOSAT )
      &            CALL DO_SAT_DIAGS()
 
-               IF ( LEMS_ABS ) CALL MAKE_EMS_ADJ_FILE
+               IF ( LEMS_ABS ) CALL MAKE_EMS_ADJ_FILE ! 写入排放文件
 
                ! Write results to screen
                CALL DISPLAY_STUFF( 4 )
@@ -1164,7 +1164,7 @@
 
          ELSE
 
-            ! We terminate execution when TASK is neither FG nor NEW_X.
+            ! We terminate execution when TASK is neither FG nor NEW_X. 好像明白了 FG 是什么，最终迭代么
             ! We print the information contained in the string TASK
             ! if the default output is not used and the execution is
             ! not stopped intentionally by the user.
@@ -1179,7 +1179,7 @@
          ENDIF
 
       !=================================================================
-      ! OPTIMIZATION loop ends here!
+      ! OPTIMIZATION loop ends here! 结束最优化的过程
       !=================================================================
       ENDDO
       WRITE( 6, '(a)'   ) REPEAT( '=', 79 )
@@ -1206,7 +1206,7 @@
       ENDIF
 #endif
 
-      ! Clean up and quit
+      ! Clean up and quit 清除一些中间文件
       CALL CLOSE_FILES
       CALL CLEANUP
       CALL CLEANUP_ADJ
@@ -1214,7 +1214,7 @@
       ! For weak constraint 4D-Var (mkeller, 06/15)
       IF ( DO_WEAK_CONSTRAINT ) CALL CLEAN_WEAK_CONSTRAINT
 
-      ! Remove all met files from temporary directory
+      ! Remove all met files from temporary directory 清除气象场文件
       IF ( LUNZIP ) THEN
          CALL UNZIP_A3_FIELDS(  'remove all' )
          CALL UNZIP_A6_FIELDS(  'remove all' )
@@ -1231,7 +1231,7 @@
 
       ENDIF
 
-      ! Write the final iteration number for the next iteration to file
+      ! Write the final iteration number for the next iteration to file 写入迭代文件的信息
       OPEN(  65, file = 'ITER' )
       WRITE(  65,*) N_CALC_STOP + 1
       CLOSE( 65 )

code/adjoint/inverse_mod.f

@@ -7,17 +7,18 @@
 !  on SGI, it didn't work on Linux, so had to move all to a module.
 !  (dkh, 02/05)!
 !  Module Variables:
+!  模块 INVERSE_MOD 包含了所有用于反演的子程序。只能在 SGI 运行，无法在 Linux 运行？
 !  ============================================================================
-!  (1 ) COST_FUNC   (REAL*8)      : Value of cost function
+!  (1 ) COST_FUNC   (REAL*8)      : Value of cost function 代价函数值
-!  (2 ) N_CALC      (INTEGER)     : Optimization iteration number
+!  (2 ) N_CALC      (INTEGER)     : Optimization iteration number 迭代次数
-!  (3 ) N_CALC_STOP (INTEGER)     : Maximum optimization iteration number
+!  (3 ) N_CALC_STOP (INTEGER)     : Maximum optimization iteration number 最大迭代次数
-!  (4 ) F           (DOUBLE)      : For optimization routine
+!  (4 ) F           (DOUBLE)      : For optimization routine 用于最优化的进程
-!  (5 ) X           (DOUBLE, ALLOC): Vector of active varialbes
+!  (5 ) X           (DOUBLE, ALLOC): Vector of active varialbes 激活的状态变量
-!  (6 ) GRADNT      (DOUBLE, ALLOC): Vector of adjoint gradients
+!  (6 ) GRADNT      (DOUBLE, ALLOC): Vector of adjoint gradients 伴随梯度向量
-!  (7 ) XP          (DOUBLE, ALLOC): Vector of active strat prod varialbes
+!  (7 ) XP          (DOUBLE, ALLOC): Vector of active strat prod varialbes 平流层源
-!  (8 ) GRADNT_P    (DOUBLE, ALLOC): Vector of strat prod adjoint gradients
+!  (8 ) GRADNT_P    (DOUBLE, ALLOC): Vector of strat prod adjoint gradients 平流层源梯度
-!  (9 ) XL          (DOUBLE, ALLOC): Vector of active strat loss varialbes
+!  (9 ) XL          (DOUBLE, ALLOC): Vector of active strat loss varialbes 平流层汇
-!  (10) GRADNT_L    (DOUBLE, ALLOC): Vector of adjoint strat loss gradients
+!  (10) GRADNT_L    (DOUBLE, ALLOC): Vector of adjoint strat loss gradients 平流层汇梯度
 !
 !  Module Routines
 !  ============================================================================
@@ -5472,7 +5473,7 @@ C     ---------- LAST CARD OF DRAN ----------
 !
 !******************************************************************************
 !  Subroutine CALC_NOPT calculates the number of paramteres to optimize
-!
+!  子程序用于计算需要优化的参数数量
 !  NOTES:
 !  (1 ) Set NOPT for initial conditions to 3D: IIPAR*JJPAR*LLPAR*N_TRACERS to
 !       be consistent with other parts of the code (mak, 6/18/09)

code/new/routines.f

@@ -64,29 +64,29 @@ c     This subroutine partitions the working arrays wa and iwa, and
 c       then uses the limited memory BFGS method to solve the bound
 c       constrained optimization problem by calling mainlb.
 c       (The direct method will be used in the subspace minimization.)
-c
+c     看上去就是一个利用有限内存进行最优化的程序？
-c     n is an integer variable.
+c     n is an integer variable. problem 的维度大小
 c       On entry n is the dimension of the problem.
 c       On exit n is unchanged.
 c
-c     m is an integer variable.
+c     m is an integer variable. 可用的变量最大数量 
 c       On entry m is the maximum number of variable metric corrections
 c         used to define the limited memory matrix.
 c       On exit m is unchanged.
 c
-c     x is a double precision array of dimension n.
+c     x is a double precision array of dimension n. 状态向量，维度为 n
 c       On entry x is an approximation to the solution.
 c       On exit x is the current approximation.
 c
-c     l is a double precision array of dimension n.
+c     l is a double precision array of dimension n. 状态变量的下边界（预设好的）
 c       On entry l is the lower bound on x.
 c       On exit l is unchanged.
 c
-c     u is a double precision array of dimension n.
+c     u is a double precision array of dimension n. 状态变量的上边界（预设好的）
 c       On entry u is the upper bound on x.
 c       On exit u is unchanged.
 c
-c     nbd is an integer array of dimension n.
+c     nbd is an integer array of dimension n. 指定了边界是如何约束变量的
 c       On entry nbd represents the type of bounds imposed on the
 c         variables, and must be specified as follows:
 c         nbd(i)=0 if x(i) is unbounded,
@@ -95,15 +95,15 @@ c                2 if x(i) has both lower and upper bounds, and
 c                3 if x(i) has only an upper bound.
 c       On exit nbd is unchanged.
 c
-c     f is a double precision variable.
+c     f is a double precision variable. 代价函数值？
 c       On first entry f is unspecified.
 c       On final exit f is the value of the function at x.
 c
-c     g is a double precision array of dimension n.
+c     g is a double precision array of dimension n. 梯度数组，和状态向量的维度一致
 c       On first entry g is unspecified.
 c       On final exit g is the value of the gradient at x.
 c
-c     factr is a double precision variable.
+c     factr is a double precision variable. 大概是一个最优化的临界值，到该值后结束迭代
 c       On entry factr >= 0 is specified by the user.  The iteration
 c         will stop when
 c
@@ -115,7 +115,7 @@ c         low accuracy; 1.d+7 for moderate accuracy; 1.d+1 for extremely
 c         high accuracy.
 c       On exit factr is unchanged.
 c
-c     pgtol is a double precision variable.
+c     pgtol is a double precision variable. 一个用户指定的值，用于指定迭代结束的条件，用于和梯度投影的长度比较
 c       On entry pgtol >= 0 is specified by the user.  The iteration
 c         will stop when
 c
@@ -124,15 +124,15 @@ c
 c         where pg_i is the ith component of the projected gradient.
 c       On exit pgtol is unchanged.
 c
-c     wa is a double precision working array of length
+c     wa is a double precision working array of length 用于计算的数组，这里就是外面状态向量计算的公式
 c       (2mmax + 5)nmax + 12mmax^2 + 12mmax.
 c
-c     iwa is an integer working array of length 3nmax.
+c     iwa is an integer working array of length 3nmax. 同样也是用于计算的数组
 c
-c     task is a working string of characters of length 60 indicating
+c     task is a working string of characters of length 60 indicating 作业状态说明
 c       the current job when entering and quitting this subroutine.
 c
-c     iprint is an integer variable that must be set by the user.
+c     iprint is an integer variable that must be set by the user. 指定了如何输出结果
 c       It controls the frequency and type of output generated:
 c        iprint<0    no output is generated;
 c        iprint=0    print only one line at the last iteration;
@@ -143,9 +143,9 @@ c        iprint>100  print details of every iteration including x and g;
 c       When iprint > 0, the file iterate.dat will be created to
 c                        summarize the iteration.
 c
-c     csave is a working string of characters of length 60.
+c     csave is a working string of characters of length 60. 同样保存了作业状态的文本
 c
-c     lsave is a logical working array of dimension 4.
+c     lsave is a logical working array of dimension 4. 用于指定任务状态的一个逻辑数组
 c       On exit with 'task' = NEW_X, the following information is
 c                                                             available:
 c         If lsave(1) = .true.  then  the initial X has been replaced by
@@ -154,7 +154,7 @@ c         If lsave(2) = .true.  then  the problem is constrained;
 c         If lsave(3) = .true.  then  each variable has upper and lower
 c                                     bounds;
 c
-c     isave is an integer working array of dimension 44.
+c     isave is an integer working array of dimension 44. 一些更具体的状态标记
 c       On exit with 'task' = NEW_X, the following information is
 c                                                             available:
 c         isave(22) = the total number of intervals explored in the
@@ -181,7 +181,7 @@ c                           active constraints in the current iteration;
 c         isave(41) = the number of variables entering the set of active
 c                         constraints in the current iteration.
 c
-c     dsave is a double precision working array of dimension 29.
+c     dsave is a double precision working array of dimension 29. 大概是一些任务的结果
 c       On exit with 'task' = NEW_X, the following information is
 c                                                             available:
 c         dsave(1) = current 'theta' in the BFGS matrix;
@@ -210,7 +210,7 @@ c
 c       L-BFGS-B Library ... mainlb.
 c
 c
-c     References:
+c     References: 居然还有参考文献
 c
 c       [1] R. H. Byrd, P. Lu, J. Nocedal and C. Zhu, ``A limited
 c       memory algorithm for bound constrained optimization'',
@@ -494,7 +494,7 @@ c     ************
       double precision one,zero
       parameter        (one=1.0d0,zero=0.0d0)
 
-      if (task .eq. 'START') then
+      if (task .eq. 'START') then ! 如果作业状态是开始
 
          epsmch = epsilon(one)
 
@@ -634,7 +634,7 @@ c                                          restore the previous iterate.
 
 c     Compute f0 and g0.
 
-      task = 'FG_START'
+      task = 'FG_START' ! 如果作业状态不是开始，则设置为 FG_START，让驱动器继续计算代价函数和梯度
 c          return to the driver to calculate f and g; reenter at 111.
       goto 1000
  111  continue