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CROSS REFERENCE TO RELATED APPLICATIONS 
   This is a continuation-in-part of U.S. Ser. No. 09/997,021, filed Nov. 28, 2001, now U.S. Pat. No. 6,938,689, which is a continuation-in-part of U.S. Ser. No. 09/179,507, filed Oct. 27, 1998, now U.S. Pat. No. 6,283,227. 

   TECHNICAL FIELD 
   The invention relates generally to interactive and/or secure activation of tools, such as tools used in well, mining, and seismic applications. 
   BACKGROUND 
   Many different types of operations can be performed in a wellbore. Examples of such operations include firing guns to create perforations, setting packers, opening and closing valves, collecting measurements made by sensors, and so forth. In a typical well operation, a tool is run into a wellbore to a desired depth, with the tool being activated thereafter by some mechanism, e.g., hydraulic pressure activation, electrical activation, mechanical activation, and so forth. 
   In some cases, activation of downhole tools creates safety concerns. This is especially true for tools that include explosive devices, such as perforating tools. To avoid accidental detonation of explosive devices in such tools, the tools are typically transferred to the well site in an unarmed condition, with the arming performed at the well site. Also, there are safety precautions taken at the well site to ensure that the explosive devices are not detonated prematurely. Another safety concern that exists at a well site is the use of wireless, especially radio frequency (RF), devices, which may inadvertently activate certain types of explosive devices. As a result, such wireless devices are usually not allowed at a well site, thereby limiting communications options that are available to well operators. Yet another concern associated with using explosive devices at a well site is the presence of stray voltages that may inadvertently detonate the explosive devices. 
   A further safety concern with explosive tools is that they may fall into the wrong hands. Such explosive tools pose great danger to persons who do not know how to handle explosive tools, or who want to use the explosive tools to harm others. 
   In addition to well applications, other applications that involve the use of explosive tools include mining applications and seismic applications. Similar types of safety concerns exist with such other types of explosive tools. Thus, a need continues exist to enhance the safety associated with the use of explosive tools as well as with other types of tools. Also, a need continues to exist to enhance the flexibility of controlling the operation of such explosive tools. 
   SUMMARY OF THE INVENTION 
   In general, an improved method and apparatus is provided to enhance the safety and flexibility associated with use of a tool. For example, a method of activating a tool includes checking an authorization code of a user to verify that the user has access to activate the tool. In addition, data pertaining to an environment around the tool is received. Activation of the tool is enabled in response to the authorization code and the data indicating that the environment around the tool meets predetermined one or more criteria for activation of the tool. 
   Other or alternative features will become apparent from the following description, the drawings, and the claims. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is block diagram of an example arrangement of control systems, sensors, and a downhole well tool. 
       FIG. 2  is a block diagram of a perforating tool, according to one embodiment, that can be used in the system of  FIG. 1 . 
       FIGS. 3A-3B  are a flow diagram of a process performed by a surface unit in accordance with an embodiment. 
       FIGS. 4 and 5  illustrate processes for secure and interactive activation of a perforating tool. 
       FIG. 6  is a block diagram of an example test arrangement including a tester box coupled to a tool under test, and a user interface device to control the tester box. 
   

   DETAILED DESCRIPTION OF THE INVENTION 
   In the following description, numerous details are set forth to provide an understanding of the present invention. However, it will be understood by those skilled in the art that the present invention may be practiced without these details and that numerous variations or modifications from the described embodiments may be possible. 
   As used here, the terms “up” and “down”; “upper” and “lower”; “upwardly” and downwardly”; “upstream” and “downstream”; “above” and “below”; and other like terms indicating relative positions above or below a given point or element are used in this description to more clearly describe some embodiments of the invention. However, when applied to equipment and methods for use in wells that are deviated or horizontal, such terms may refer to a left to right, right to left, or other relationship as appropriate. 
   Referring to  FIG. 1 , a system according to one embodiment includes a surface unit  100  that is coupled by cable  102  (e.g., a wireline) to a tool  104 . In the example shown in  FIG. 1 , the tool  104  is a tool for use in a well. For example, the tool  104  can include a perforating tool or other tool containing explosive devices, such as pipe cutters and the like. In other embodiments, other types of tools can be used for performing other types of operations in a well. For example, such other types of tools include tools for setting packers, opening or closing valves, logging, taking measurements, core sampling, and so forth. In the embodiments described below, safety issues associated with well tools containing explosive devices are discussed. However, similar methods and apparatus can be applied to tools having explosive devices in other applications, e.g., mining, seismic acquisition, surface demolition, armaments, and so forth. 
   The tool  104  includes a safety sub  106  and a plurality of guns  108 . In one embodiment, the safety sub  106  differs from the gun  108  in that the safety sub  106  does not include explosive devices that are present in the guns  108 . The safety sub  106  serves one of several purposes, including providing a quick connection of the tool  104  to the cable  102 . Additionally, the safety sub  106  allows electronic arming of the perforating tool  104  downhole instead of at the surface. Because the safety sub  106  does not include explosive devices, it provides electrical isolation between the cable  102  and the guns  108  so that electrical activation of the guns  108  is disabled until the safety sub  106  has been activated to close an electrical connection. 
   In the example of  FIG. 1 , the cable  102  is run through a winch assembly  110 , which is coupled to a depth sensor  112 . The depth sensor  112  monitors the rotation of the winch assembly  110  to determine the depth of the perforating tool  104 . The data relating to the depth of the tool  104  is communicated to the surface unit  100 . 
   In some systems, an internal (hardware or software) drive system can be used to simulate that the tool  104  has descended to a certain depth in the wellbore, even though the tool  104  is still at the earth surface. The depth sensor  112  can be used by the surface unit to verify that the tool  104  has indeed been lowered into the wellbore to a target depth. As a safety precaution, the ability to use the output of the internal hardware or drive system to enable activation of the tool  104  is prohibited. 
   The perforating tool  104  also includes a number of sensors, such as sensors  114  in the safety sub and sensors  116  in the guns  108 . Although  FIG. 1  shows each gun  108  as containing sensors  116 , less than all of the guns can be selected to include sensors in other embodiments. 
   Data from the sensors  114  and  116  are communicated over the cable  102  to a logging module  120  in the surface unit  100 . The logging module  120  is capable of performing bi-directional communications with the sensors  114  and  116  over the cable  102 . For example, the logging module  120  is able to issue commands to the sensors  114  and  116  to take measurements, and the logging module  120  is then able to receive measurement data from the sensors  114  and  116 . Data collected by the logging module  120  is stored in a storage  122  in the surface unit  100 . Examples of the storage  122  include magnetic media (e.g., a hard disk drive), optical media (e.g., a compact disk or digital versatile disk), semiconductor memories, and so forth. The surface unit  100  also includes activation software  124  that is executable on a processor  126 . The activation software  124  is responsible for managing the activation of the perforating tool  104  in response to user commands. The user commands can be issued from a number of sources, such as directly through a user interface  128  at the surface unit  100 , from a remote site system  130  over a communications link  132 , or from a portable user interface device  134  over a communications link  136 . 
   In one embodiment, the communications links  132  and  136  include wireless links, in the form of radio frequency (RF) links, infrared (IR) links, and the like. Alternatively, the communications links  132  and  136  are wired links. The surface unit  100  includes a communications interface  138  for communicating with the user interface device  134  and the remote site system  130  over the respective links. The remote site system  130  also includes a communications interface  140  for communicating over the communications link  132  to the surface unit  100 . Also, the remote site system  130  includes a display  142  for presenting information (e.g., status information, logging information, etc.) associated with the surface unit  100 . 
   The user interface device  134  also includes a communications interface  144  for communicating over the communications link  136  with the surface unit  100 . Additionally, the user interface device  134  includes a display  146  to enable the user to view information associated with the surface unit  100 . An example of the user interface device  134  is a personal digital assistant (PDA), such as a PALM® device, a WINDOWS® CE device, or other like device. Alternatively, the user interface device  134  includes a laptop or notebook computer. 
   In accordance with an embodiment, a security feature of the surface unit  100  is a smart card interface  148  for interacting with a smart card of a user. The smart card interface  148  is capable of reading identification information of the user (e.g., a digital signature, a user code, an employee number, and so forth). The activation software  124  uses this identification information to determine if the user is authorized to access the surface unit  100  and to perform activation of the perforating tool  104 . The identification information is part of the “authorization code” provided by a user to gain access to the surface unit  100 . 
   A smart card is basically a card with an embedded processor and storage, with the storage containing various types of information associated with a user. Such information includes a digital signature, a user profile, and so forth. 
   In an alternative embodiment, instead of a smart card interface  148 , the surface unit  100  can include another type of security feature, such as providing a prompt in which a user has to enter his or her user name and password. In yet another embodiment, the security mechanism of the surface unit  100  includes a biometric device to scan a biometric feature (e.g., fingerprint) of the user. The user interface device  134  can similarly include a smart card reader or biometric input device. 
   Alternatively, the user enters information and commands using either the user interface device  134  or the remote site system  130 . The user interface device  134  may itself store an authorization code, such as in the form of a user code, digital signature, and the like, that is communicated to the surface unit  100  with any commands issued by the user interface device  134 . Only authorized user interface devices  134  are able to issue commands that are acted on by the surface unit  100 . Although not shown, the user interface device  134  can optionally include a smart card interface to interact with the smart card of the user. 
   In the example shown, the remote site system  130  also includes a smart card interface  150 . Thus, before a user is able to issue commands from the remote site system  130  to the surface unit  100  to perform various actions, the user must be in possession of a smart card that enables access to the various features provided by the surface unit  100 . 
   In this way, the surface unit  100  cannot be accessed by unauthorized users. Therefore, safety problems associated with the unauthorized use of the perforating tool  104  is avoided. 
   Another safety feature offered by the perforating tool  104  is that each of the guns  108  is associated with a unique code or identifier. This code or identifier must be issued by the surface unit  100  with an activate command for the gun  108  to be activated. If the code or identifier is not provided, then the gun  108  cannot be fired. Thus, if the perforating tool  104  is stolen or is lost, unauthorized users will not be able to activate the guns  108  since they do not know what the codes or identifiers are. The safety sub  106  is also associated with a unique code or identifier that must be received by the safety sub  106  for the safety sub  106  to be activated to electrically arm the perforating tool  104 . 
   Another feature allowed by using unique codes or identifiers for the guns  108  is that the guns can be traced (to enable the tracking of lost or misplaced guns). Also, the unique codes or identifiers enable inventory control, allowing a well operator to know the equipment available for well operations. 
   Yet another safety feature associated with the guns  108  according to one embodiment is that they use exploding foil initiators (EFIs), which are safe in an environment in which wireless signals, such as RF signals, are present. As a result, this feature of the guns  108  enables the use of RF communications between the surface unit  100  and the remote site system  130  and with the user interface device  134 . However, in other embodiments, conventional detonators can be used in the perforating tool  104 , with precautions taken to avoid use of RF signals. The EFI detonator is one example of an electro-explosive device (EED) detonator, with other examples including an exploding bridge wire (EBW) detonator, semiconductor bridge detonator, hot-wire detonator, and so forth. 
   Another feature offered by the surface unit  100  according to some embodiments is the ability to perform “interactive” activation of the perforating tool  104 . The “interactive” activation feature refers to the ability to communicate with the sensors  114  and/or  116  in the perforating tool  104  before, during, and after activation of the perforating tool  104 . For example, the sensors  114  and/or  116  are able to take pressure measurements (to determine if an under balance or over balance condition exists prior to perforating), take temperature measurements (to verify explosive temperature ratings are not exceeded), and take fluid density measurements (to differentiate between liquid and gas in the wellbore). Also, the surface unit  100  is able to interact with the depth sensor  112  to determine the depth of the perforating tool  104 . This is to ensure that the perforating tool  104  is not activated prior to it being at a safe depth in the wellbore. As an added safety precaution, a user will be prevented from artificially setting the depth of the perforating tool below a predetermined depth for test purposes. In some systems, such a depth can be set by software or hardware to simulate the tool being in the wellbore. However, due to safety concerns, artificially setting the depth to a value where a gun is allowed to be activated is prohibited. 
   The sensors  114  and/or  116  may also include voltage meters to measure the voltage of the cable  102  at the upper head of the perforating tool  104 , the voltages at the detonating devices in the respective guns  108 , the amount of current present in the cable  102 , the impedance of the cable  102  and other electrical characteristics. The sensors may also include accelerometers for detecting tool movement as well as shot indication. Shot indication can be determined from waveforms provided by accelerometers over the cable  102  to the surface unit  100 . Alternatively, the waveform of the discharge voltage on the cable  102  can be monitored to determine if a shot has occurred. 
   The sensors  114  and/or  116  may also include moisture detectors to detect if excessive moisture exists in each of the guns  108 . Excessive moisture can indicate that the gun may be flooded and thus may not fire properly or at all. 
   The sensors may also include a position or orientation sensor to detect the position or orientation of a gun in well, to provide an indication of well deviation, and to detect correct positioning (e.g., low side of casing) before firing the gun. Also, the sensors may include a strain-gauge bridge sensor to detect external strain on the perforating tool  104  that may be due to pulling or other type of strain on the housing or cable head of a gun that is stuck in the well. Other types of sensors include acoustic sensors (e.g., a microphone), and other types of pressure gauges. 
   Other types of example sensors include equipment sensors (e.g., vibration sensors), sand detection sensors, water detection sensors, scale detectors, viscosity sensors, density sensors, bubble point sensors, composition sensors, infrared sensors, gamma ray detectors, H 2 S detectors, CO 2  detectors, casing collar locators, and so forth. 
   One of the aspects of the sensors  116  is that they are destroyed with firing of the guns  108 . However, the sensors  114  in the safety sub  106  may be able to survive detonation of the guns  108 . Thus, these sensors  114  can be used to monitor well conditions (e.g., measure pressure, temperature, and so forth) before, during, and after a perforating operation. 
   In addition to the sensors that are present in the perforating tool  104 , other sensors  152  can also be located at the earth surface. The sensors  152  are able to detect shock or vibrations created in the earth due to activation of the perforating tool  104 . For example, the sensors  152  may include geophones. The sensors  152  are coupled by a communications link  154 , which may be a wireless link or a wired link, to the surface unit  100 . Data from the sensors  152  to the surface unit  100  provide an indication of whether the perforating tool  104  has been activated. 
   The safety sub  106  and guns  108  of the perforating tool  104  are shown in greater detail in  FIG. 2 . In the example shown in  FIG. 2 , the safety sub  106  includes a control unit  14 A, and the guns  108  include control units  14 B,  14 C. Although only two guns  108  are shown in the example  FIG. 2 , other embodiments may include additional guns  108 . Each control unit  14  is coupled to switches  16  and  18  (illustrated at  16 A- 16 C and  18 A- 18 C). The switches  18 A- 18 C are cable switches that are controllable by the control units  14 A- 14 C, respectively, between on and off positions to enable or disable current flow through portions of the cable  102 . When the switch  18  is off, then the portion of the cable  102  below the switch  18  is isolated from the portion of the cable  102  above the switch  18 . The switches  16 A- 16 C are detonating switches. 
   In the safety sub  106 , the detonating switch  16 A is not connected to a detonating device. However, in the guns  108 , the detonating switches  16 B,  16 C are connected to detonating devices  22 B,  22 C, respectively. If activated to an on position, a detonating switch  16  allows electrical current to flow to a coupled detonating device  22  to activate the detonating device. The detonating device  22 B,  22 C includes an EFI detonator or other detonators. The detonating devices  22 B,  22 C are ballistically coupled to explosives, such as shaped charges or other explosives, to perform perforating. 
   As noted above, the safety sub  106  provides a convenient mechanism for connecting the perforating tool  104  to the cable  102 . This is because the safety sub  106  does not include a detonating device  22  or any other explosive, and thus does not pose a safety hazard. The switch  18 A of the safety sub  106  is initially in the open position, so that all guns of the perforating tool  104  are electrically isolated from the cable  102  by the safety sub  106 . Because of this feature, electrically arming of the perforating tool  104  does not occur until the perforating tool  104  is positioned downhole and the switch  18 A is closed. 
   Another feature allowed by the safety sub  106  is that the guns  108  can be pre-armed (by connecting each detonating device  22  in the gun  108 ) during transport or other handling of the perforating tool  104 . Thus, even though the perforating tool  104  is transported ballistically armed, the open switch  18 A of the safety sub  106  electrically isolates the guns  108  from any activation signal during transport or other handling. 
     FIGS. 3A-3B  are a flow diagram of a tool activation process, which is performed by the activation software  124  according to one embodiment. Before access is provided for activating the perforating tool  104 , the activation software  124  checks (at  202 ) if an authorization code has been received. The authorization code includes a digital signature, a user code, a user name and password, or some other code. The authorization code can be stored on a smart card and communicated to the surface unit  100  through the smart card interface  148 . Alternatively, the authorization code can be manually entered by the user through a user interface. 
   If an authorization code has been received and verified, the activation software  124  determines (at  204 ) the level of access provided to the user. Users are assigned a hierarchy of usage levels, with some users provided with a higher level of access while others are provided with a lower level of access. For example, a user with a higher level of access is authorized to activate the perforating tool to fire guns. A user with a lower access level may be able only to send inquiries to the perforating tool to determine the configuration of the perforating tool, and possibly, to perform a test of the perforating tool (without activating the detonating devices  22  in the perforating tool  104 ). 
   The activation software  24  also checks (at  206 ) for a depth of the perforating tool  104  in the well. Activation of the perforating tool  104  is prohibited unless the perforating tool  104  is at the correct depth. While the perforating tool  104  is not at a correct depth, as determined (at  208 ), further actions are prevented. However, once the perforating tool  104  is at the correct depth, the activation software  124  performs (at  210 ) various interrogations of control units  14  in the perforating tool  100 . Interrogations may include determining the positions of switches  16  and  18  in the perforating tool  104 , the status of the control unit  14 , the configuration and arrangement of the perforating tool  104  (e.g., number of guns, expected identifications or codes of each control unit, etc.), and so forth. 
   Once the status information has been received from the perforating tool  104 , the activation software  124  compares (at  212 ) the information against an expected configuration of the perforating tool  104 . Based on the interrogations and the comparison performed at  210  and  212 , the activation software  124  determines (at  214 ) if the perforating tool  104  is functioning properly or is in the proper configuration. If not, then the activation process ends with the tool  104  remaining deactivated. However, if the tool is determined to be functioning properly and in the expected configuration, the activation software  124  waits (at  216 ) for receipt of an arm command from the user. The arm command can be provided by the user through the user interface  128  of the surface unit  100 , through the user interface device  134 , or through the remote site system  130 . 
   Upon receipt of the arm command, the activation software  124  checks (at  218 ) the depth of the perforating tool  104  again. This is to ensure that the perforating tool  104  has not been raised from its initial depth. 
   Next, the activation software  124  checks (at  220 ) for various downhole environment conditions, including pressure, temperature, the presence of gas or liquid, the deviation of the wellbore, and so forth. 
   If the proper condition is not present, as determined at  224 , the activation software  124  communicates (at  226 ) an indication to the user, such as through the user interface  128  of the surface unit  100 , the display  146  of the user interface device  134 , or the display  142  of the remote site system  130 . Arming is prohibited. 
   However, if the condition of the well and the position of the perforating tool  104  is proper, the activation software  124  issues an arm command (at  228 ) to the perforating tool  100 . The arm command is received by the safety sub  106 , which closes the cable switch  18 A in response to the arm command. Optionally, the cable switches  18 B,  18 C can also be actuated closed at this time. 
   The activation software  124  waits (at  230 ) for receipt of an activate command from the user. Upon receipt of the activate command, the activation software  124  re-checks (at  232 ) the environment conditions and the depth of the penetrating tool. The activation software  124  also checks (at  234 ) the gun position and orientation. It may be desirable to shoot the gun at a predetermined angle with respect to the vertical. Also, the shaped charges of the perforating tool  104  may be oriented to shoot in a particular direction, so the orientation has to be verified. 
   If the environment condition and gun position is proper, as determined at  236 , the activation software  124  sends (at  238 ) the activate command to the perforating tool  104 . The activate command may be encrypted by the activation software  124  for communication over the cable  102 . The control units  14  in the perforating tool  104  are able to decrypt the encrypted activate command. In one embodiment, the activate command is provided with the proper identifier code of each control unit  14 . Each control unit  14  checks this code to ensure that the proper code has been issued before activating the appropriate switches  16  and  18  to fire the guns  108  in the perforating tool  104 . 
   In one sequence, the guns  108  of the perforating tool  104  are fired sequentially by a series of activate commands. In another sequence, the activate command is provided simultaneously to all guns  108 , with each gun  108  preprogrammed with a delay that specifies the delay time period between the receipt of the activate command and the firing of the gun  108 . The delays in plural guns  108  may be different. 
   During and after activation of the perforating tool  104 , measurement data is collected (at  240 ) from the various sensors  114 ,  116 , and  152 . The collected measurement data is then communicated (at  242 ) to the user. 
     FIG. 4  illustrates a flow diagram of a process of performing secure activation of an explosive tool, such as the perforating tool  104 , according to one embodiment. A central management site (not shown) provides (at  302 ) a profile of a user that includes his or her associated identifier, authorization code, personal identification number (PIN) code, digital signature, and access level. This profile is loaded as a certificate (at  304 ) into the surface unit  100 , where it is stored in the storage  122 . During use, a user inserts (at  306 ) his or her smart card into the smart card interface  148  of the surface unit  100 . The surface unit  100  may prompt for a PIN code through the user interface  128 , which is then entered by the user. The surface unit  100  checks (at  308 ) to ensure that a user is authorized to use a system based on the stored certificate and notifies the user of access grant. 
   Next, the user requests (at  310 ) arming of the perforating tool  104 , which is received by the surface unit  100 . In response, as discussed above, the surface unit  100  checks (at  312 ) the depth of the perforating tool  104  and the data from other sensors from the perforating tool  104  to determine if the perforating tool  104  is safe to arm. 
   The user then issues a fire command (at  314 ), which is received by the surface unit  100 . The surface unit  100  then checks (at  316 ) that the perforating tool  104  is safe to activate, and if so, sends an encrypted activate command to the perforating tool  104 . 
   The control unit  14 A in the safety sub  106  stores a private key at manufacture. This private key is used by the control unit  14 A in the safety sub  106  to decrypt the activate command (at  318 ). The decrypted activate command is then forwarded to the guns  108  to fire the guns. 
     FIG. 5  illustrates a flow diagram of a process of remotely activating the perforating tool  104 . In the context of  FIG. 1 , the remote activation is performed by a user at the remote site system  130 . In the example of  FIG. 5 , two users are involved in remotely activating the perforating tool  104 , with user  1  at the well site and user  2  at the remote site system  130 . As before, a central management system authorizes user names and their associated information and access levels (at  302 ) and communicates certificates containing the profiles (at  404 ) to the surface unit  100  and to the remote site system  130  for storage. 
   At the surface unit  100 , user  1  inserts (at  406 ) his or her smart card into the surface unit  100 , along with the user&#39;s PIN code, to request remote arming and activation of the perforating tool  104 . This indication is communicated (at  408 ) from the surface unit  100  to the remote site system  130  over the communications link  132 . User  1  also verifies (at  407 ) that all is safe and ready to fire at the surface unit  100 . 
   User  2  inserts his or her smart card into the smart card interface  150  of the remote site system  130  to gain access to the remote site system  130 . Once authorized, user  2  requests (at  410 ) arming of the perforating tool  104 . The surface unit  100  checks (at  412 ) that user  2  is authorized by accessing the certificate stored in the surface unit  100 . This check can alternatively be performed by the remote site system  130 . 
   The surface unit  100  then checks (at  414 ) the depth of the perforating tool  104  along with data from other sensors of the perforating tool  104  to ensure that the perforating tool  104  is safe to arm. Once the verification has been performed and communicated back to the remote site system  130 , user  2  issues an activate command (at  416 ) at the remote site system  130 . The surface unit  100  checks (at  418 ) to ensure that the perforating tool  104  is safe to activate, and then sends an encrypted activate command. The encrypted activate command is received by the safety sub  106 , with the encrypted activate command decrypted (at  420 ) by the control unit  14 A in the safety sub  106 . 
   According to some embodiments of the invention, another feature is the ability to test the perforating tool  104  to ensure the perforating tool  104  is functioning properly. The test can be performed at the well site or at an assembly shop that is remote from the well site. To do so, as shown in  FIG. 6 , a tester box  500  is coupled to the perforating tool  104  over a communications link  502  through a communications interface  504 . If the test is performed at the well site, the tester box  500  can be implemented in the surface unit  100 . At the assembly shop or at some other location, the tester box  500  is a stand-alone unit. The tester box  500  includes a communications port  503  that is capable of performing wireless communications with communications port  144  in the user interface device  134 . The communications can be in the form of IR communications, RF communications, or other forms of wireless communications. The communications between the user interface device  134  and the tester box  500  can also be over a wired link. 
   In one embodiment, various graphical user interface (GUI) elements (e.g., windows, screens, icons, menus, etc.) are provided in the display  146  of the user interface device  134 . The GUI elements include control elements such as menu items or icons that are selectable by a user to perform various acts. The GUI elements also include display boxes or fields in which information pertaining to the perforating tool  104  is displayed to the user. 
   In response to user selection of various GUI elements, the user interface device  134  sends commands to the tester box  500  to cause a certain task to be performed by control logic in the tester box  500 . Among the actions taken by the tester box  500  is the transmission of signals over the cable  502  to test the components of the perforating tool  104 . Feedback regarding the test is communicated back to the tester box  500 , which in turn communicates data over the wireless medium to the user interface device  134 , where the information is presented in the display  146 . As an added safety feature, the tester box  500  can also include a smart card reader or biometric input device to verify user authorization. 
   A more detailed description of the tester box  500  and components in the perforating tool  104  to enable this testing feature is discussed in greater detail in U.S. Ser. No. 09/997,021, entitled “Communicating with a Tool,” filed Nov. 28, 2001, which is hereby incorporated by reference. 
   The various systems and devices discussed herein each includes various software routines or modules. Such software routines or modules are executable on corresponding control units or processors. Each control unit or processor includes a microprocessor, a microcontroller, a processor card (including one or more microprocessors or microcontrollers), or other control or computing devices. As used here, a “controller” refers to a hardware component, software component, or a combination of the two. Although used in the singular sense, a “controller” can also refer to plural hardware components, plural software components, or a combination thereof. 
   The storage devices referred to in this discussion include one or more machine-readable storage media for storing data and instructions. The storage media include different forms of memory including semiconductor memory devices such as dynamic or static random access memories (DRAMs or SRAMs), erasable and programmable read-only memories (EPROMs), electrically erasable and programmable read-only memories (EEPROMs) and flash memories; magnetic disks such as fixed, floppy and removable disks; other magnetic media including tape; and optical media such as compact disks (CDs) or digital video disks (DVDs). Instructions that make up the various software routines or modules in the various devices or systems are stored in respective storage devices. The instructions when executed by a respective control unit or processor cause the corresponding node or system to perform programmed acts. 
   The instructions of the software routines or modules are loaded or transported to each device or system in one of many different ways. For example, code segments including instructions stored on floppy disks, CD or DVD media, a hard disk, or transported through a network interface card, modem, or other interface device are loaded into the device or system and executed as corresponding software routines or modules. In the loading or transport process, data signals that are embodied in carrier waves (transmitted over telephone lines, network lines, wireless links, cables, and the like) communicate the code segments, including instructions, to the device or system. Such carrier waves are in the form of electrical, optical, acoustical, electromagnetic, or other types of signals. 
   While the invention has been disclosed with respect to a limited number of embodiments, those skilled in the art, having the benefit of this disclosure, will appreciate numerous modifications and variations therefrom. It is intended that the appended claims cover such modifications and variations as fall within the true spirit and scope of the invention.

Summary:
A tool activation system and method includes receiving an authorization code of a user to verify access rights of a user to activate the tool. In one example, the authorization code is receive from a smart card. The environment around the tool, which can be in a wellbore, for example, is checked. In response to the authorization code and the checking of the environment, activation of the tool is enabled.