-
The Kalman filter is a set of mathematical equations that provides an efficient computational
[recursive] means to estimate the state of a process, in a way that minimizes
the mean of the squared error. The filter is very powerful in several aspects:
it supports estimations of past, present, and even future states, and it can do so even
when the precise nature of the modeled system is unknown.
标签:
computational
mathematical
equations
efficient
上传时间:
2014-06-02
上传用户:yd19890720
-
The main MIPS processor of SMP8630 comes with a JTAG interface, allowing:
� access to caches and data bus (DRAM) with a bandwidth of about 200kbit/s
� examining the processor state whatever the execution mode (monice)
� connecting to monice using mdi-server and using a gdb client on the processor to step and break
accurately whatever the execution mode
� running semi-hosted applications
� fl ash write tool
� memory testing (MT command)
� real-time traces: has not been built in CPU (Config3_TL=0) and only supported by MajicPLUS probes
(maybe built into emulator?)
标签:
interface
processor
allowing
access
上传时间:
2013-12-19
上传用户:youke111
-
/*
*********************************************************************************************************
* uC/TCP-IP V2
* The Embedded TCP/IP Suite
*
* (c) Copyright 2003-2010; Micrium, Inc.; Weston, FL
*
* All rights reserved. Protected by international copyright laws.
*
* uC/TCP-IP is provided in source form to registered licensees ONLY. It is
* illegal to distribute this source code to any third party unless you receive
* written permission by an authorized Micrium representative. Knowledge of
* the source code may NOT be used to develop a similar product.
*
* Please help us continue to provide the Embedded community with the finest
* software available. Your honesty is greatly appreciated.
*
* You can contact us at www.micrium.com.
*********************************************************************************************************
*/
/*
*********************************************************************************************************
*
* NETWORK TCP LAYER
* (TRANSMISSION CONTROL PROTOCOL)
*
* Filename : net_tcp.h
* Version : V2.10
* Programmer(s) : ITJ
*********************************************************************************************************
* Note(s) : (1) Supports Transmission Control Protocol as described in RFC #793 with the following
* restrictions/constraints :
*
* (a) TCP Security & Precedence NOT supported RFC # 793, Section 3.6
*
* (b) TCP Urgent Data NOT supported RFC # 793, Section 3.7
* 'The Communication of
* Urgent Information'
*
* (c) The following TCP options NOT supported :
*
* (1) Window Scale RFC #1072, Section 2
* RFC #1323, Section 2
* (2) Selective Acknowledgement (SACK) RFC #1072, Section 3
* RFC #2018
* RFC #2883
* (3) TCP Echo RFC #1072, Section 4
* (4) Timestamp RFC #1323, Section 3.2
* (5) Protection Against Wrapped Sequences (PAWS) RFC #1323, Section 4
*
* (d) #### IP-Options-to-TCP-Connection RFC #1122, Section 4.2.3.8
* Handling NOT supported
*
* (e) #### ICMP-Error-Message-to-TCP-Connection RFC #1122, Section 4.2.3.9
* Handling NOT currently supported
*
* (2) TCP Layer assumes/requires Network Socket Layer (see 'net_sock.h MODULE Note #1a2').
*********************************************************************************************************
*/
/*$PAGE*/�
/*
*********************************************************************************************************
* MODULE
*
* Note(s) : (1) TCP Layer module is NOT required for UDP-to-Application API configuration.
*
* See also 'net_cfg.h TRANSPORT LAYER CONFIGURATION'
* & 'net_cfg.h USER DATAGRAM PROTOCOL LAYER CONFIGURATION'.
*
* See also 'net_tcp.h Note #2'.
*
* (2) The following TCP-module-present configuration value MUST be pre-#define'd in
* 'net_cfg_net.h' PRIOR to all other network modules that require TCP Layer
* configuration (see 'net_cfg_net.h TCP LAYER CONFIGURATION Note #2b') :
*
* NET_TCP_MODULE_PRESENT
*********************************************************************************************************
*/
#ifdef NET_TCP_MODULE_PRESENT /* See Note #2. */
/*
*********************************************************************************************************
* EXTERNS
*********************************************************************************************************
*/
#if ((defined(NET_TCP_MODULE)) && \
(defined(NET_GLOBALS_EXT)))
#define NET_TCP_EXT
#else
#define NET_TCP_EXT extern
#endif
/*$PAGE*/�
/*
*********************************************************************************************************
* DEFINES
*********************************************************************************************************
*/
/*
*********************************************************************************************************
* TCP HEADER DEFINES
*
* Note(s) : (1) The following TCP value MUST be pre-#define'd in 'net_def.h' PRIOR to 'net_buf.h' so that
* the Network Buffer Module can configure maximum buffer header size (see 'net_def.h TCP
* LAYER DEFINES' & 'net_buf.h NETWORK BUFFER INDEX & SIZE DEFINES Note #1') :
*
* (a) NET_TCP_HDR_SIZE_MAX 60 (NET_TCP_HDR_LEN_MAX
* * NET_TCP_HDR_LEN_WORD_SIZE)
*
* (2) Urgent pointer & data NOT supported (see 'net_tcp.h Note #1b').
*********************************************************************************************************
*/
#define NET_TCP_HDR_LEN_MASK 0xF000u
#define NET_TCP_HDR_LEN_SHIFT 12u
#define NET_TCP_HDR_LEN_NONE 0u
#define NET_TCP_HDR_LEN_MIN 5u
#define NET_TCP_HDR_LEN_MAX 15u
#define NET_TCP_HDR_LEN_WORD_SIZE CPU_WORD_SIZE_32
#define NET_TCP_HDR_SIZE_MIN (NET_TCP_HDR_LEN_MIN * NET_TCP_HDR_LEN_WORD_SIZE)
#if 0 /* See Note #1a. */
#define NET_TCP_HDR_SIZE_MAX (NET_TCP_HDR_LEN_MAX * NET_TCP_HDR_LEN_WORD_SIZE)
#endif
#define NET_TCP_HDR_SIZE_TOT_MIN (NET_IP_HDR_SIZE_TOT_MIN + NET_TCP_HDR_SIZE_MIN)
#define NET_TCP_HDR_SIZE_TOT_MAX (NET_IP_HDR_SIZE_TOT_MAX + NET_TCP_HDR_SIZE_MAX)
#define NET_TCP_PSEUDO_HDR_SIZE 12u /* = sizeof(NET_TCP_PSEUDO_HDR) */
#define NET_TCP_PORT_NBR_RESERVED NET_PORT_NBR_RESERVED
#define NET_TCP_PORT_NBR_NONE NET_TCP_PORT_NBR_RESERVED
#define NET_TCP_HDR_URG_PTR_NONE 0x0000u /* See Note #2. */
/*$PAGE*/�
/*
*********************************************************************************************************
* TCP HEADER FLAG DEFINES
*
* Note(s) : (1) See 'TCP HEADER Note #2' for flag fields.
*
* (2) Urgent pointer & data NOT supported (see 'net_tcp.h Note #1b').
*********************************************************************************************************
*/
#define NET_TCP_HDR_FLAG_MASK 0x0FFFu
#define NET_TCP_HDR_FLAG_NONE DEF_BIT_NONE
#define NET_TCP_HDR_FLAG_RESERVED 0x0FE0u /* MUST be '0'. */
#define NET_TCP_HDR_FLAG_URGENT DEF_BIT_05 /* See Note #2. */
#define NET_TCP_HDR_FLAG_ACK DEF_BIT_04
#define NET_TCP_HDR_FLAG_PUSH DEF_BIT_03
#define NET_TCP_HDR_FLAG_RESET DEF_BIT_02
#define NET_TCP_HDR_FLAG_SYNC DEF_BIT_01
#define NET_TCP_HDR_FLAG_FIN DEF_BIT_00
#define NET_TCP_HDR_FLAG_CLOSE NET_TCP_HDR_FLAG_FIN
/*
*********************************************************************************************************
* TCP FLAG DEFINES
*********************************************************************************************************
*/
/* ------------------ NET TCP FLAGS ------------------- */
#define NET_TCP_FLAG_NONE DEF_BIT_NONE
#define NET_TCP_FLAG_USED DEF_BIT_00 /* TCP conn cur used; i.e. NOT in free TCP conn pool. */
/* ------------------ TCP TX FLAGS ------------------- */
/* TCP tx flags copied from TCP hdr flags. */
#define NET_TCP_FLAG_TX_FIN NET_TCP_HDR_FLAG_FIN
#define NET_TCP_FLAG_TX_CLOSE NET_TCP_FLAG_TX_FIN
#define NET_TCP_FLAG_TX_SYNC NET_TCP_HDR_FLAG_SYNC
#define NET_TCP_FLAG_TX_RESET NET_TCP_HDR_FLAG_RESET
#define NET_TCP_FLAG_TX_PUSH NET_TCP_HDR_FLAG_PUSH
#define NET_TCP_FLAG_TX_ACK NET_TCP_HDR_FLAG_ACK
#define NET_TCP_FLAG_TX_URGENT NET_TCP_HDR_FLAG_URGENT
#define NET_TCP_FLAG_TX_BLOCK DEF_BIT_07
/* ------------------ TCP RX FLAGS ------------------- */
#define NET_TCP_FLAG_RX_DATA_PEEK DEF_BIT_08
#define NET_TCP_FLAG_RX_BLOCK DEF_BIT_15
/*$PAGE*/�
/*
*********************************************************************************************************
* TCP TYPE DEFINES
*
* Note(s) : (1) NET_TCP_TYPE_&&& #define values specifically chosen as ASCII representations of the TCP
* types. Memory displays of TCP types will display with their chosen ASCII names.
*********************************************************************************************************
*/
/* ------------------ NET TCP TYPES ------------------- */
#if (CPU_CFG_ENDIAN_TYPE == CPU_ENDIAN_TYPE_BIG)
#define NET_TCP_TYPE_NONE 0x4E4F4E45u /* "NONE" in ASCII. */
#define NET_TCP_TYPE_CONN 0x54435020u /* "TCP " in ASCII. */
#else
#if (CPU_CFG_DATA_SIZE == CPU_WORD_SIZE_32)
#define NET_TCP_TYPE_NONE 0x454E4F4Eu /* "NONE" in ASCII. */
#define NET_TCP_TYPE_CONN 0x20504354u /* "TCP " in ASCII. */
#elif (CPU_CFG_DATA_SIZE == CPU_WORD_SIZE_16)
#define NET_TCP_TYPE_NONE 0x4F4E454Eu /* "NONE" in ASCII. */
#define NET_TCP_TYPE_CONN 0x43542050u /* "TCP " in ASCII. */
#else /* Dflt CPU_WORD_SIZE_08. */
#define NET_TCP_TYPE_NONE 0x4E4F4E45u /* "NONE" in ASCII. */
#define NET_TCP_TYPE_CONN 0x54435020u /* "TCP " in ASCII. */
#endif
#endif
/*
*********************************************************************************************************
* TCP SEQUENCE NUMBER DEFINES
*
* Note(s) : (1) TCP initial transmit sequence number is incremented by a fixed value, preferably a large
* prime value or a large value with multiple unique factors.
*
* (a) One reasonable TCP initial transmit sequence number increment value example :
*
* 65527 = 37 * 23 * 11 * 7
*
*
* #### NET_TCP_TX_SEQ_NBR_CTR_INC could be developer-configured in 'net_cfg.h'.
*
* See also 'NET_TCP_TX_GET_SEQ_NBR() Notes #1b2 & #1c2'.
*********************************************************************************************************
*/
#define NET_TCP_SEQ_NBR_NONE 0u
#define NET_TCP_ACK_NBR_NONE NET_TCP_SEQ_NBR_NONE
#define NET_TCP_TX_SEQ_NBR_CTR_INC 65527u /* See Note #1. */
#define NET_TCP_ACK_NBR_DUP_WIN_SIZE_SCALE 4
/*$PAGE*/�
/*
*********************************************************************************************************
* TCP DATA/TOTAL LENGTH DEFINES
*
* Note(s) : (1) (a) TCP total length #define's (NET_TCP_TOT_LEN) relate to the total size of a complete
* TCP packet, including the packet's TCP header. Note that a complete TCP packet MAY
* be fragmented in multiple Internet Protocol packets.
*
* (b) TCP data length #define's (NET_TCP_DATA_LEN) relate to the data size of a complete
* TCP packet, equal to the total TCP packet length minus its TCP header size. Note
* that a complete TCP packet MAY be fragmented in multiple Internet Protocol packets.
*********************************************************************************************************
*/
/* See Notes #1a & #1b. */
#define NET_TCP_DATA_LEN_MIN 0u
#define NET_TCP_TOT_LEN_MIN (NET_TCP_HDR_SIZE_MIN + NET_TCP_DATA_LEN_MIN)
#define NET_TCP_TOT_LEN_MAX (NET_IP_TOT_LEN_MAX - NET_IP_HDR_SIZE_MIN )
#define NET_TCP_DATA_LEN_MAX (NET_TCP_TOT_LEN_MAX - NET_TCP_HDR_SIZE_MIN)
/*$PAGE*/�
/*
*********************************************************************************************************
* TCP SEGMENT SIZE DEFINES
*
* Note(s) : (1) (a) RFC # 879, Section 3 states that the TCP Maximum Segment Size "counts only
* data octets in the segment, ... not the TCP header or the IP header".
*
* (b) RFC #1122, Section 4.2.2.6 requires that :
*
* (1) "The MSS value to be sent in an MSS option must be less than or equal to
*
* (A) MMS_R - 20
*
* where MMS_R is the maximum size for a transport-layer message that can
* be received."
*
* (2) "If an MSS option is not received at connection setup, TCP MUST assume a
* default send MSS of 536 (576 - 40)."
*
* See also 'net_ip.h IP DATA/TOTAL LENGTH DEFINES Note #1'.
*********************************************************************************************************
*/
/* See Note #1. */
#define NET_TCP_MAX_SEG_SIZE_DFLT (NET_IP_MAX_DATAGRAM_SIZE_DFLT - NET_IP_HDR_SIZE_MIN - NET_TCP_HDR_SIZE_MIN)
#define NET_TCP_MAX_SEG_SIZE_DFLT_RX NET_TCP_DATA_LEN_MAX /* See Note #1b1. */
#define NET_TCP_MAX_SEG_SIZE_DFLT_TX NET_TCP_MAX_SEG_SIZE_DFLT /* See Note #1b2. */
#define NET_TCP_MAX_SEG_SIZE_NONE 0u
#define NET_TCP_MAX_SEG_SIZE_MIN NET_TCP_MAX_SEG_SIZE_DFLT
#define NET_TCP_MAX_SEG_SIZE_MAX NET_TCP_DATA_LEN_MAX
#define NET_TCP_SEG_LEN_MIN NET_TCP_DATA_LEN_MIN
#define NET_TCP_SEG_LEN_MAX NET_TCP_DATA_LEN_MAX
#define NET_TCP_SEG_LEN_SYNC 1u
#define NET_TCP_SEG_LEN_FIN 1u
#define NET_TCP_SEG_LEN_CLOSE NET_TCP_SEG_LEN_FIN
#define NET_TCP_SEG_LEN_ACK 0u
#define NET_TCP_SEG_LEN_RESET 0u
#define NET_TCP_SEG_LEN_PROBE 0u
#define NET_TCP_DATA_LEN_TX_SYNC 0u
#define NET_TCP_DATA_LEN_TX_FIN 0u
#define NET_TCP_DATA_LEN_TX_CLOSE NET_TCP_DATA_LEN_TX_FIN
#define NET_TCP_DATA_LEN_TX_ACK 0u
#define NET_TCP_DATA_LEN_TX_PROBE_NO_DATA 0u
#define NET_TCP_DATA_LEN_TX_PROBE_DATA 1u
#define NET_TCP_DATA_LEN_TX_RESET 0u
#define NET_TCP_TX_PROBE_DATA 0x00u
/*
*********************************************************************************************************
* TCP WINDOW SIZE DEFINES
*
* Note(s) : (1) Although NO RFC specifies the absolute minimum TCP connection window size value allowed,
* RFC #793, Section 3.7 'Data Communication : Managing the Window' states that for "the
* window ... there is an assumption that this is related to the currently available data
* buffer space available for this connection".
*********************************************************************************************************
*/
#define NET_TCP_WIN_SIZE_NONE 0u
#define NET_TCP_WIN_SIZE_MIN NET_TCP_MAX_SEG_SIZE_MIN
#define NET_TCP_WIN_SIZE_MAX DEF_INT_16U_MAX_VAL
/*$PAGE*/�
/*
*********************************************************************************************************
* TCP HEADER OPTIONS DEFINES
*
* Note(s) : (1) See the following RFC's for TCP options summary :
*
* (a) RFC # 793, Section 3.1 'Header Format : Options'
* (b) RFC #1122; Sections 4.2.2.5, 4.2.2.6
*
* (2) TCP option types are encoded in the first octet for each TCP option as follows :
*
* --------
* | TYPE |
* --------
*
* The TCP option type value determines the TCP option format :
*
* (a) The following TCP option types are single-octet TCP options -- i.e. the option type
* octet is the ONLY octet for the TCP option.
*
* (1) TYPE = 0 End of Options List
* (2) TYPE = 1 No Operation
*
*
* (b) All other TCP options MUST be multi-octet TCP options (see RFC #1122, Section 4.2.2.5) :
*
* ------------------------------
* | TYPE | LEN | TCP OPT |
* ------------------------------
*
* where
* TYPE Indicates the specific TCP option type
* LEN Indicates the total TCP option length, in octets, including
* the option type & the option length octets
* TCP OPT Additional TCP option octets, if any, that contain the remaining
* TCP option information
*
* The following TCP option types are multi-octet TCP options where the option's second
* octet specify the total TCP option length, in octets, including the option type & the
* option length octets :
*
* (1) TYPE = 2 Maximum Segment Size See RFC # 793, Section 3.1 'Header Format :
* Options : Maximum Segment Size';
* RFC #1122, Section 4.2.2.6;
* RFC # 879, Section 3
*
* (2) TYPE = 3 Window Scale See 'net_tcp.h Note #1c1'
* (3) TYPE = 4 SACK Allowed See 'net_tcp.h Note #1c2'
* (4) TYPE = 5 SACK Option See 'net_tcp.h Note #1c2'
* (5) TYPE = 6 Echo Request See 'net_tcp.h Note #1c3'
* (6) TYPE = 7 Echo Reply See 'net_tcp.h Note #1c3'
* (7) TYPE = 8 Timestamp See 'net_tcp.h Note #1c4'
*
* (3) TCP header allows for a maximum option list length of 40 octets :
*
* NET_TCP_HDR_OPT_SIZE_MAX = NET_TCP_HDR_SIZE_MAX - NET_TCP_HDR_SIZE_MIN
*
* = 60 - 20
*
* = 40
*
* (4) 'NET_TCP_OPT_SIZE' MUST be pre-defined PRIOR to all definitions that require TCP option
* size data type.
*********************************************************************************************************
*/
/*$PAGE*/�
#define NET_TCP_HDR_OPT_END_LIST 0u
#define NET_TCP_HDR_OPT_NOP 1u
#define NET_TCP_HDR_OPT_MAX_SEG_SIZE 2u
#define NET_TCP_HDR_OPT_WIN_SCALE 3u
#define NET_TCP_HDR_OPT_SACK_PERMIT 4u
#define NET_TCP_HDR_OPT_SACK 5u
#define NET_TCP_HDR_OPT_ECHO_REQ 6u
#define NET_TCP_HDR_OPT_ECHO_REPLY 7u
#define NET_TCP_HDR_OPT_TS 8u
#define NET_TCP_HDR_OPT_PAD NET_TCP_HDR_OPT_END_LIST
#define NET_TCP_HDR_OPT_LEN_END_LIST 1u
#define NET_TCP_HDR_OPT_LEN_NOP 1u
#define NET_TCP_HDR_OPT_LEN_MAX_SEG_SIZE 4u
#define NET_TCP_HDR_OPT_LEN_WIN_SCALE 3u
#define NET_TCP_HDR_OPT_LEN_SACK_PERMIT 2u
#define NET_TCP_HDR_OPT_LEN_ECHO_REQ 6u
#define NET_TCP_HDR_OPT_LEN_ECHO_REPLY 6u
#define NET_TCP_HDR_OPT_LEN_TS 10u
#define NET_TCP_HDR_OPT_LEN_SACK_MIN 6u
#define NET_TCP_HDR_OPT_LEN_SACK_MAX 38u
#define NET_TCP_HDR_OPT_LEN_MIN 1u
#define NET_TCP_HDR_OPT_LEN_MIN_LEN 2u
#define NET_TCP_HDR_OPT_LEN_MAX 38u
typedef CPU_INT32U NET_TCP_OPT_SIZE; /* TCP opt size data type (see Note #4). */
#define NET_TCP_HDR_OPT_SIZE_WORD (sizeof(NET_TCP_OPT_SIZE))
#define NET_TCP_HDR_OPT_SIZE_MAX (NET_TCP_HDR_SIZE_MAX - NET_TCP_HDR_SIZE_MIN)
#define NET_TCP_HDR_OPT_NBR_MIN 0u
#define NET_TCP_HDR_OPT_NBR_MAX (NET_TCP_HDR_OPT_SIZE_MAX / NET_TCP_HDR_OPT_SIZE_WORD)
#define NET_TCP_HDR_OPT_IX NET_TCP_HDR_SIZE_MIN
/*$PAGE*/�
/*
*********************************************************************************************************
* TCP OPTION CONFIGURATION TYPE DEFINES
*
* Note(s) : (1) NET_TCP_OPT_CFG_TYPE_&&& #define values specifically chosen as ASCII representations of
* the TCP option configuration types. Memory displays of TCP option configuration buffers
* will display the TCP option configuration TYPEs with their chosen ASCII names.
*********************************************************************************************************
*/
/* ---------------- TCP OPT CFG TYPES ----------------- */
#if (CPU_CFG_ENDIAN_TYPE == CPU_ENDIAN_TYPE_BIG)
#define NET_TCP_OPT_CFG_TYPE_NONE 0x4E4F4E45u /* "NONE" in ASCII. */
#define NET_TCP_OPT_CFG_TYPE_MAX_SEG_SIZE 0x4D535320u /* "MSS " in ASCII. */
#define NET_TCP_OPT_CFG_TYPE_WIN_SCALE 0x57494E20u /* "WIN " in ASCII (see 'net_tcp.h Note #1c1'). */
#define NET_TCP_OPT_CFG_TYPE_SACK_PERMIT 0x53434B50u /* "SCKP" in ASCII (see 'net_tcp.h Note #1c2'). */
#define NET_TCP_OPT_CFG_TYPE_SACK 0x5341434Bu /* "SACK" in ASCII (see 'net_tcp.h Note #1c2'). */
#define NET_TCP_OPT_CFG_TYPE_ECHO_REQ 0x45524551u /* "EREQ" in ASCII (see 'net_tcp.h Note #1c3'). */
#define NET_TCP_OPT_CFG_TYPE_ECHO_REPLY 0x4543484Fu /* "ECHO" in ASCII (see 'net_tcp.h Note #1c3'). */
#define NET_TCP_OPT_CFG_TYPE_TS 0x54532020u /* "TS " in ASCII (see 'net_tcp.h Note #1c4'). */
#else
#if (CPU_CFG_DATA_SIZE == CPU_WORD_SIZE_32)
#define NET_TCP_OPT_CFG_TYPE_NONE 0x454E4F4Eu /* "NONE" in ASCII. */
#define NET_TCP_OPT_CFG_TYPE_MAX_SEG_SIZE 0x2053534Du /* "MSS " in ASCII. */
#define NET_TCP_OPT_CFG_TYPE_WIN_SCALE 0x204E4957u /* "WIN " in ASCII (see 'net_tcp.h Note #1c1'). */
#define NET_TCP_OPT_CFG_TYPE_SACK_PERMIT 0x504B4353u /* "SCKP" in ASCII (see 'net_tcp.h Note #1c2'). */
#define NET_TCP_OPT_CFG_TYPE_SACK 0x4B434153u /* "SACK" in ASCII (see 'net_tcp.h Note #1c2'). */
#define NET_TCP_OPT_CFG_TYPE_ECHO_REQ 0x51455245u /* "EREQ" in ASCII (see 'net_tcp.h Note #1c3'). */
#define NET_TCP_OPT_CFG_TYPE_ECHO_REPLY 0x4F484345u /* "ECHO" in ASCII (see 'net_tcp.h Note #1c3'). */
#define NET_TCP_OPT_CFG_TYPE_TS 0x20205354u /* "TS " in ASCII (see 'net_tcp.h Note #1c4'). */
#elif (CPU_CFG_DATA_SIZE == CPU_WORD_SIZE_16)
#define NET_TCP_OPT_CFG_TYPE_NONE 0x4F4E454Eu /* "NONE" in ASCII. */
#define NET_TCP_OPT_CFG_TYPE_MAX_SEG_SIZE 0x534D2053u /* "MSS " in ASCII. */
#define NET_TCP_OPT_CFG_TYPE_WIN_SCALE 0x4957204Eu /* "WIN " in ASCII (see 'net_tcp.h Note #1c1'). */
#define NET_TCP_OPT_CFG_TYPE_SACK_PERMIT 0x4353504Bu /* "SCKP" in ASCII (see 'net_tcp.h Note #1c2'). */
#define NET_TCP_OPT_CFG_TYPE_SACK 0x41534B43u /* "SACK" in ASCII (see 'net_tcp.h Note #1c2'). */
#define NET_TCP_OPT_CFG_TYPE_ECHO_REQ 0x52455145u /* "EREQ" in ASCII (see 'net_tcp.h Note #1c3'). */
#define NET_TCP_OPT_CFG_TYPE_ECHO_REPLY 0x43454F48u /* "ECHO" in ASCII (see 'net_tcp.h Note #1c3'). */
#define NET_TCP_OPT_CFG_TYPE_TS 0x53542020u /* "TS " in ASCII (see 'net_tcp.h Note #1c4'). */
#else /* Dflt CPU_WORD_SIZE_08. */
#define NET_TCP_OPT_CFG_TYPE_NONE 0x4E4F4E45u /* "NONE" in ASCII. */
#define NET_TCP_OPT_CFG_TYPE_MAX_SEG_SIZE 0x4D535320u /* "MSS " in ASCII. */
#define NET_TCP_OPT_CFG_TYPE_WIN_SCALE 0x57494E20u /* "WIN " in ASCII (see 'net_tcp.h Note #1c1'). */
#define NET_TCP_OPT_CFG_TYPE_SACK_PERMIT 0x53434B50u /* "SCKP" in ASCII (see 'net_tcp.h Note #1c2'). */
#define NET_TCP_OPT_CFG_TYPE_SACK 0x5341434Bu /* "SACK" in ASCII (see 'net_tcp.h Note #1c2'). */
#define NET_TCP_OPT_CFG_TYPE_ECHO_REQ 0x45524551u /* "EREQ" in ASCII (see 'net_tcp.h Note #1c3'). */
#define NET_TCP_OPT_CFG_TYPE_ECHO_REPLY 0x4543484Fu /* "ECHO" in ASCII (see 'net_tcp.h Note #1c3'). */
#define NET_TCP_OPT_CFG_TYPE_TS 0x54532020u /* "TS " in ASCII (see 'net_tcp.h Note #1c4'). */
#endif
#endif
/*$PAGE*/�
/*
*********************************************************************************************************
* TCP CONNECTION TIMEOUT DEFINES
*
* Note(s) : (1) (a) (1) RFC #1122, Section 4.2.2.13 'DISCUSSION' states that "the graceful close algorithm
* of TCP requires that the connection state remain defined on (at least) one end of
* the connection, for a timeout period of 2xMSL ... During this period, the (remote
* socket, local socket) pair that defines the connection is busy and cannot be reused".
*
* (2) The following sections reiterate that the TIME-WAIT state timeout scalar is two
* maximum segment lifetimes (2 MSL) :
*
* (A) RFC #793, Section 3.9 'Event Processing : SEGMENT ARRIVES :
* Check Sequence Number : TIME-WAIT STATE'
* (B) RFC #793, Section 3.9 'Event Processing : SEGMENT ARRIVES :
* Check FIN Bit : TIME-WAIT STATE'
*
* (b) (1) RFC #793, Section 3.3 'Sequence Numbers : Knowing When to Keep Quiet' states that
* "the Maximum Segment Lifetime (MSL) is ... to be 2 minutes. This is an engineering
* choice, and may be changed if experience indicates it is desirable to do so".
*
* (2) Microsoft Corporation's Windows XP defaults MSL to 15 seconds.
*********************************************************************************************************
*/
/* Max seg timeout (see Note #1b) : */
#define NET_TCP_CONN_TIMEOUT_MAX_SEG_MIN_SEC ( 0u ) /* ... min = 0 seconds */
#define NET_TCP_CONN_TIMEOUT_MAX_SEG_MAX_SEC ( 2u * DEF_TIME_NBR_SEC_PER_MIN) /* ... max = 2 minutes */
#define NET_TCP_CONN_TIMEOUT_MAX_SEG_DFLT_SEC ( 15u ) /* ... dflt = 15 seconds */
#define NET_TCP_CONN_TIMEOUT_MAX_SEG_SCALAR 2u /* ... scalar (see Note #1a). */
#define NET_TCP_CONN_TIMEOUT_CONN_DFLT_SEC (120u * DEF_TIME_NBR_SEC_PER_MIN) /* Dflt conn timeout = 120 minutes */
#define NET_TCP_CONN_TIMEOUT_USER_DFLT_SEC ( 30u * DEF_TIME_NBR_SEC_PER_MIN) /* Dflt user timeout = 30 minutes */
/*$PAGE*/�
/*
*********************************************************************************************************
* TCP CONNECTION STATES
*
* Note(s) : (1) See the following RFC's for TCP state machine summary :
*
* (a) RFC # 793; Sections 3.2, 3.4, 3.5, 3.9
* (b) RFC #1122; Sections 4.2.2.8, 4.2.2.10, 4.2.2.11, 4.2.2.13, 4.2.2.18, 4.2.2.20
*
* (2) (a) #### Additional closing-data-available state used for closing connections to allow the
* application layer to receive any remaining data.
*
* See also 'net_tcp.c NetTCP_RxPktConnHandlerFinWait1() Note #2f5A2',
* 'net_tcp.c NetTCP_RxPktConnHandlerFinWait2() Note #2f5B',
* 'net_tcp.c NetTCP_RxPktConnHandlerClosing() Note #2d2B2a1B',
* & 'net_tcp.c NetTCP_RxPktConnHandlerLastAck() Note #2d2A1b'.
*********************************************************************************************************
*/
#define NET_TCP_CONN_STATE_NONE 0u
#define NET_TCP_CONN_STATE_FREE 1u
#define NET_TCP_CONN_STATE_CLOSED 10u
#define NET_TCP_CONN_STATE_LISTEN 20u
#define NET_TCP_CONN_STATE_SYNC_RXD 30u
#define NET_TCP_CONN_STATE_SYNC_RXD_PASSIVE 31u
#define NET_TCP_CONN_STATE_SYNC_RXD_ACTIVE 32u
#define NET_TCP_CONN_STATE_SYNC_TXD 35u
#define NET_TCP_CONN_STATE_CONN 40u
#define NET_TCP_CONN_STATE_FIN_WAIT_1 50u
#define NET_TCP_CONN_STATE_FIN_WAIT_2 51u
#define NET_TCP_CONN_STATE_CLOSING 52u
#define NET_TCP_CONN_STATE_TIME_WAIT 53u
#define NET_TCP_CONN_STATE_CLOSE_WAIT 55u
#define NET_TCP_CONN_STATE_LAST_ACK 56u
#define NET_TCP_CONN_STATE_CLOSING_DATA_AVAIL 59u /* See Note #2a. */
/*
*********************************************************************************************************
* TCP CONNECTION QUEUE STATES
*********************************************************************************************************
*/
#define NET_TCP_RX_Q_STATE_NONE 0u
#define NET_TCP_RX_Q_STATE_CLOSED 100u
#define NET_TCP_RX_Q_STATE_CLOSING 101u
#define NET_TCP_RX_Q_STATE_SYNC 110u
#define NET_TCP_RX_Q_STATE_CONN 111u
#define NET_TCP_TX_Q_STATE_NONE 0u
#define NET_TCP_TX_Q_STATE_CLOSED 200u
#define NET_TCP_TX_Q_STATE_CLOSING 201u
#define NET_TCP_TX_Q_STATE_SYNC 210u
#define NET_TCP_TX_Q_STATE_CONN 211u
#define NET_TCP_TX_Q_STATE_SUSPEND 215u
#define NET_TCP_TX_Q_STATE_CLOSED_SUSPEND 220u
#define NET_TCP_TX_Q_STATE_CLOSING_SUSPEND 221u
/*$PAGE*/�
/*
*********************************************************************************************************
* TCP CONNECTION CODE DEFINES
**************
标签:
tcp
uCOS-II
上传时间:
2015-11-22
上传用户:the same kong
-
This book is an entry-level text on the technology of telecommunications. It has been
crafted with the newcomer in mind. The twenty-one chapters of text have been prepared
for high-school graduates who understand algebra, logarithms, and the basic principles of
electricity such as Ohm’s law. However, it is appreciated that many readers require support
in these areas. Appendices A and B review the essentials of electricity and mathematics
up through logarithms. This material was placed in the appendices so as not to distract
from the main theme, the technology of telecommunication systems. Another topic that
many in the industry find difficult is the use of decibels and derived units. Appendix C
provides the reader a basic understanding of decibels and their applications. The only
mathematics necessary is an understanding of the powers of ten
标签:
Telecommunications
Fundamentals
2nd
of
ed
上传时间:
2020-05-27
上传用户:shancjb
-
DescriptionThe IMX385LQR-C is a diagonal 8.35 mm (Type 1/2) CMOS active pixel type solid-state image sensor with a squarepixel array and 2.13 M effective pixels. This chip operates with analog 3.3 V, digital 1.2 V, and interface 1.8 V triplepower supply, and has low power consumption. High sensitivity, low dark current and no smear are achieved throughthe adoption of R, G and B primary color mosaic filters. This chip features an electronic shutter with variablecharge-integration time.(Applications: Surveillance cameras)
标签:
CMOS传感器
IMX385LQR-C
上传时间:
2022-06-18
上传用户:
-
One of the strengths of Synplify is the Finite State Machine compiler. This is a powerfulfeature that not only has the ability to automatically detect state machines in the sourcecode, and implement them with either sequential, gray, or one-hot encoding. But alsoperform a reachability analysis to determine all the states that could possibly bereached, and optimize away all states and transition logic that can not be reached.Thus, producing a highly optimal final implementation of the state machine.
标签:
Synplicity
Machine
Verilog
Design
上传时间:
2013-10-23
上传用户:司令部正军级
-
磁芯电感器的谐波失真分析 摘 要:简述了改进铁氧体软磁材料比损耗系数和磁滞常数ηB,从而降低总谐波失真THD的历史过程,分析了诸多因数对谐波测量的影响,提出了磁心性能的调控方向。 关键词:比损耗系数, 磁滞常数ηB ,直流偏置特性DC-Bias,总谐波失真THD Analysis on THD of the fer rite co res u se d i n i nductancShi Yan Nanjing Finemag Technology Co. Ltd., Nanjing 210033 Abstract: Histrory of decreasing THD by improving the ratio loss coefficient and hysteresis constant of soft magnetic ferrite is briefly narrated. The effect of many factors which affect the harmonic wave testing is analysed. The way of improving the performance of ferrite cores is put forward. Key words: ratio loss coefficient,hysteresis constant,DC-Bias,THD 近年来,变压器生产厂家和软磁铁氧体生产厂家,在电感器和变压器产品的总谐波失真指标控制上,进行了深入的探讨和广泛的合作,逐步弄清了一些似是而非的问题。从工艺技术上采取了不少有效措施,促进了质量问题的迅速解决。本文将就此热门话题作一些粗浅探讨。 一、 历史回顾 总谐波失真(Total harmonic distortion) ,简称THD,并不是什么新的概念,早在几十年前的载波通信技术中就已有严格要求<1>。1978年邮电部公布的标准YD/Z17-78“载波用铁氧体罐形磁心”中,规定了高μQ材料制作的无中心柱配对罐形磁心详细的测试电路和方法。如图一电路所示,利用LC组成的150KHz低通滤波器在高电平输入的情况下测量磁心产生的非线性失真。这种相对比较的实用方法,专用于无中心柱配对罐形磁心的谐波衰耗测试。 这种磁心主要用于载波电报、电话设备的遥测振荡器和线路放大器系统,其非线性失真有很严格的要求。
图中 ZD —— QF867 型阻容式载频振荡器,输出阻抗 150Ω, Ld47 —— 47KHz 低通滤波器,阻抗 150Ω,阻带衰耗大于61dB, Lg88 ——并联高低通滤波器,阻抗 150Ω,三次谐波衰耗大于61dB Ld88 ——并联高低通滤波器,阻抗 150Ω,三次谐波衰耗大于61dB FD —— 30~50KHz 放大器, 阻抗 150Ω, 增益不小于 43 dB,三次谐波衰耗b3(0)≥91 dB, DP —— Qp373 选频电平表,输入高阻抗, L ——被测无心罐形磁心及线圈, C ——聚苯乙烯薄膜电容器CMO-100V-707APF±0.5%,二只。
测量时,所配用线圈应用丝包铜电磁线SQJ9×0.12(JB661-75)在直径为16.1mm的线架上绕制 120 匝, (线架为一格) , 其空心电感值为 318μH(误差1%) 被测磁心配对安装好后,先调节振荡器频率为 36.6~40KHz, 使输出电平值为+17.4 dB, 即选频表在 22′端子测得的主波电平 (P2)为+17.4 dB,然后在33′端子处测得输出的三次谐波电平(P3), 则三次谐波衰耗值为:b3(+2)= P2+S+ P3 式中:S 为放大器增益dB 从以往的资料引证, 就可以发现谐波失真的测量是一项很精细的工作,其中测量系统的高、低通滤波器,信号源和放大器本身的三次谐波衰耗控制很严,阻抗必须匹配,薄膜电容器的非线性也有相应要求。滤波器的电感全由不带任何磁介质的大空心线圈绕成,以保证本身的“洁净” ,不至于造成对磁心分选的误判。 为了满足多路通信整机的小型化和稳定性要求, 必须生产低损耗高稳定磁心。上世纪 70 年代初,1409 所和四机部、邮电部各厂,从工艺上改变了推板空气窑烧结,出窑后经真空罐冷却的落后方式,改用真空炉,并控制烧结、冷却气氛。技术上采用共沉淀法攻关试制出了μQ乘积 60 万和 100 万的低损耗高稳定材料,在此基础上,还实现了高μ7000~10000材料的突破,从而大大缩短了与国外企业的技术差异。当时正处于通信技术由FDM(频率划分调制)向PCM(脉冲编码调制) 转换时期, 日本人明石雅夫发表了μQ乘积125 万为 0.8×10 ,100KHz)的超优铁氧体材料<3>,其磁滞系数降为优铁
标签:
磁芯
电感器
分
谐波失真
上传时间:
2014-12-24
上传用户:7891
-
为了改变目前电网现场作业管理的变电巡检、变电检修试验、输电线路巡检检修等管理系统各自独立运行,信息不能共享,功能、效率受限,建设和维护成本高的现状,提出了采用B/S+C/S构架模式,将各现场作业管理模块和生产MIS(管理系统)集成为一体的现场作业管理系统的设计方案,做到各子系统和生产MIS软硬资源共享,做到同一数据唯一入口、一处录入多处使用。各子系统设备人员等基础信息来源于生产管理系统,各子系统又是生产管理系统的作业数据、缺陷信息的重要来源。经过研究试用成功和推广应用,目前该系统已在江西电网220 kV及以上变电站全面应用。
Abstract:
In order to improve the status that the substation field inspection system, substation equipments maintenance and testing system, power-line inspection and maintenance system are running independent with each other. They can?蒺t share the resource information which accordingly constrains their functions and efficiency, and their construction and maintenance costs are high. This paper introduces a field standardized work management system based on B/S+C/S mode, integrating all field work management systems based on MIS and share the equipments and employee?蒺s data of MIS,the field work data of the sub systems are the source information of MIS, by which the same single data resouce with one-time input can be utilized in multiple places. After the research and testing, this system is triumphantly using in all 220kV and above substations in Jiangxi grid.
标签:
电网
信息化
管理系统
上传时间:
2013-11-15
上传用户:han_zh
-
All inputs of the C16x family have Schmitt-Trigger input characteristics. These Schmitt-Triggers are intended to always provide proper internal low and high levels, even if anundefined voltage level (between TTL-VIL and TTL-VIH) is externally applied to the pin.The hysteresis of these inputs, however, is very small, and can not be properly used in anapplication to suppress signal noise, and to shape slow rising/falling input transitions.Thus, it must be taken care that rising/falling input signals pass the undefined area of theTTL-specification between VIL and VIH with a sufficient rise/fall time, as generally usualand specified for TTL components (e.g. 74LS series: gates 1V/us, clock inputs 20V/us).The effect of the implemented Schmitt-Trigger is that even if the input signal remains inthe undefined area, well defined low/high levels are generated internally. Note that allinput signals are evaluated at specific sample points (depending on the input and theperipheral function connected to it), at that signal transitions are detected if twoconsecutive samples show different levels. Thus, only the current level of an input signalat these sample points is relevant, that means, the necessary rise/fall times of the inputsignal is only dependant on the sample rate, that is the distance in time between twoconsecutive evaluation time points. If an input signal, for instance, is sampled throughsoftware every 10us, it is irrelevant, which input level would be seen between thesamples. Thus, it would be allowable for the signal to take 10us to pass through theundefined area. Due to the sample rate of 10us, it is assured that only one sample canoccur while the signal is within the undefined area, and no incorrect transition will bedetected. For inputs which are connected to a peripheral function, e.g. capture inputs, thesample rate is determined by the clock cycle of the peripheral unit. In the case of theCAPCOM unit this means a sample rate of 400ns @ 20MHz CPU clock. This requiresinput signals to pass through the undefined area within these 400ns in order to avoidmultiple capture events.For input signals, which do not provide the required rise/fall times, external circuitry mustbe used to shape the signal transitions.In the attached diagram, the effect of the sample rate is shown. The numbers 1 to 5 in thediagram represent possible sample points. Waveform a) shows the result if the inputsignal transition time through the undefined TTL-level area is less than the time distancebetween the sample points (sampling at 1, 2, 3, and 4). Waveform b) can be the result ifthe sampling is performed more than once within the undefined area (sampling at 1, 2, 5,3, and 4).Sample points:1. Evaluation of the signal clearly results in a low level2. Either a low or a high level can be sampled here. If low is sampled, no transition willbe detected. If the sample results in a high level, a transition is detected, and anappropriate action (e.g. capture) might take place.3. Evaluation here clearly results in a high level. If the previous sample 2) had alreadydetected a high, there is no change. If the previous sample 2) showed a low, atransition from low to high is detected now.
标签:
Signal
Input
Fall
Rise
上传时间:
2013-10-23
上传用户:copu
-
摘 要:用一种新的思路和方法,先计算低通、再计算高通滤波器的有关参数,然后组合成带通滤波器.关键词:滤波器;参数;新思路中图分类号: TN713. 5 文献识别码:B 文章编号:1008 - 1666 (1999) 04 - 0089 - 03A New Consideration of the Band Filter’s CalculationGuo Wencheng( S hao Yang B usiness and Technology school , S haoyang , Hunan ,422000 )Abstract :This essay deals with a new method of calculating the band filters - first calculatingthe relevant parameters of low - pass filters ,then calculating the ones of high - pass filters.Key words :filter ; parameters ;new considercation八十年代后,信息产业得到了迅猛发展. 带通滤波器在微波通信、广播电视和精密仪器设备中得到了广泛应用. 带通滤波器性能的优劣,对提高接收机信噪比,防止邻近信道干扰,提高设备的技术指标,有着十分重要的意义.我在长期的教学实践中,用切比雪夫型方法设计、计算出宽带滤波器集中参数元件的数据. 该滤波器可运用在检测微波频率的仪器和其他设备中. 再将其思路和计算方法介绍给大家,供参考.
标签:
带通滤波器设计
计算
上传时间:
2014-12-28
上传用户:Yukiseop
