A terminal may be connected to its host computer either by a direct cable connection, via a modem, or via a terminal server. The flow of data may be either a direct sequence of bytes (such as from a serial port) or packets on a network (such as TCP/IP).
Additional serial cards may be purchased which have many serial ports on them called "multiport boards". These boards are not covered in this HOWTO but there is a list of some of them (with URLs) in the Serial-HOWTO.
The simplest way to connect a terminal to a host computer is via a direct connection to a serial port on the computer. You may also use some the info in this section for connecting one computer to another (via the serial port). Most PC's come with a couple of serial ports, but one is usually used by a mouse. For the EIA-232 port, you need a null modem cable that crosses over the transmit and receive wires. In ethernet terminology it would be called a "crossover cable" (but the ethernet cable will not work for the serial port). If you want hardware flow control, you will probably use the DTR pin (or both the DTR and DSR pins).
Make sure you have the right kind of cable. A null modem cable bought at a computer store may do it (if it's long enough), but it probably will not work for hardware flow control. Such a cable may be labeled as a serial printer cable. Only larger computer stores are likely to stock such cables. A "modem cable" will not work since the wires go straight thru (and don't cross over). See Buy or Make your own cable. Make sure you are connecting to your PC's serial port at the male DB25 or the DB9, and not to your parallel port (female DB25).
These 3 diagrams are for real text-terminals. But you could use them to connect up 2 PCs if you substitute RTS for DTR and CTS for DSR. (Don't use 4-conductors for PC-to-PC). For terminals, if you only have DTR flow control (one-way) you may eliminate the RTS-to-DSR wire. If you have no hardware flow control, then you may also eliminate the CTS-to-DTR wire. Then if you have 2@ twisted pairs, you may then use 2 wires for signal ground per A Kludge using Twisted-Pair Cable. For a DB25 connector on your PC, you need:
PC male DB25 Terminal DB25
TxD Transmit Data 2 --> 3 RxD Receive Data
RxD Receive Data 3 <-- 2 TxD Transmit Data
SG Signal Ground 7 --- 7 SG Signal Ground
CTS Clear To Send 5 <--20 DTR Data Terminal Ready
RTS Request To Send 4 --> 6 DSR Data Set Ready
If you have a DB9 connector on your PC, try the following:
PC DB9 Terminal DB25
RxD Receive Data 2 <-- 2 TxD Transmit Data
TxD Transmit Data 3 --> 3 RxD Receive Data
SG Signal Ground 5 --- 7 SG Signal Ground
CTS Clear To Send 8 <--20 DTR Data Terminal Ready
RTS Request To Send 7 --> 6 DSR Data Set Ready **
If you have a DB9 connector on both your serial port and terminal:
PC DB9 Terminal DB9
RxD Receive Data 2 <-- 3 TxD Transmit Data
TxD Transmit Data 3 --> 2 RxD Receive Data
SG Signal Ground 5 --- 5 SG Signal Ground
CTS Clear To Send 8 <-- 4 DTR Data Terminal Ready
RTS Request To Send 7 --> 6 DSR Data Set Ready **
The above don't have modem control lines so be sure to give a "local" option to getty (which is equivalent to "stty clocal"). Also if you need hardware flow control it must be enabled at your computer (use a -h flag with agetty) ( equivalent to "stty crtscts" ).
The following 3 diagrams show full "standard" null modem cables. One that you purchase may be wired this way. Another pinout is for 20 and 6 to cross over and to have 8 cross over to both 4 and 5. This will not provide hardware flow control (RTS/CTS) for directly connected computers. Both of the above will work for terminals using software (Xon/Xoff) flow control (or no flow control). None of these cables will work for terminal hardware flow control since most real terminals support DTR or DTR/DSR flow control (handshaking) but Linux doesn't yet (2000).
PC male DB25 Terminal DB25
DSR Data Set Ready 6
|
DCD Carrier Detect 8 <-- 20 DTR Data Terminal Ready
TxD Transmit Data 2 --> 3 RxD Receive Data
RxD Receive Data 3 <-- 2 TxD Transmit Data
RTS Request To Send 4 --> 5 CTS Clear To Send
CTS Clear To Send 5 <-- 4 RTS Request To Send
SG Signal Ground 7 --- 7 SG Signal Ground
DTR Data Terminal Ready 20 --> 8 DCD Carrier Detect
|
6 DSR Data Set Ready
Alternatively, a full DB9-DB25 null modem cable (will not work
with terminal hardware handshaking; see above):
PC DB9 Terminal DB25
RxD Receive Data 2 <-- 2 TxD Transmit Data
TxD Transmit Data 3 --> 3 RxD Receive Data
6 DSR Data Set Ready
|
DTR Data Terminal Ready 4 --> 8 DCD Carrier Detect
SG Signal Ground 5 --- 7 SG Signal Ground
DCD Carrier Detect 1
|
DSR Data Set Ready 6 <-- 20 DTR Data Terminal Ready
RTS Request To Send 7 --> 5 CTS Clear To Send
CTS Clear To Send 8 <-- 4 RTS Request To Send
(RI Ring Indicator 9 (not needed)
(Yes, the pins 2 and 3 really do have opposite meanings for DB9 and
DB25 connectors!)
Here's how to null-modem connect two DB9's together (but DTR flow control will not work):
PC DB9 DB9
RxD Receive Data 2 <-- 3 TxD Transmit Data
TxD Transmit Data 3 --> 2 RxD Receive Data
6 DSR Data Set Ready
|
DTR Data Terminal Ready 4 --> 1 DCD Carrier Detect
GND Signal Ground 5 --- 5 GND Signal Ground
DCD Carrier Detect 1
|
DSR Data Set Ready 6 <-- 4 DTR Data Terminal Ready
RTS Request To Send 7 --> 8 CTS Clear To Send
CTS Clear To Send 8 <-- 7 RTS Request To Send
RI Ring Indicator 9 (not used)
Using the above 2 connections provide full modem control signals and seemingly allow one to set "stty -clocal". Then one must turn on the terminal first (asserts DTR) before the port may be opened in a normal manner by getty, etc. But there is likely to be trouble if you fail to turn on the terminal first (see Getty Respawning Too Rapidly). For this reason one should use "stty clocal" which is the default (ignores modem control lines) and the additional wires in these cables then serve no useful purpose.
In olden days when it may not have been this easy to ignore modem control signals etc, the following "trick" was done for cables that lacked conductors for modem control: on your computer side of the connector, connect RTS and CTS together, and also connect DSR, DCD and DTR together. This way, when the computer needs a certain handshaking signal to proceed, it will get it (falsely) from itself.
A cable longer than a 50 feet or so may not work properly at high speed. Much longer lengths sometimes work OK, especially if the speed is low and/or the cable is a special low-capacitance type and/or the electronics of the receiving end are extra sensitive. It is claimed that under ideal conditions at 9600 baud, 1000 feet works OK. One way to cover long distances is to install 2@ line drivers near each serial port so as to convert unbalanced to balanced (and conversely) and then use twisted pair cabling. But line drivers are expensive.
Another way to increase the distance is to try to cancel out much of the magnetic field created by the currents in the transmit and receive data wires: TxD and RxD. To do this, ground return lines, which have current which is roughly equal (but in the opposite direction) are placed next to the the transmit and received wires. Twisted pair has the best cancellation. Some DEC terminals have two signal ground wires for this purpose. For example, one pair would be TxD and SG(TxD) where SG is signal ground. If you use ribbon cable, insure that the TxD and SG(TxD) wires are right next to each other. Similarly for the RxD.
If there is only one signal ground wire provided by both the PC and the terminal, it may be split into two wires in a twisted pair cable for this purpose. You might think that return currents will be equally split between the two signal ground wires. This would cancel out only about half of the magnetic field. But it's better cancellation than this because return current prefers the path of least impedance. The return path of a data signal (such as TxD) has the lowest impedance (due to lower inductance) if it flows back in the same twisted pair. Although I've haven't seen any experimental test results for this method, it should allow longer cable lengths.
If you expect to use hardware flow control (handshaking) you will likely need to make up your own cable (or order one made). Of course, if the connecters on the ends of a used cable remove, you might rewire it. See Installing DB Connectors. You will need to determine whether or not the terminal uses the DTR pin for this, and if not, what pin (or pins) it uses. The set-up menus may give you a clue on this since there may be an option for enabling "DTR handshaking" (or flow control) which of course implies that it uses the DTR pin. It may also use the DSR pin. See Hardware Flow Control for a detailed explanation of it. Older terminals may have no provision for hardware flow control.
The normal "straight thru" cable will not work unless you are using it as an extension cable in conjunction with either a null modem (crossover) cable or a null modem adapter. Make sure that the connectors on the cable ends will mate with the connectors on the hardware. One may use telephone cable which is at least 4-conductor (and possibly twisted pair). Shielded, special low-capacitance cable computer cable is best.
See also Overcoming Length Limitations. Although none of the EIA-232 signals are balanced for twisted pair one may attempt to use twisted-pair cable with it. Use one pair for transmit and another for receive. To do this connect signal ground to one wire in each of these 2 pair. Only part of the signal ground current flows in the desired wire but it may help. Due to the lower inductance of the twisted pair circuit (as compared to ground return current by some other path) more return (ground) current will confine itself to the desired twisted pair than one would expect from only resistance calculations. This is especially true at higher frequencies since inductive impedance increases with frequency. The rectangular wave of the serial port contains high frequency harmonics.
Pin 1 (of a DB25) should be chassis ground (also earth ground) but on cheap serial ports it may not even be connected to anything. A 9-pin connector doesn't even have a chassis ground. The signal ground is pin 7 and is usually grounded to chassis ground. This means that part of the signal current will flow thru the ground wires of the building wiring (undesirable). Cable shields are supposed to be only grounded at one end of the cable, but it may be better to ground both ends since it's better to have current in the shield than in the building wiring ??
By using a terminal-modem combination (without a computer) one may dial out to other computers. Up to the mid 1990s in the US, there were many "bulletin boards" one could dial out to. Some even provided connections to the Internet. But bulletin boards lost out in favor of the Internet.
Instead of connecting a terminal (or computer emulating a terminal) directly to a host computer using a cable it may be connected to the host via a telephone line (or dedicated private line) with a modem at each end of the line. The terminal (or computer) will usually dial out on a phone line to a host computer.
Most people use a PC and modem for dialing out. The PC could have a terminal connected to a serial port and the person at the terminal may dial out using the PC. Connecting a real terminal directly to an external modem is more difficult since the real terminal isn't very intelligent and doesn't give as much feedback to the user. For dialing out, many terminals can store one or more telephone numbers as messages which may be "set-up" into them and are sent out to the modem by pressing certain function keys. Many modems can also store phone numbers. The modem initiation sequence must precede the telephone number. When the outgoing call is answered by another modem at the other end of the phone line, the the host computer on this modem may run a getty program to enable you to log in.
It's common for a computer running Linux to get dialed into. The caller gets a login prompt and logs in. At first glance, it may seem strange how a dumb terminal (not connected to any computer) could accept an incoming call, but it can. One possible reason for doing this is to save on phone bills where rates are not symmetric. Your terminal needs to be set up for dial-in: Set the modem at your terminal for automatic answer (Register S0 set to 2 will answer on the 2nd ring). You turn on the terminal and modem before you expect a call and when the call comes in you get a login prompt and log in.
The host computer that dials out to your terminal needs to do something quite unusual. As soon as your modem answers, it needs to run login (getty). A host may do this by running the Linux program "callback" sometimes named "cb". Callback is for having computer A call computer B, and then B hangs up and calls A back. This is what you want if you are using computer A to emulate a terminal. For the case of a real terminal this may be too complex a task so the host may utilize only the "back" part of the callback program. The setup file for callback must be properly configured at the host. Callback makes the call to the terminal and then has mgetty run a login on that port. Mgetty by itself (as of early 1998) is only for dial-in calls but there is work being done to incorporate callback features into it and thus make it able to dial-out. As of early 1999 it didn't seem to have been done.
Telnet is a program which lets a text terminal (or a PC console) connect to a host computer over a network. No serial ports are used for the telnet connection. Of course if you are sitting at a real text terminal there is a serial connection to your own host. But when you run telnet, your host connects to another host via serial-less telnet.
Telnet uses tcp/ip packets over various networks: the Internet, LANs, etc. You run telnet (as a client) and it connects to a telnet server on another computer on a network. Then you get a login prompt and log in just as if you were directly connected via a cable to a serial port.
A terminal server is something that serves to connect a bunch of terminals to a host computer(s) via a network. Today this server is often located nearby or inside the host computer. If you directly connect some terminals to a PC or connect them via dial-up modems thru serial ports at each end, you don't need a terminal server.
But if the terminals are connected to the host over a network, then you may need a terminal server to make the serial-to-network conversions. This is useful for devices such as printers and terminals that have no built-in network support. However the definition of "terminal server" has broadened to the case where all data flows entirely over a network (except of course within the computer itself) and where no serial ports are involved. The term "terminal" may include a thin client type terminal with a GUI. The network usually uses tcp/ip and/or ppp but other protocols (including protocol conversion) are sometimes supported.
One way to connect a "terminal" (your PC console) to a network is to run telnet on your PC (assuming your PC has a network connection). At one time, terminal servers were dedicated hardware which could be used only as terminal servers. Today a PC can simultaneously serve as a terminal server thereby serving many terminals.
Today, most terminal servers serve thin client terminals rather than text-terminals. The "Linux Terminal Server Project" is an example. But it can also serve text terminals using telnet. Such a text-terminal is likely to be just a PC monitor emulating a terminal of type "Linux". The terminal server is just software running on the host computer. Telnet server software is like a simple terminal server.
A host that only has directly connected terminals (or modem connections without tcp/ip or ppp) is sometimes called a "terminal server". Although it's doing the same job as a real terminal server, it strictly speaking is not a terminal server.
Originally a terminal server served real text-terminals via the serial port. A server for real text-terminals would have a number of serial ports. The user would log in to the server and then get connected via tcp/ip, etc. to a host computer where s/he would login a second time again. Sometimes the first login would be automatic, or perhaps there would be a choice given the user as to what host computer (or printer) to connect to (or what protocol to use).
The use of text-terminals declined as the PC replaced mainframes. But the PC could emulate a terminal (using say minicom (Linux) or (hyper)terminal for MS). One could could then dial-out via a modem to a bulletin-board or the like. There would be a bank of modems to accept such calls and each modem would be connected to a serial port. The serial port could either be on a multiport card or on a dedicated terminal server. Note that in both the above cases there is no client software. It's not a client-server model.
When the Internet became popular, one would run the PPP protocol on the phone line and still go thru a modem and "terminal server" at the ISP. This server would handle PPP and ultimately connect one to the Internet. But the PC was no longer emulating a text terminal since browser images were being displayed. Today with ISPs getting only digital signals from the phone company, they don't need real modems anymore. So what was a "terminal server" evolved into a "remote access server". It's infrequently been called a "digital terminal server". Note that 56k modem service requires that an ISP have a digital connection to the phone company.
With remote access servers, instead of many individual telephone line cables connected to a terminal server, one now finds just a few cables with many digitized telephone calls on each cable (multiplexed). The multitude of connectors needed for large numbers of terminals or modems is no longer present on a remote access server and thus the successor to this type of terminal server can't readily serve text-terminals anymore.
More recently with the advent of thin clients terminals, the term "terminal server" was revived to apply to the hosts that served the thin clients. Both MS Windows and Linux can serve thin clients.
A connector is more-or-less permanently attached to the end of a cable or to a hardware unit. There are two basic types of connectors used in serial communications: 1. DBxx with pins (such as DB25) and 2. modular telephone-style connectors.
An adapter looks about like a connector but it has two ends. It is just like a cable that is so short that there is no cable part left at all --just different connectors on each end is all that remains. The adapter just plugs in on each side. It allows two incompatible connectors to mate with each other by going in between them. Sometimes the purpose of the adapter is to interchange wires. Obviously, one may use a special cable (perhaps homemade) as a substitute for an adapter.
Connectors (or one side of adapters) are either male or female. The connectors that have pins are male and the ones that have sockets (sometimes also called pins) are female. For modular connectors, the ones with exposed contacts are plugs while the ones with internal contacts (not easy to see) are jacks. Plugs are male; jacks are female.
There are three basic types of adapters: null modem, gender changers and port adapters. Some adapters perform more than one of these three functions.
(For how to install a DB connector on the ends of a cable see Installing DB Connectors.) These come in 9 or 25 pins. The EIA-232 specs. call for 25 pins but since most of these pins are not used on ordinary serial ports, 9 pins is sufficient. See DB9-DB25 for the pin-out. The pins are usually numbered if you look closely enough or use a magnifying glass.
RJ means Registered Jack. These look like modern telephone connectors but are sometimes not compatible with telephone connectors. See also Installing RJ Connectors. For use with serial ports they may be 6 or 8 conductor. A few are 10-conductor but may not officially belong to the RJ series.
RJ11 are all the same size but may have 2, 4, or 6 conductors. If it has two conductors, it should be called a RJ11. If it has 4 conductors, some call it a RJ14. If it has 6 conductors, many call it a RJ12 (but a RJ12 per the phone company has only 4 conductors). Seems confusing but they are all the same size and differ mainly by the number of conductor contacts present.
A look-alike (almost) is a MMJ connector (6-conductor) used on later model VT (and other) terminals. It's sometimes referred to as a DEC-423 or a DEC RJ11. MMJ has an offset tab and is not compatible with RJ ones (unless the tab is cut off). However, some connectors have been made that are compatible with both MMJ and the RJ ones. Since MMJ connectors are both hard to find and may be expensive some people have forced a RJ (6 conductor) to fit MMJ by filing off the offset tab with a file.
The MMJ (DEC) pinout is: 1-DTR, 2-TxD, 3-TxD_Gnd, 4-RxD_Gnd, 5-RxD, 6-DSR. Cyclades Cyclom-8Ys RJ12 has: 1-DTR, 2-TxD, 3-Gnd, 4-CTS, 5-RxD, 6-DCD. Specialix IO8+ has: 1-DCD, 2-RxD, 3-DTR/RTS, 4-Gnd, 5-TxD, 6-CTS. The pins of the RJ (and MMJ) are numbered similar to the RJ45.
Plug Jack (or socket)
(Looking at the end (Looking at the cavity
end of a cable) in a wall or PC back)
.________. .________.
| 654321 | | 123456 |
|__. .__| |__. .__|
|__| |__|
A standard MMJ null-modem cable has a MMJ connector at each end. It connects to the PC using a MMJ-to-DB adapter. This adapter plugs into a DB (say 25 pin) connector on the back of the PC and the MMJ connecter plugs into it. If you don't have such an adapter, you can make a custom cable with a MMJ (or filed RJ) connector on one end and a DB connector on the other end.
The standard null-modem cable with two MMJ (or RJ11/14) connectors will connect: 1-6, 2-5, and 3-4. Note that such a cable supports DTR/DSR flow control which is not supported (yet) by Linux. Making up your own standard 6-conductor null-modem cable is very simple if you understand that the ordinary 4-conductor telephone cable from the wall to your telephone, used in hundreds of millions of homes, is also a null-modem cable. Find one and wire your cable the same way.
If you lay such a cable (or your terminal null-modem cable) flat on the floor (with no twists) you will note that both plugs on the ends have their gold contacts facing up (or both facing down). Although it's symmetrical, it is also null- modem if you think about it a bit. One may put a few such cables together with inline couplers and everything works OK because each inline coupler is also a null-modem adapter. Two null-modem devices in series result in a straight-thru connection.
Here's a custom cable diagram (by Mark Gleaves) for connecting MMJ to a 9-pin serial port using RTS/CTS flow control:
DEC MMJ Linux PC DB9
Pin Signal Signal Pin
=== ====== ====== ===
1 DTR -----------------------|---> DSR 6
|---> CTS 8
2 TxD ---------------------------> RxD 2
3 SG (TxD)--------------------|--- SG 5
4 SG (RxD)--------------------|
5 RxD <--------------------------- TxD 3
6 DSR <--------------------------- RTS 7
|--> DTR 4
|--> CD 1
(no connection) RI 9
RJ45 and RJ48 are 8-conductor modular telephone plugs. There exists some 10-conductor connectors which are allegedly wider and will not mate with the 8-conductor ones. People have called the 10-conductor ones RJ45 and/or RJ48 but this may be incorrect. These connectors are used for both flat telephone cable and round twisted pair cable. The cable end of the connector may be different for round and flat cable. RJ48 has an extra tab so that a RJ48 plug will not push into a RJ45 jack (but a RJ45 plug will mate with a RJ48 jack). They're used on some multiport serial cards and networks. Heres the pin numbers for an 8-conductor:
Plug Jack (or socket)
(Looking at the end (Looking at the cavity
end of a cable) in a wall)
.__________. .__________.
| 87654321 | | 12345678 |
|__. .__| |__. .__|
|____| |____|
You may try to buy a short, null modem cable. Just a "modem cable" will not work. Null modem cables are often labeled as serial printer cables (but serial printers are not very popular today and neither are the cables). Unfortunately, they will probably not work for hardware flow control (until Linux supports DTR flow control, possibly in 2001). Make sure the connectors on the cable ends will fit the connectors on your computer and terminal.
But if you need longer cables to connect up terminals or need hardware flow control, how do you get the right cables? The right ready-made cables may be difficult to find (you might find them by searching the Internet), especially if you want to use a minimum (say 4) of conductors. One option is to get them custom made, which is likely to be fairly expensive although you might find someone to make them at prices not too much higher than ready-made cable (I did).
A low-cost alternative is to buy used cables (if you can find them). If you get a used terminal, ask if they have a cable for it. Another alternative is to make your own. Even if you get used cables, they may need some changes to the pin wiring. In either case, this may require special tools. Most connectors that come with short cables are permanently molded to the cable and can't be rewired but most custom-made and homemade cables have connectors that can be rewired. One advantage of making your own cable is that the skills you learn will come in handy if a cable breaks (or goes bad) or if you need to make up another cable in a hurry.
The numbers of the pins should be engraved in the plastic of the connector. Each pin should have a number next to it. You may need a magnifying glass to read them.
See DB Connectors for a brief description of them. Unfortunately, most cables one purchases today have molded connectors on each end and can't be modified. Others have connectors which unscrew and can be rewired. If you are making up cable or modifying an existing one then you need to know about pins. There are two types: soldered and crimped.
The crimped pins require a special crimping tool and also need an "insertion/extraction" tool. But once you have these tools, making up and modifying cable may be faster than soldering. If you are connecting two wires to one pin (also needed if you want to jumper one connected pin to another pin) then soldering is faster (for these pins). This is because the crimped pins can only take one wire each while the soldered ones can accept more than one wire per pin.
To insert crimped pins just push them in by hand or with the insertion tool. Using the tool for either insertion of removal first requires putting the tool tip around the wire. The tool tip should completely encircle the wire at the the back of the pin.
Removing a pin with this tool is a little tricky. These directions can be best understood if you have both the tool and wires in front of you as you read this. With the tool tip around the wire insert the tool as far as it will go into the hole (about 1 1/2 cm. Some tools have a mark (such as a tiny hole) on them to indicate how far to insert it. The tool tip should have a tapered gap so that you may get the tip around the wire by starting it in where the gap is wider than the wire. The tool may have 2 tips. The one that is the most difficult to get around the wire is also the one that removes the wire the easiest since it almost completely envelops the wire.
With the tip properly inserted pull on both the tool and the wire with a gentle pull. If it doesn't come out, the tool was likely not inserted correctly so either push it in more or twist it to a different position (or both). Perhaps you should have used another tip that fits tighter around the pin. Using this tool, one may readily convert a straight-thru cable to a null-modem cable, etc.
There can be problems using the "insertion/extraction" tool. If the tools will not insert on the back of the pin, it could be that the pin was not neatly crimped to the wire and is sort of square where it should be round, etc. If a pin starts to come out but will not pull out all the way, the pin may be bent. Look at it under a magnifying glass. Straightening a pin with needle-nose pliers may damage the gold plating but you may have to straighten it to remove it. Sometimes a stuck pin may be pushed out with a thick screwdriver blade tip (or the like) but if you push too hard you may gouge the plastic hole or bend the pin:.
Don't try soldering unless you know what you're doing or have read about how to do it.
These are telephone modular connecters one type of which is used for most ordinary telephones. But there are many different types (see RJ Modular Connectors).
These are not easy to reuse. You might be able to pull the wires out, push in something wedged that would lift up the gold-colored contacts and reuse the connector. There are special crimping tools used to install them; a different tool for each type.
If you don't have a crimping tool, installation is still possible (but difficult) using a small screwdriver (and possibly a hammer). Push in the cable wires and then push each gold-colored contact down hard with a small screwdriver that will just fit between the insulating ridges between the contacts. You may damage it if you fail to use a screwdriver with a head almost the same thickness as the contacts or if the screwdriver slips off the contact as you are pushing it down. You may also use a small hammer to pound on the screwdriver (push first by hand).
Be sure to not hurt the "remove lever" on the connecter when you push in the contacts. Don't just set it down on a table and push in the contacts. Instead, put a shim (about 1 mm thick) that fits snugly in the crevice between the lever and the body. For such a shim you may use thick cardboard, several calling cards, or wood. Since the bottom of the connector (that you will put on the table) isn't level (due to the "remove lever), make sure that the table top has something a little soft on it (like a sheet of cardboard) to help support the non-level connector. Even better would be to put another 1mm shim under the first 6mm of the connector, supporting it just under where you see the contacts. A soft tabletop wouldn't hurt either. Another method (I've never done this) is to hold the connector in a vice but be careful not to break the connector.
As compared to using a crimping tool, installing it per above takes a lot longer and is much more prone to errors and failure but it's sometimes more expedient and a lot cheaper than buying a special tool if you only have one or two connectors to install.