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Claims  |
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I claim:
1. A structure, comprising:
a first connector having a first plurality of electrical contacts;
a second connector having a second plurality of electrical contacts; and
a cable including a plurality of wires coupling said first connector and
said second connector;
wherein when the second connector is attached to a computer interface in a
first orientation, the cable extends from the computer interface in a
first direction, and when the second connector is attached to the computer
interface in a second orientation, the cable extends from the computer
interface in a second direction; and
further wherein at least one of said electrical contacts in said first
plurality is electrically connected by said cable to at least two
electrical contacts in said second plurality so that the electrical signal
pattern of the second plurality of electrical contacts is the same in both
orientations of said second connector.
2. Structure as in claim 1, wherein said cable couples said electrical
contact in said first plurality to exactly two electrical contacts in said
second plurality, and one of said two electrical contacts in said second
plurality is coupled to said computer interface in said first orientation
and the other of said two electrical contacts in said second plurality is
coupled to said computer interface in said second orientation.
3. Structure as in claim 1, wherein the second connector and the first
connector are respectively couplable to a PCMCIA card and a SCSI interface
connector.
4. Structure as in claim 1, further comprises:
a first shell section;
a second shell section attached to the first shell section to form an
enclosure having an opening;
an alignment post extending through the opening;
wherein said second connector is positioned within the enclosure, the first
connector having either contact pins or contact holes that are accessible
through the opening; and
an adapter formed with an alignment hole and further comprising a third
connector having the other of either contact pins or contact holes for
making electrical connection to the second connector, wherein:
the alignment post is of sufficient length such that when the second
connector is coupled to the third connector the alignment post extends
into the alignment hole.
5. Structure as in claim 4, wherein:
the first connector is a male connector;
the third connector is a female connector; and
the alignment hole is formed in the female connector.
6. Structure as in claim 4, wherein:
a second alignment post extends through the opening; and
a second alignment hole is formed in the third connector, the second
alignment post extending into the second alignment hole when the third
connector is attached to the second connector.
7. Structure as in claim 1,
wherein said second plurality of electrical contacts of said second
connector are arranged in two rows, with electrical contacts in a first
row numbered A1, A2, through As located opposite to electrical contacts in
a second row numbered As+1, As+2, through An;
wherein
electrical contacts A1 and An are opposite each other;
electrical contacts A2 and An-1 are opposite each other;
contacts As and As+1 are opposite each other; and
an order of electrical signals on the second row of electrical contacts is
reverse of an order of electrical signals on the first row of electrical
contacts.
8. Structure as in claim 7 wherein a group of said first row electrical
contacts and a plurality of second row electrical contacts are coupled to
each other, and are coupled to a ground plane of a PCMCIA card when said
second connector is coupled to said PCMCIA card.
9. Structure as in claim 1, wherein said second plurality of electrical
contacts of said second connector are arranged in a plurality of rows and
a group of electrical contacts in each of said rows are coupled to each
other through a ground terminal in said structure.
10. Structure as in claim 9, wherein said plurality of rows is two rows.
11. Structure for connecting a first computer interface to a second
computer interface, comprising:
a first connector, wherein the first connector has a plurality of
electrical contacts for making electrical connection to a plurality of
electrical terminals of the first computer interface; and
a second connector, wherein:
the second connector has a plurality of electrical contacts for making
electrical connection to a plurality of electrical terminals of the second
computer interface, the second connector attachable to the second computer
interface in a plurality of orientations;
each of the electrical contacts of the second connector is electrically
connected to one of the electrical contacts of the first connector so that
an electrical signal is sent from each terminal of the first computer
interface to one of two corresponding terminals of the second computer
interface; and
the same electrical signal is sent from each terminal of the first computer
interface to the other of two corresponding terminals of the second
computer interface irrespective of the orientation of the second connector
with respect to the second computer interface.
12. Structure as in claim 11, wherein the cable includes a plurality of
wires, each of the wires electrically connecting one of the plurality of
contacts of the first connector to at least one of the plurality of
contacts of the second connector.
13. Structure as in claim 11, further comprising a cable electrically
coupling the first and second connectors.
14. Structure as in claim 13, wherein:
when the second connector is attached to the second computer interface in a
first orientation, the cable extends from the second computer interface in
a first direction; and
when the second connector is attached to the second computer interface in a
second orientation, the cable extends from the second computer interface
in a second direction opposite the first direction.
15. Structure as in claim 11, further comprises:
a first shell section;
a second shell section attached to the first shell section to form an
enclosure having an opening;
an alignment post extending through the opening;
wherein said second connector is positioned within the enclosure, the first
connector having either contact pins or contact holes that are accessible
through the opening; and
an adapter formed with an alignment hole and further comprising a third
connector having the other of either contact pins or contact holes for
making electrical connection to the second connector; wherein:
the alignment post is of sufficient length such that when the second
connector is coupled to the third connector the alignment post extends
into the alignment hole.
16. Structure as in claim 15, wherein:
a second alignment post extends through the opening; and
a second alignment hole is formed in the third connector, the second
alignment post extending into the second alignment hole when the third
connector is attached to the second connector.
17. Structure as in claim 15, wherein:
the first connector is a male connector;
the third connector is a female connector; and
the alignment hole is formed in the female connector.
18. Structure for connecting a first computer interface to a second
computer interface, comprising:
a first adapter, wherein the first adapter has a first plurality of
electrical contacts for making electrical connection to a plurality of
electrical terminals of the first computer interface; and
a second adapter, wherein:
the second adapter has a second plurality of electrical contacts for making
electrical connection to a plurality of electrical terminals of the second
computer interface, the second adapter attachable to the second computer
interface in a plurality of orientations;
each of the electrical contacts of the second adapter is electrically
connected to one of the electrical contacts of the first adapter so that
an electrical signal is sent from each terminal of the first computer
interface to a corresponding terminal of the second computer interface;
and
the same electrical signal is sent from each terminal of the first computer
interface to the corresponding terminal of the second computer interface
irrespective of the orientation of the second adapter with respect to the
second computer interface;
wherein the second computer interface is a slot for a PCMCIA card; and the
first computer interface is a SCSI interface.
19. Structure as in claim 18, wherein said second plurality of electrical
contacts of said second adapter are arranged in a plurality of rows and a
group of electrical contacts in each of said rows are coupled to each
other through a ground terminal in said structure.
20. Structure as in claim 19, wherein said plurality of rows is two rows.
21. Structure as in claim 18,
wherein said second plurality of electrical contacts of said second
connector are arranged in two rows, with electrical contacts in a first
row numbered A1, A2, through As located opposite to electrical contacts in
a second row numbered As+1, As+2, through An;
wherein
electrical contacts A1 and An are opposite each other;
electrical contacts A2 and An-1 are opposite each other;
contacts As and As+1 are opposite each other; and
an order of electrical signals on the second row of electrical contacts is
reverse of an order of electrical signals on the first row of electrical
contacts.
22. Structure as in claim 21 wherein a group of said first row electrical
contacts and a plurality of second row electrical contacts are coupled to
each other, and are coupled to a ground plane of a PCMCIA card when said
second connector is coupled to said PCMCIA card. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to a structure for connecting a first computer
interface to a second computer interface. More particularly, the invention
relates to such a structure where the first computer interface is a PCMCIA
socket and the second interface is a SCSI interface.
2. Related Art
Typically, a computer is interconnected by an adapter to peripheral
devices, such as printers, CD-ROMs, hard disks and scanners.
Interconnection between a computer and a peripheral device (or between
peripheral devices) is frequently done with a cable that is configured, at
each end of the cable, to be compatible with an interface of the computer
or one of the peripheral devices, as appropriate.
Some computers include a slot (interface) for accepting a card that
conforms to the Personal Computer Memory Card International Association
(PCMCIA) standard. PCMCIA is a widely accepted industry standard for small
form factor add-in card applications which are especially popular among
users of notebook and sub-notebook computers. A PCMCIA card includes
electronic devices, such as printed circuit boards and/or integrated
circuit chips, on which circuitry is formed for performing logical
functions and/or for storing data. PCMCIA cards generally fall into two
categories: 1) memory add-in products including solid state and rotating
media, and 2) I/O add-in products such as fax-modems, network adapters,
and SCSI adapters.
Many computer peripheral devices utilize an interface bus standard known as
Small Computer Standard Interface (SCSI). For example, most CD-ROMs, many
high performance/high capacity hard disks and tape drives, scanners,
high-speed laser printers and digital cameras implement the SCSI standard.
Without more, a computer equipped with a PCMCIA card slot (and without a
SCSI interface) must use PCMCIA-compatible peripheral devices. However, in
some cases, the desired device may not exist in a PCMCIA format, or such a
device may be redundant with a SCSI peripheral device. In such situations,
it desirable to use an adapter that is configured to translate electrical
signals between the PCMCIA interface and the SCSI interface. However, such
an adapter can be awkward to use with a device equipped with a PCMCIA
slot.
SUMMARY OF THE INVENTION
A structure according to the invention connects a first computer interface
to a second computer interface. Generally, the first and second computer
interfaces can be of any type such as a SCSI interface, a PCMCIA slot, a
parallel port, an IDE interface, or any of a number of proprietary bus
interfaces developed by companies such as Sony and typically used for
CD-ROMs or tape drives. The structure according to the invention is
constructed so that an adapter attached to one of the first or second
computer interfaces is reversible, i.e., connection pins of the adapter
can be oriented in any of a plurality of directions while maintaining the
same electronic functionality of the structure according to the invention.
The multidirectionality of the adapter enables a user to attach the
adapter to the computer interface so that a cable attached to the adapter
extends from the adapter into an area that has sufficient room to
accommodate the cable.
One embodiment of a structure according to the invention includes a first
adapter having a first plurality of electrical contacts and a
multidirectional second adapter having a second plurality of electrical
contacts. Each of the first plurality of electrical contacts is
electrically connected to one of the second plurality of electrical
contacts so that the electrical signal pattern of the second plurality of
contacts is the same irrespective of the orientation of the
multidirectional connector.
Another embodiment of a structure according to the invention includes first
and second adapters. The first adapter has a plurality of electrical
contacts for making electrical connection to a plurality of electrical
terminals of a first computer interface. The second adapter has a
plurality of electrical contacts for making electrical connection to a
plurality of electrical terminals of a second computer interface. Each of
the electrical contacts of the second adapter is electrically connected to
one of the electrical contacts of the first adapter so that an electrical
signal is sent from each terminal of the first computer interface to a
corresponding terminal of the second computer interface, the same
electrical signal being sent from each terminal of the first computer
interface to the corresponding terminal of the second computer interface
irrespective of the orientation of the second adapter with respect to the
second computer interface.
Though not necessary, a structure according to the invention can also
include structure for electrically connecting the first and second
adapters. In one embodiment, when the second adapter is attached to a
computer interface in a first orientation, the structure for electrically
connecting extends from the second adapter in a first direction, and when
the second adapter is attached to the computer interface in a second
orientation, the structure for electrically connecting extends from the
second adapter in a second direction opposite the first direction. The
structure for electrically connecting is, for example, a cable including a
plurality of wires, each of the wires electrically connecting the contacts
of the first and second adapters.
In one embodiment, the multidirectional adapter includes first and second
connectors, the first connector having either contact pins or contact
holes and the second connector having the other of either contact pins or
contact holes for making electrical connection to the first connector. One
or more alignment posts on either the first or second connectors fits into
corresponding alignment holes formed in the other of the first or second
connectors. The alignment post or posts are of sufficient length so that
when the first connector is attached to the second connector, the
alignment post or posts extend into the alignment hole or holes so that
each of the contact pins are aligned with a corresponding one of the
contact holes prior to insertion of each of the contact pins into the
corresponding contact hole.
In a particular embodiment of the invention, the first computer interface
is a slot for a PCMCIA card and the second computer interface is a SCSI
interface.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a perspective view of a structure according to the invention for
connecting a first computer interface to a second computer interface.
FIG. 2 is a side view of the housing of the cable adapter shown in FIG. 1,
illustrating a side of the housing.
FIG. 3 is a side view of the housing of FIG. 2, illustrating another side
of the housing opposite the side shown in FIG. 2.
FIG. 4 is an end view of the housing of FIG. 2, illustrating an end of the
housing from which the cable shown in FIG. 1 extends.
FIG. 5A is a plan view of the exterior of the top half of the housing of
FIG. 2.
FIG. 5B is a plan view of the interior of the bottom half of the housing of
FIG. 2.
FIG. 6A is a plan view of the interior of the top half of the housing of
FIG. 2.
FIG. 6B is a plan view of the exterior of the bottom half of the housing of
FIG. 2.
FIG. 7A is a side view of the frame of the PCMCIA card of FIG. 1,
illustrating a side of the frame.
FIG. 7B is a plan view of the frame of FIG. 7A.
FIG. 7C is a side view of the frame of FIG. 7A, illustrating another side
of the frame opposite the side shown in FIG. 7A.
FIG. 7D is a plan view of the frame of FIG. 7A, taken in the opposite
direction of the view of FIG. 7B.
FIG. 7E is a cross-sectional view taken along sectional line 7E--7E of FIG.
7B.
FIG. 7F is a cross-sectional view taken along sectional line 7F--7F of FIG.
7B.
FIG. 7G is a cross-sectional view taken along sectional line 7G--7G of FIG.
7B.
FIG. 7H is a detailed view of the area within circle D of FIG. 7B.
FIG. 8A is a plan view of the male connector of the cable adapter of FIG.
1.
FIG. 8B is a front view of the male connector of FIG. 8A.
FIG. 8C is a side view of the male connector of FIG. 8A.
FIG. 9A is a plan view of the female connector of the PCMCIA card of FIG.
1.
FIG. 9B is a front view of the female connector of FIG. 9A
FIG. 9C is a cross-sectional view, taken along section line 9C--9C of FIG.
9A, of the female connector of FIG. 9A.
FIG. 9D is a cross-sectional view, taken along section line 9D--9D of FIG.
9A, of the female connector of FIG. 9A, illustrating an alignment hole.
DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION
FIG. 1 is a perspective view of structure 100 according to the invention
for connecting a PCMCIA interface to a SCSI interface. Other structures
according to the invention can be used to make connection between other
combinations of interfaces. Structure 100 includes standard SCSI connector
101, flexible cable 102, and a PCMCIA adapter including cable adapter 103
and PCMCIA card 104.
In use of structure 100, PCMCIA card 104 is inserted into a compatible
PCMCIA slot in a computer. Cable 102 extends from cable adapter 103 in a
direction parallel to the plane of PCMCIA card 104 and perpendicular to
the direction in which PCMCIA card 104 is inserted into the PCMCIA slot.
Cable adapter 103 is detachable from PCMCIA card 104, as explained in more
detail below, enabling cable adapter 103 to be flipped over and attached
to PCMCIA card 104 so that cable 102 extends from cable adapter 103 in a
direction opposite to that shown in FIG. 1.
Cable 102 connects SCSI connector 101 to cable adapter 103. SCSI connector
101 is a 50 pin, shielded connector as specified in the Small Computer
System Interface (SCSI) Specification, ANSI X3.131-1986, the pertinent
disclosure of which is incorporated herein by reference. As more readily
understood from the discussion bellows only 36 of the pins (electrical
contacts) of SCSI connector 101 are connected to cable adapter 103 through
cable 102.
Cable 102 houses twisted wire pairs. In the preferred embodiment of the
invention, cable 102 includes 19 twisted wire pairs. Each twisted wire
pair is housed in an electrical insulator that is preferably made as thin
as possible while maintaining the desired electrical properties. Each of
the twisted wire pairs include a ground line and a signal line. Each
ground line and signal line are soldered to respective pins of SCSI
connector 101. The pin assignments for SCSI connector 101 are shown in
Table 1 below and are functionally identical to that shown in the SCSI
specification noted above.
TABLE 1
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Pin Assignments for SCSI Connector 101
Pin Number Signal
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1 GND
2 GND
3 GND
4 GND
5 GND
6 GND
7 GND
8 GND
9 GND
10 N/C (GND)
11 N/C (GND)
12 N/C (GND)
13 N/C (GND)
14 N/C (GND)
15 N/C (GND)
16 GND
17 N/C (GND)
18 GND
19 GND
20 GND
21 GND
22 GND
23 GND
24 GND
25 GND
26 -DB0
27 -DB1
28 -DB2
29 -DB3
30 -DB4
31 -DB5
32 -DB6
33 -DB7
34 -DBP
35 N/C (GND)
36 N/C (GND)
37 N/C (GND)
38 N/C (GND)
39 N/C (GND)
40 N/C (GND)
41 -ATN
42 N/C (GND)
43 -BSY
44 -ACK
45 -RST
46 -MSG
47 -SEL
48 -C/D
49 -REQ
50 -I/O
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In Table 1, only 18 signals and 18 grounds are shown as connected from SCSI
connector 101. This is because, in the preferred embodiment of the
invention, the twisted pair for signal +TERMPWR from SCSI connector 101 is
not connected to cable adapter 103. As a result, termination power is not
provided to the printed circuit board used to bus signals within cable
adapter 103. Since termination power is not necessary to practice the
invention, this signal is disconnected to minimize the power drain on the
device including the PCMCIA card, which, in practice, is frequently a
notebook computer, and to eliminate the necessity to provide a current
limit.
Cable 102 also includes a drain wire which electrically connects the metal
shield of SCSI connector 101 to a foil shield that surrounds cable 102 and
to the shield ground pin at the interface between cable adapter 103 and
PCMCIA card 104. In one embodiment, the foil shield is made of
aluminum-mylar. The electrical connection between the foil shield
surrounding cable 102 and the metal shield of SCSI connector 101 helps
reduce electromagnetic interference (EMI), both with nearby electronic
devices as a result of the electromagnetic field induced by the flow of
current through the conductors within cable 102, and with the conductors
within cable 102 as a result of the electromagnetic field caused by the
nearby electronic devices.
Each of the signal lines of each twisted pair extend from cable 102 into
cable adapter 103 and are soldered to contacts on one side of a printed
circuit board inside cable adapter 103. The ground lines are soldered to a
ground plane formed on the other side of the printed circuit board. The
shield ground line is soldered to a contact on the same side of the
printed circuit board as the signal lines, so that the shield ground is
electrically isolated from the other ground lines (signal grounds), thus
making spurious electrical signals in the signal ground lines smaller than
they otherwise would be.
The printed circuit board in cable adapter 103 busses the signal and ground
lines to a male connector (described in more detail below with respect to
FIGS. 8A through 8C) formed as part of cable adapter 103. The signal lines
are bussed through the center of the printed circuit board, while the
shield ground is bussed near the periphery of the printed circuit board.
The male connector fits into a female connector (described in more detail
below with respect to FIGS. 9A through 9D) formed as part of PCMCIA card
104, making electrical contact so that the signals and grounds are
transmitted to PCMCIA card 104, as described in more detail below.
The male and female connectors between cable adapter 103 and PCMCIA card
104 each have two rows of 24 pins, a row on each connector corresponding
to a row on the other connector. Table 2 shows the pin assignments for the
card/adapter interface, i.e., the connection between the male and female
connectors. The signals correspond to the SCSI signals of the same name
(see Table 1 above).
TABLE 2
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Pin Assignments for Card/Adapter Interface
Pin Number Signal
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1 Shield GND
2 GND
3 -DB0
4 -DB1
5 -DB2
6 -DB3
7 -DB4
8 -DB5
9 -DB6
10 -DB7
11 -DBP
12 Vcc
13 -ACK
14 GND
15 -ATN
16 -BSY
17 -RST
18 -MSG
19 -SEL
20 -C/D
21 -I/O
22 GND
23 -REQ
24 GND
25 GND
26 -REQ
27 GND
28 -I/O
29 -C/D
30 -SEL
31 -MSG
32 -RST
33 -BSY
34 -ATN
35 GND
36 -ACK
37 Vcc
38 -DBP
39 -DB7
40 -DB6
41 -DB5
42 -DB4
43 -DB3
44 -DB2
45 -DB1
46 -DB0
47 GND
48 Shield GND
______________________________________
In the preferred embodiment, pins 12 and 37 (the pins connecting to supply
voltage V.sub.cc on PCMCIA card 104) are not connected between cable
adapter 103 and PCMCIA card 104. This reduces power consumption, as
explained above with respect to the +TERMPWR signal from SCSI connector
101, from the power supply of the computer device in which PCMCIA card 104
is inserted. In other embodiments of the invention, if desirable for some
purpose, V.sub.cc pins 12 and 37 can be connected between cable adapter
103 and cable 102.
When cable adapter 103 is connected to PCMCIA card 104, only the SCSI
signals on one row ("active row") of the two rows of pins are electrically
connected between cable adapter 103 and PCMCIA card 104. As can be seen
from Table 2, the order of electrical signals on the second row of 24 pins
(i.e., pins 25 through 48) is the reverse of the order of electrical
signals on the first row of 24 pins. Thus, PCMCIA card 104 can be
connected to cable adapter 103 in either of two orientations (i.e., with
either pins 1 through 24 as the top row of pins and pins 25 through 48 as
the bottom row of pins, or pins 1 through 24 as the bottom row of pins and
pins 25 through 48 as the top row of pins) and maintain the same sequence
of electrical connection on the active row of pins.
As described above, cable 102 extends from cable adapter 103 in a direction
along a line 105 parallel to the plane of PCMCIA card 104 and
perpendicular to the direction 106 in which PCMCIA card 104 is inserted
into the PCMCIA slot. Thus, cable 102 typically extends, at least for a
short distance, along a side of the computer in which PCMCIA card is
inserted.
The PCMCIA slot of different computers is located in different places, some
of which may accommodate cable 102 extending in one direction and others
of which may accommodate cable 102 extending in the opposite direction.
PCMCIA card 104 is keyed so that PCMCIA card 104 can only be inserted into
a PCMCIA slot of a computer in one orientation. However, since cable
adapter 103 can be connected to PCMCIA card 104 in either of two
orientations, cable 102 can extend in either of two directions. Thus, a
user can attach cable adapter 103 to PCMCIA card 104 in whichever
orientation results in the best accommodation of cable 102 extending from
cable adapter 103.
Though only the signal pins in one row of the interface between PCMCIA card
104 and cable adapter 103 are connected, all of the grounds in each row of
pins are electrically connected, resulting in a total of 29 electrical
connections between cable adapter 103 and PCMCIA card 104: 18 SCSI signal
connections, 8 ground connections and 2 shield ground connections. SCSI
requires a good ground connection that maintains consistent impedance
through cable 102 and cable adapter 103, so that detrimental effects along
signal paths such as signal reflections, signal undershoot and signal
overshoot are minimized. The quality of the ground connection is affected
by the magnitude of the impedance of each section of the ground current
path (which is, in turn, a function of the cross-sectional area and length
of the section of the ground current path), the number of transitions in
impedance along the ground current path, and the magnitude of the
impedance transitions.
Cable 102 includes 18 electrically connected ground lines. The printed
circuit board in cable adapter 103 includes a ground plane for bussing
ground lines. PCMCIA card 104 also includes a ground plane. Consequently,
in structure 100, to minimize the above-noted detrimental effects
according to the above criteria, it is desirable to provide as many ground
connections as possible at the interface between PCMCIA card 104 and cable
adapter 103. Since all ground lines in each row of the card/adapter
interface are electrically connected, 8, rather than 4, ground connections
are made, thus improving the quality of the ground connection between SCSI
connector 101 and PCMCIA card 104, thereby minimizing the detrimental
transmission line effects noted above.
PCMCIA card 104 includes the electronics for converting electrical signals
between the PCMCIA and SCSI formats. The electronics are established so
that structure 100 is compatible with PCMCIA PC Card Standard, Release 2.0
or later, the pertinent disclosure of which is incorporated herein by
reference, and with SCSI-1 electrical specifications as specified in the
Small Computer System Interface (SCSI) Specification, ANSI X3.131-1986.
The circuitry necessary to convert SCSI electrical signals to PCMCIA
electrical signals is apparent to one skilled in the art from review of
the above-cited PCMCIA and SCSI specifications.
PCMCIA card 104 has the form factor of a PCMCIA Type II card. The vertical
dimension of the cable adapter 103 is greater than the vertical dimension
of a PCMCIA Type II Extended card.
FIG. 2 is a side view of housing 200 of cable adapter 103. Housing 200
includes first half (top) 201 and second half (bottom) 202. Top 201 and
bottom 202 are attached together to enclose the printed circuit board (not
shown), as explained in more detail below, that is used to bus signals
from cable 102 to PCMCIA card 104. Top 201 and bottom 202 are made of any
lightweight, durable material having adequate strength to resist the
stresses to which housing 200 is reasonably expected to be subjected.
Illustratively, housing 200 is made of a plastic such as ABS. ABS plastic
is available commercially from a number of sources.
Top 201 has a stepped rim 211 (so designated in FIG. 6A) having a portion
211a that is lowered relative to a raised portion 211b. Bottom 202 also
has a stepped rim 208 having a portion 208a that is raised relative to a
lowered portion 208b. When top 201 is attached to bottom 202, raised
portion 211b of stepped rim 211 of top 201 fits against lowered portion
208b of stepped rim 208 of bottom 202, and raised portion 208a of stepped
rim 208 of bottom 202 fits against lowered portion 211a of stepped rim 211
of top 201. Consequently, a side of the raised portion 211b of the rim of
top 201 contacts a side of the raised portion 208a of the rim of bottom
202, thereby holding top 201 and bottom 202 laterally in place with
respect to each other.
Posts 205a and 205b are formed on bottom 202 and, when top 201 is attached
to bottom 202, fit into corresponding holes in bosses 204a and 204b formed
on top 201. Holes are formed in the printed circuit board within housing
200. Posts 205a and 205b extend through the holes, thereby holding the
printed circuit board laterally in place.
Legs 203a and 203b extend from top 201 near the location at which housing
200 interfaces with PCMCIA card 104. Each of legs 203a and 203b has an
L-shaped cross-section so that when top 201 and bottom 202 are attached
together, the base of each of legs 203aand 203b snaps into a corresponding
slot (not visible in the Figures) formed in raised section 208a of the rim
of bottom 202, thereby preventing top 201 and bottom 202 from separating.
In one embodiment of the invention, an adhesive is added onto each of legs
203a to further secure top 201 to bottom 202.
As best seen in FIG. 4, top 201 has an extending portion 210 and bottom 202
has an extending portion 209 such that, when top 201 and bottom 202 are
attached together, a substantially rectangular hole is formed in housing
200 into which PCMCIA card 104 fits. Alignment posts 206a and 206b extend
from bottom 202 past extending portion 209. Each of alignment posts 206a
and 206b have a substantially rectangular shape, though this need not be
the case. Alignment posts 206a and 206b are the male connector (described
above with respect to FIG. 1) which fit into the female connector of
PCMCIA card 104 to make electrical connection between cable adapter 103
and PCMCIA card 104.
Protruding portions 207a and 207b extend from bottom 202 toward top 201.
Each of protruding portions 207a and 207b has an L-shaped cross-section
such that when cable adapter 103 is assembled, protruding portions 207a
and 207b mate with recesses formed in top 201 to position top 201 and
bottom 202 in two axes with respect to each other.
FIG. 3 is a side view of housing 200, illustrating another side of housing
200 opposite the side shown in FIG. 2. Legs 301a and 301b extend from
raised section 211b of the rim of top 201. Each of legs 301a and 301b has
an L-shaped cross-section so that when top 201 and bottom 202 are attached
together, the base of each of legs 301a and 301b fits into corresponding
slot 501a or 501b (FIG. 5) formed in raised section 208a of the rim of
bottom 202, thereby preventing top 201 and bottom 202 from separating.
FIG. 4 is an end view of housing 200, illustrating an end of housing 200
from which cable 102 (FIG. 1) extends. Top 201 is formed with a recess
401a and bottom 202 is formed with a recess 401b so that when top 201 is
attached to bottom 202, recesses 401a and 401b together define a hole
through which cable 102 fits.
Top 201 is formed with rectangular recesses 402a and 402b. When top 201 is
attached to bottom 202, protruding portions 207a and 207b (FIG. 2) fit
into recesses 402b and 402a, respectively, so that the base of each of the
L-shaped protruding portions 207a and 207b contacts recesses 402b and
402a, respectively.
Grooves 403a and 403b are formed in top 201, and grooves 403c and 403d are
formed in bottom 202, so that when top 201 is attached to bottom 202,
grooves 403a and 403c form one continuous groove around housing 200, and
grooves 403b and 403d form another continuous groove around housing 200.
These grooves are not necessary to the invention.
FIG. 5A is a plan view of the exterior of top 201 of housing 200. FIG. 5B
is a plan view of the interior of bottom 202 of housing 200.
Top 201 has rectangular recesses 502a and 502b formed on opposite sides of
top 201. When top 201 is attached to bottom 202, the upright portion of
each of the L-shaped protruding portions 207a and 207b fits against recess
502a or 502b, respectively.
Bottom 202 is formed with rectangular recesses 506a and 506b adjacent
protruding portions 207a and 207b, respectively. Recesses 506a and 506b
aid a user in gripping cable adapter 103 when PCMCIA card 104 is being
inserted into or withdrawn from a PCMCIA slot.
Two pairs of ridges, each ridge extending perpendicular to the plane of
FIG. 5B, are formed on opposite sides of bottom 202, to define slots 507a
and 507b. When top 201 is attached to bottom 202, ridges 601a and 601b
(FIG. 6A) formed on opposite sides of top 201 fit into slots 507a and
507b, respectively, helping to hold top 201 in place laterally with
respect to bottom 202.
Cavities 503a and 503b are formed in alignment posts 206a and 206b,
respectively. Cavities 503a and 503b are present to help reduce "dimpling"
that may otherwise occur during the plastic injection molding used to form
bottom 202, as is well known in the art of plastic injection molding.
FIG. 6A is a plan view of the interior of top 201 of housing 200. FIG. 6B
is a plan view of the exterior of bottom 202 of housing 200. Each of the
elements of top 201 and bottom 202 illustrated in FIGS. 6A and 6B have
been discussed in more detail above.
FIG. 7A is a side view of frame 700 of PCMCIA card 104 (FIG. 1),
illustrating a side of frame 700. FIG. 7B is a plan view of frame 700.
FIG. 7C is a side view of frame 700, illustrating another side of frame
700 opposite the side shown in FIG. 7A. FIG. 7D is a plan view of frame
700, taken in the opposite direction of the view of FIG. 7B. FIG. 7E is a
cross-sectional view taken along sectional line A--A of FIG. 7B. FIG. 7F
is a cross-sectional view taken along sectional line B--B of FIG. 7B. FIG.
7G is a cross-sectional view taken along sectional line C--C of FIG. 7B.
FIG. 7H is a detailed view of the area within circle D of FIG. 7B.
Female connector 900, discussed in more detail below, is mounted on frame
700 near end 700b by fitting ears 905a and 905b (FIG. 9B) of female
connector 900 into corresponding cavities 705a and 705b (FIG. 7D) formed
in frame 700. Female connector 900 is attached to a printed circuit board,
as explained in more detail below, which is, in turn, attached to another
connector (not shown in the Figures) that is mounted on frame 700 using
cavities 706a and 706b.
A lid (not shown) is attached to each side of frame 700 to enclose the
printed circuit board and the two connectors. Protrusions formed on a
first lid are snap fit into cavities 703 (FIG. 7B) and protrusions formed
on a second lid are snap fit into cavities 704 (FIG. 7D).
End 700a is inserted into the PCMCIA slot of the computer with which
structure 100 is to be used. The sides of frame 700 near end 700a are
differently keyed, i.e., slots 701 (FIGS. 7A and 7B) and 702 (FIGS. 7B and
7C) are differently shaped, so that PCMCIA card 104 can only be inserted
into the PCMCIA slot in one direction.
Indentations 707 (FIGS. 7A and 7C) are formed on either side of frame 700.
In one embodiment of the invention, a metal clip is fitted over
indentations 707 and the shield ground from cable adapter 103 is connected
to the metal clip. However, this is not necessary to the invention and, in
the preferred embodiment, this is not done.
FIG. 8A is a plan view of male connector 800 of cable adapter 103 (FIG. 1).
FIG. 8B is a front view of male connector 800. FIG. 8C is a side view of
male connector 800.
Male connector 800 includes connector body 801, pins 802 and pins 803. Male
connector 800 is positioned in housing 200 of cable adapter 103 between
alignment posts 206a and 206b (see FIG. 5B) so that surface 801a of
connector body 801 contacts extending portion 209 of bottom 202 and
surface 801b of connector body 801 contacts extending portion 210 of top
201. When housing 200 is assembled, connector body 801 is held in place by
the contact with extending portions 209 and 210. Male connector 800 is
also held in place by attachment to the printed circuit board within
housing 200, as explained in more detail below, which is held lateral | | |
