在升级到TM 1 9.5的过程中,如果有任何方面出现错误,可以利用这些文件来恢复TM 1 9.4Server数据和TM 1 9.4Web虚拟目录。
These files can be used to restore the TM1 9.4 Server data and TM1 9.4 Web virtual directory should anything go wrong during the upgrade to TM1 9.5.
在恢复过程中,ontape从stdin(标准输入)读取数据。
During a restore, ontape reads data from stdin (standard input).
您可以对所有类型的数据和环境重复该脚本,并在该过程中包括数据库写入和恢复。
You could repeat this with all sorts of data and environments, and include database writing and recovery into that process.
只有出错成员正在更新过程中的数据在恢复完成之前暂时不可用。
Only data in the process of being updated on the failing member is temporarily unavailable until recovery is complete.
该数据在恢复过程中是必须的,用于将文件目录映射到DocumentLibrary模型的一个文档中。
This data is required during restore to map the file contents to a document in the document Library model.
这个过程大约需要45分钟到一个小时取决于有多少数据要备份和恢复过程中。
The process takes about 45 minutes to an hour depending on how much data you have to backup and restore during the process.
安全可靠,恢复过程中只读不写,不会对源数据造成二次破坏。
Safe, reliable, read-only do not write in the recovery process will not cause secondary damage to the source data.
在这个更新过程中,可能由于某种故障(如网络)使数据库处于不一致状态,这时,我们必须通过某种恢复机制来恢复数据库的一致性。
During updating, database may be inconsistent because of some error, for example network error, so we must recover it by the recovery mechanism of the DDES.
本文给出了医院ORACLE数据库在热备份过程中的断点恢复及操作过程的方法。
The methods and operation of breakpoints recovery during hot backup in the ORACLE database of the hospital is introduced.
本文在对开断过程中介质恢复特性进行的研究中,以两场并行计算得到的结果为依托进行了单元节点的数据耦合。
In computing the dielectric recovery characteristic of HVCB during the interrupting course, the numerical results of parallel couple calculation on flow field and electric field has been performed.
基于SERDES的串行通信过程中采用时钟和数据恢复技术(CDR)代替同时传输数据和时钟,从而解决了限制数据传输速率的信号时钟偏移问题。
Serial communications based on SERDES adopt the clock_data recovery(CDR) instead of both data and clock transmitting, which solve the problem of clock skew.
该机制通过非对称加密算法、随机密钥加密用户备份信息,以及“一次一密”加密数据库等手段有效解决传统密钥恢复机制在密钥产生、存储、备份、恢复过程中的安全问题。
In this mechanism, random encryption key, asymmetric encryption algorithm and one-time key for database encryption are used to ensure the key's safety in generation, storage, backup and recovery.
该机制通过非对称加密算法、随机密钥加密用户备份信息,以及“一次一密”加密数据库等手段有效解决传统密钥恢复机制在密钥产生、存储、备份、恢复过程中的安全问题。
In this mechanism, random encryption key, asymmetric encryption algorithm and one-time key for database encryption are used to ensure the key's safety in generation, storage, backup and recovery.
应用推荐